variables
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104 rows where datasetId = 6590 sorted by id descending
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id ▲ | name | unit | description | createdAt | updatedAt | code | coverage | timespan | datasetId | sourceId | shortUnit | display | columnOrder | originalMetadata | grapherConfigAdmin | shortName | catalogPath | dimensions | schemaVersion | processingLevel | processingLog | titlePublic | titleVariant | attributionShort | attribution | descriptionShort | descriptionFromProducer | descriptionKey | descriptionProcessing | licenses | license | grapherConfigETL | type | sort | dataChecksum | metadataChecksum |
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944119 | Solar and wind per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:57 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Solar and wind", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | solar_and_wind_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind_per_capita__kwh__equivalent | 2 | major | Solar and wind power consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944118 | Solar and wind per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:57 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Solar and wind", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | solar_and_wind_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind_per_capita__kwh__direct | 2 | major | Solar and wind power consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944116 | Wind per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:57 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Wind", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | wind_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#wind_per_capita__kwh__equivalent | 2 | major | Wind power consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944114 | Wind per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:57 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Wind", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | wind_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#wind_per_capita__kwh__direct | 2 | major | Wind power consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944113 | Solar per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:57 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Solar", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | solar_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_per_capita__kwh__equivalent | 2 | major | Solar power consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944112 | Solar per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Solar", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | solar_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_per_capita__kwh__direct | 2 | major | Solar power consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944111 | Renewables per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Renewables", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | renewables_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables_per_capita__kwh__equivalent | 2 | major | Renewables consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944110 | Renewables per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Renewables", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | renewables_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables_per_capita__kwh__direct | 2 | major | Renewables consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944109 | Other renewables per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:46 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Other renewables", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | other_renewables_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables_per_capita__kwh__equivalent | 2 | major | Other renewables consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944107 | Other renewables per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:45 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Other renewables", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | other_renewables_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables_per_capita__kwh__direct | 2 | major | Other renewables consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944105 | Nuclear per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:45 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Nuclear", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | nuclear_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear_per_capita__kwh__equivalent | 2 | major | Nuclear power consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
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944104 | Nuclear per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:45 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Nuclear", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | nuclear_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear_per_capita__kwh__direct | 2 | major | Nuclear power consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944102 | Low-carbon energy per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Low-carbon energy", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | low_carbon_energy_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy_per_capita__kwh__equivalent | 2 | major | Low-carbon energy consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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944101 | Low-carbon energy per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Low-carbon energy", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | low_carbon_energy_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy_per_capita__kwh__direct | 2 | major | Low-carbon energy consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
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0abe6925af83d62fbba28e3614e86f4b | a04a6b2fa818ce12c0e2739573a57cf9 | |||||||||||||
944096 | Hydro per capita (kWh - equivalent) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Hydro", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | hydro_per_capita__kwh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro_per_capita__kwh__equivalent | 2 | major | Hydropower consumption per capita | Using the substitution method | Measured in kilowatt-hours per person. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
5df6a8dd4fe9a611a87959fb39a9b82e | 65cbb3aec6f9742d4924f89aa5739d25 | |||||||||||||
944092 | Biofuels per capita (kWh) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Biofuels", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | biofuels_per_capita__kwh | grapher/energy/2024-06-20/energy_mix/energy_mix#biofuels_per_capita__kwh | 2 | major | Biofuel consumption per capita | Measured in kilowatt-hours per person. | [ "Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
135a50b68a383df9427cf000f6e31391 | c3f2eb8cfb09f30f8e14052692ee77ad | ||||||||||||||
944091 | Hydro per capita (kWh - direct) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Hydro", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | hydro_per_capita__kwh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro_per_capita__kwh__direct | 2 | major | Hydropower consumption per capita | In terms of direct primary energy | Measured in kilowatt-hours per person. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
b0af5b6122d8f31a92fac9459c21ee76 | 7202412ab817b452a27e6245472938fc | |||||||||||||
944090 | Oil per capita (kWh) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Oil", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | oil_per_capita__kwh | grapher/energy/2024-06-20/energy_mix/energy_mix#oil_per_capita__kwh | 2 | major | Oil consumption per capita | Measured in kilowatt-hours per person. | [ "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
d454054863a3d8a9da7cf1cdf20eb7cc | 6144b22059381118301144301a798f12 | ||||||||||||||
944088 | Gas per capita (kWh) | kilowatt-hours | 2024-06-25 14:50:44 | 2024-07-25 23:08:56 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Gas", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | gas_per_capita__kwh | grapher/energy/2024-06-20/energy_mix/energy_mix#gas_per_capita__kwh | 2 | major | Gas consumption per capita | Measured in kilowatt-hours per person. | [ "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
2baecfd2d7631e3a73eb4b3f4008c662 | 01f4c575b5bace627e7171e51ed6df2f | ||||||||||||||
944085 | Fossil fuels per capita (kWh) | kilowatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Fossil fuels", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | fossil_fuels_per_capita__kwh | grapher/energy/2024-06-20/energy_mix/energy_mix#fossil_fuels_per_capita__kwh | 2 | major | Fossil fuel consumption per capita | Measured in kilowatt-hours per person. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
57f812684339e0db328dce7a51bf4f90 | a56ec13c98dea84bb6abb2b21b264c2c | ||||||||||||||
944083 | Coal per capita (kWh) | kilowatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1965-2023 | Energy mix 6590 | kWh | { "name": "Coal", "unit": "kilowatt-hours", "shortUnit": "kWh" } |
0 | coal_per_capita__kwh | grapher/energy/2024-06-20/energy_mix/energy_mix#coal_per_capita__kwh | 2 | major | Coal consumption per capita | Measured in kilowatt-hours per person. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data." ] |
Per capita figures are calculated by dividing by a population dataset that is built and maintained by Our World in Data, based on [different sources](https://ourworldindata.org/population-sources). | [ { "url": "https://docs.google.com/document/d/1-RmthhS2EPMK_HIpnPctcXpB0n7ADSWnXa5Hb3PxNq4/edit?usp=sharing", "name": "Creative Commons BY 4.0" }, { "url": "https://dataportaal.pbl.nl/downloads/HYDE/HYDE3.2/readme_release_HYDE3.2.1.txt", "name": "CC BY 3.0" }, { "url": "http://creativecommons.org/licenses/by/3.0/igo/", "name": "CC BY 3.0 IGO" } ] |
float | [] |
d6b0c73fd26c8fb188a469b23dc004d8 | 5f9b2d0ac40b0c64b493edf14ef625cc | ||||||||||||||
944080 | Solar and wind (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Solar and wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar_and_wind__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__twh_growth__equivalent | 2 | major | Annual change in solar and wind power consumption | Using the substitution method | Input-equivalent energy, in terawatt-hours, is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
ed0859af1bca8d766091984d28210423 | 995f10be1711bbccd47f4ce71660217c | ||||||||||||||
944077 | Solar and wind (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Solar and wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar_and_wind__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__twh_growth__direct | 2 | major | Annual change in solar and wind power consumption | In terms of direct primary energy | Figures are based on gross generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
9cb3f80085066a2aa4a1ab287a6239a8 | de7e7db2e825153b6601495ea50e1124 | ||||||||||||||
944073 | Solar and wind (% growth) | % | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1979-2023 | Energy mix 6590 | % | { "name": "Solar and wind", "unit": "%", "shortUnit": "%" } |
0 | solar_and_wind__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__pct_growth | 2 | major | Annual percentage change in solar and wind power consumption | Figures are based on gross generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
b44b0f7f14a152966f720754b29a62b6 | 21d8e175f5f45dd34b7aa7d02b293961 | |||||||||||||||
944072 | Wind (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | wind__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__twh_growth__equivalent | 2 | major | Annual change in wind power consumption | Using the substitution method | Input-equivalent energy, in terawatt-hours, is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
0d9611976c56a701b29526e37fe9aef2 | 68fab572f3ad17625dffa986726e10f4 | ||||||||||||||
944069 | Wind (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | wind__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__twh_growth__direct | 2 | major | Annual change in wind power consumption | In terms of direct primary energy | Figures are based on gross generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
0cb9c995c0b7543640590fc40f4820c4 | 185f0571363fda5250828e5e19787016 | ||||||||||||||
944068 | Wind (% growth) | % | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1979-2023 | Energy mix 6590 | % | { "name": "Wind", "unit": "%", "shortUnit": "%" } |
0 | wind__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__pct_growth | 2 | major | Annual percentage change in wind power consumption | Figures are based on gross generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
1b9ce552b112c98da89734f8125dc94e | e65a33cd7a4bdec04be54d3da1718f7a | |||||||||||||||
944066 | Solar (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:43 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Solar", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__twh_growth__equivalent | 2 | major | Annual change in solar power consumption | Using the substitution method | Input-equivalent energy, in terawatt-hours, is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
d04d85149c62a969a53cacd11d9648f1 | 8b7947828e2a1f6279af3d192e70995a | ||||||||||||||
944063 | Solar (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:42 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Solar", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__twh_growth__direct | 2 | major | Annual change in solar power consumption | In terms of direct primary energy | Figures are based on gross generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
b4c8397a562b081c373d4ada57153361 | 4c8b0693ba0ab56a1683abf36bf59ee7 | ||||||||||||||
944059 | Solar (% growth) | % | 2024-06-25 14:50:42 | 2024-07-25 23:08:55 | 1984-2023 | Energy mix 6590 | % | { "name": "Solar", "unit": "%", "shortUnit": "%" } |
0 | solar__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__pct_growth | 2 | major | Annual percentage change in solar power consumption | Figures are based on gross generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
6a3ed1e673b57a1721d888116e5ae1e4 | f61e824d16207fd623be4cca5841b5e4 | |||||||||||||||
944055 | Renewables (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:42 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | renewables__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__twh_growth__equivalent | 2 | major | Annual change in renewables consumption | Using the substitution method | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
a007b353f74470c53cd7cfadf757598c | c6ad2b255912f124cc38263f1a3c6905 | |||||||||||||||
944054 | Renewables (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:42 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | renewables__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__twh_growth__direct | 2 | major | Annual change in renewables consumption | In terms of direct primary energy | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
0580d13603e803899264a50dba338cca | ec874e0ab6d4e7bef18ea545fb034f24 | |||||||||||||||
944053 | Renewables (% growth) | % | 2024-06-25 14:50:41 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | % | { "name": "Renewables", "unit": "%", "shortUnit": "%" } |
0 | renewables__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__pct_growth | 2 | major | Annual percentage change in renewables consumption | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
e9dd1da9e2036f79f2f571fcb9462593 | 11dfbda243661bd7274c227115965082 | ||||||||||||||||
944051 | Other renewables (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:41 | 2024-07-25 23:08:55 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Other renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | other_renewables__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__twh_growth__equivalent | 2 | major | Annual change in other renewables consumption | Using the substitution method | Input-equivalent energy, in terawatt-hours, is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
688328281e8e46da26e946fd8592c28f | 09ba501143b0d016e738977709a49cda | ||||||||||||||
944049 | Other renewables (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:41 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Other renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | other_renewables__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__twh_growth__direct | 2 | major | Annual change in other renewables consumption | In terms of direct primary energy | Figures are based on gross generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
ca75e5920c2e1e9133a2d94ffbc89e27 | ac7424097805d393bd44f9107650cd12 | ||||||||||||||
944048 | Other renewables (% growth) | % | 2024-06-25 14:50:41 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | % | { "name": "Other renewables", "unit": "%", "shortUnit": "%" } |
0 | other_renewables__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__pct_growth | 2 | major | Annual percentage change in other renewables consumption | Figures are based on gross generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
9f6e2bdd2bf23aeedfb1eab28418d62e | 5137b1d7b796822e7a61c3ab9d4ecddb | |||||||||||||||
944046 | Nuclear (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:41 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Nuclear", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | nuclear__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear__twh_growth__equivalent | 2 | major | Annual change in nuclear power consumption | Using the substitution method | Input-equivalent energy is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
ceae9c94eecd2531b8f2221dc004e4d5 | 2ed1bb7439ef9bf76a70826612098565 | ||||||||||||||
944043 | Nuclear (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:41 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Nuclear", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | nuclear__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear__twh_growth__direct | 2 | major | Annual change in nuclear power consumption | In terms of direct primary energy | Figures are based on gross generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
1d28dacfd57d4c65242f7760a7841561 | b0b37ece449afcf17f8d0a083bcfe05a | ||||||||||||||
944041 | Nuclear (% growth) | % | 2024-06-25 14:50:41 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | % | { "name": "Nuclear", "unit": "%", "shortUnit": "%" } |
0 | nuclear__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear__pct_growth | 2 | major | Annual percentage change in nuclear power consumption | Figures are based on gross generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
f498ee189333a363569a83f622d411c3 | 8d79b5680ed69dd4afb8b96a9033f6c1 | |||||||||||||||
944039 | Low-carbon energy (% growth) | % | 2024-06-25 14:50:40 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | % | { "name": "Low-carbon energy", "unit": "%", "shortUnit": "%" } |
0 | low_carbon_energy__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__pct_growth | 2 | major | Annual percentage change in low-carbon energy consumption | Figures are based on gross generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
f8bc048c510d97faee75f6a34050961f | 3827525c3993ce9616417623aad606e0 | |||||||||||||||
944038 | Low-carbon energy (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:40 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Low-carbon energy", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | low_carbon_energy__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__twh_growth__equivalent | 2 | major | Annual change in low-carbon energy consumption | Using the substitution method | Input-equivalent energy is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
ae9975efa584ca47b8a875f58eacdc30 | 6bbf6632280c5a62e174517dcee89f81 | ||||||||||||||
944037 | Low-carbon energy (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:40 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Low-carbon energy", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | low_carbon_energy__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__twh_growth__direct | 2 | major | Annual change in low-carbon energy consumption | In terms of direct primary energy | Figures are based on gross generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
cc1cf155f847b42bb3ffbe5f1608f142 | 2b4f19e62aa0b58a128bec271104d0d0 | ||||||||||||||
944036 | Hydro (TWh growth - equivalent) | terawatt-hours | 2024-06-25 14:50:40 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Hydro", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | hydro__twh_growth__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__twh_growth__equivalent | 2 | major | Annual change in hydropower consumption | Using the substitution method | Input-equivalent energy is based on gross generation and does not account for cross-border electricity supply. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
d70c4432050a35a187b469d2187b318a | 6a2def5cdbc96d9173d9ad890a46a0fd | ||||||||||||||
944034 | Hydro (TWh growth - direct) | terawatt-hours | 2024-06-25 14:50:40 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Hydro", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | hydro__twh_growth__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__twh_growth__direct | 2 | major | Annual change in hydropower consumption | In terms of direct primary energy | Figures are based on gross primary hydroelectric generation and do not account for cross-border electricity supply. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
67b5b5c59633872d18587fa91e09d625 | 8b5f7d886d7fec011b604397f603dde9 | ||||||||||||||
944027 | Hydro (% growth) | % | 2024-06-25 14:50:39 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | % | { "name": "Hydro", "unit": "%", "shortUnit": "%" } |
0 | hydro__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__pct_growth | 2 | major | Annual percentage change in hydropower consumption | Figures are based on gross primary hydroelectric generation and do not account for cross-border electricity supply. | [] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
cea2aec2a2eb769a969faf3436a5be13 | 665bb70280f7826ee5b5f14b9beefd8d | |||||||||||||||
944025 | Biofuels (TWh growth) | terawatt-hours | 2024-06-25 14:50:39 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Biofuels", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | biofuels__twh_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#biofuels__twh_growth | 2 | major | Annual change in biofuel consumption | Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content. | [ "Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
a2466ce93453f7d4410fdfacf1fa7fbc | c3f93b3fd3783e331ed407f47d0102c0 | |||||||||||||||
944023 | Biofuels (% growth) | % | 2024-06-25 14:50:39 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | % | { "name": "Biofuels", "unit": "%", "shortUnit": "%" } |
0 | biofuels__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#biofuels__pct_growth | 2 | major | Annual percentage change in biofuel consumption | Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content. | [ "Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
7722e0f59ff4f67d0c7e779a7d012da0 | 664a777a4a6b446e1e4a1fe34871c204 | |||||||||||||||
944022 | Oil (TWh growth) | terawatt-hours | 2024-06-25 14:50:39 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Oil", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | oil__twh_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#oil__twh_growth | 2 | major | Annual change in oil consumption | [ "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
e657e18ab92ab99318ca855a25b949e3 | a576c08ce8a46c4c627f59531d572823 | ||||||||||||||||
944018 | Oil (% growth) | % | 2024-06-25 14:50:39 | 2024-07-25 23:08:54 | 1966-2023 | Energy mix 6590 | % | { "name": "Oil", "unit": "%", "shortUnit": "%" } |
0 | oil__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#oil__pct_growth | 2 | major | Annual percentage change in oil consumption | [ "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
7707229fff6ac3e62de3fb2f0f06761a | 2d35d22341a8cd3169b318c2c0efce19 | ||||||||||||||||
944016 | Gas (TWh growth) | terawatt-hours | 2024-06-25 14:50:38 | 2024-07-25 23:08:53 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Gas", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | gas__twh_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#gas__twh_growth | 2 | major | Annual change in gas consumption | [ "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
4dc190bf131e44a5233deb4a7ada33d1 | 56727a0b0e4b83d01fafd00a87d343ac | ||||||||||||||||
944014 | Gas (% growth) | % | 2024-06-25 14:50:38 | 2024-07-25 23:08:53 | 1966-2023 | Energy mix 6590 | % | { "name": "Gas", "unit": "%", "shortUnit": "%" } |
0 | gas__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#gas__pct_growth | 2 | major | Annual percentage change in gas consumption | [ "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
f23eaa25021a42094ffac66ca657266f | ab0f5afd0b8bda2b003cc59df0a8cec1 | ||||||||||||||||
944013 | Fossil fuels (TWh growth) | terawatt-hours | 2024-06-25 14:50:38 | 2024-07-25 23:08:53 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Fossil fuels", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | fossil_fuels__twh_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#fossil_fuels__twh_growth | 2 | major | Annual change in fossil fuel consumption | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
6784429695c877d12325cf8e85baff41 | d43450d81a8afd73ab44070515d50e69 | ||||||||||||||||
944012 | Fossil fuels (% growth) | % | 2024-06-25 14:50:38 | 2024-07-25 23:08:53 | 1966-2023 | Energy mix 6590 | % | { "name": "Fossil fuels", "unit": "%", "shortUnit": "%" } |
0 | fossil_fuels__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#fossil_fuels__pct_growth | 2 | major | Annual percentage change in fossil fuel consumption | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
45ff12e4b7f9edfe4fffe5875f60874a | f24ee03fc22b685f53647459b5e1a8f1 | ||||||||||||||||
944011 | Coal (TWh growth) | terawatt-hours | 2024-06-25 14:50:38 | 2024-07-25 23:08:53 | 1966-2023 | Energy mix 6590 | TWh | { "name": "Coal", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | coal__twh_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#coal__twh_growth | 2 | major | Annual change in coal consumption | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
d57afb4e6ca4a8537d7fd7470facbeb0 | 1d8760788508242387835c5bfb029608 | ||||||||||||||||
944009 | Coal (% growth) | % | 2024-06-25 14:50:38 | 2024-07-25 23:08:53 | 1966-2023 | Energy mix 6590 | % | { "name": "Coal", "unit": "%", "shortUnit": "%" } |
0 | coal__pct_growth | grapher/energy/2024-06-20/energy_mix/energy_mix#coal__pct_growth | 2 | major | Annual percentage change in coal consumption | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data." ] |
The annual change in energy consumption by source is calculated as the difference with respect to the previous year. | float | [] |
047c5847d0dca60d63bd1abaf858e6e7 | 2cf422858d46b18feed1ad21903172bd | ||||||||||||||||
944007 | Solar and wind (% equivalent primary energy) | % | 2024-06-25 14:50:37 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Solar and wind", "unit": "%", "shortUnit": "%" } |
0 | solar_and_wind__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from solar and wind power | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
40f0960d1355df80bd514693cbed7449 | bca0c9992bce3a63a5120fec7916e3ec | |||||||||||||||
944005 | Solar and wind (% direct primary energy) | % | 2024-06-25 14:50:37 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Solar and wind", "unit": "%", "shortUnit": "%" } |
0 | solar_and_wind__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from solar and wind power | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
314f3549c39c5a1448c759dbff3acb70 | 8152de35a0db78e631164d4051ae0174 | |||||||||||||||
944004 | Wind (% equivalent primary energy) | % | 2024-06-25 14:50:37 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Wind", "unit": "%", "shortUnit": "%" } |
0 | wind__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from wind power | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
eca77a618e1644e6e15312f6662090a9 | d5e14e045f4f501d8439951ea4e8d1c3 | |||||||||||||||
944002 | Wind (% direct primary energy) | % | 2024-06-25 14:50:37 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Wind", "unit": "%", "shortUnit": "%" } |
0 | wind__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from wind power | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
da34e52c7d3f914ce342682064505471 | a47892a7c7ed538234d58e4b7a8f3cb5 | |||||||||||||||
944000 | Solar (% equivalent primary energy) | % | 2024-06-25 14:50:37 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Solar", "unit": "%", "shortUnit": "%" } |
0 | solar__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from solar power | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
d5eb505fad31f757ce7deb030baa90c3 | 80eb0c42578020d775e656db676b5e2d | |||||||||||||||
943999 | Renewables (% equivalent primary energy) | % | 2024-06-25 14:50:36 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Renewables", "unit": "%", "shortUnit": "%" } |
0 | renewables__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from renewables | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
6572ad775c898f420e756b5d5dab5618 | e41b7a33308c91ea0412dff110cd53e6 | |||||||||||||||
943997 | Solar (% direct primary energy) | % | 2024-06-25 14:50:36 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Solar", "unit": "%", "shortUnit": "%" } |
0 | solar__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from solar power | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
88718741de6a5da5f8f703203074f421 | f8c06604cd1f621e29f437a838c15495 | |||||||||||||||
943995 | Renewables (% direct primary energy) | % | 2024-06-25 14:50:36 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Renewables", "unit": "%", "shortUnit": "%" } |
0 | renewables__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from renewables | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
d6ee07fd7d5e4bc62f486ccc07775a1c | 59e391aa6741ba1c99f3d80a56e36220 | |||||||||||||||
943994 | Other renewables (% equivalent primary energy) | % | 2024-06-25 14:50:36 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Other renewables", "unit": "%", "shortUnit": "%" } |
0 | other_renewables__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from other renewables | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
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943993 | Other renewables (% direct primary energy) | % | 2024-06-25 14:50:36 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Other renewables", "unit": "%", "shortUnit": "%" } |
0 | other_renewables__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from other renewables | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
fe7819730e4f4d9855d1c7a938ffb606 | b52d279c56bc4cc750d9fbff52b88468 | |||||||||||||||
943992 | Nuclear (% equivalent primary energy) | % | 2024-06-25 14:50:36 | 2024-07-25 23:08:53 | 1965-2023 | Energy mix 6590 | % | { "name": "Nuclear", "unit": "%", "shortUnit": "%" } |
0 | nuclear__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from nuclear power | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
c0c4e15d68c819ad210352482e78e78e | 525abbae1926914ca30efb69779c2138 | |||||||||||||||
943990 | Nuclear (% direct primary energy) | % | 2024-06-25 14:50:35 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Nuclear", "unit": "%", "shortUnit": "%" } |
0 | nuclear__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from nuclear power | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
5d6f4464420693028fda6d910f92da0e | 3e8491b1d3b5dd73ff57248ea68134b5 | |||||||||||||||
943989 | Low-carbon energy (% equivalent primary energy) | % | 2024-06-25 14:50:35 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Low-carbon energy", "unit": "%", "shortUnit": "%" } |
0 | low_carbon_energy__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from low-carbon sources | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
1faced6e1ab102bd611e69335f559aed | 7b980dfae021745f1abdf2ab2cedbc17 | |||||||||||||||
943988 | Low-carbon energy (% direct primary energy) | % | 2024-06-25 14:50:35 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Low-carbon energy", "unit": "%", "shortUnit": "%" } |
0 | low_carbon_energy__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from low-carbon sources | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
e4377c5bf919e2ae7711984371b62e8e | e24f098eaf6d8bc09d62c74ccdc91b54 | |||||||||||||||
943987 | Hydro (% equivalent primary energy) | % | 2024-06-25 14:50:35 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Hydro", "unit": "%", "shortUnit": "%" } |
0 | hydro__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from hydropower | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
e3e6ee61a821147f59708ae05f61db69 | 79c832cef0a4808d4b63e7d15dbb2486 | |||||||||||||||
943986 | Biofuels (% equivalent primary energy) | % | 2024-06-25 14:50:35 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Biofuels", "unit": "%", "shortUnit": "%" } |
0 | biofuels__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#biofuels__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from biofuels | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
43eb079283cbbb03c2e5220ec002a881 | e785806d78741862b96ddbd46d78dd91 | |||||||||||||||
943985 | Hydro (% direct primary energy) | % | 2024-06-25 14:50:35 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Hydro", "unit": "%", "shortUnit": "%" } |
0 | hydro__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from hydropower | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
8ec1deef8229197052e615e546266b11 | 06e1797a10566df39673495932e554a0 | |||||||||||||||
943982 | Biofuels (% direct primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Biofuels", "unit": "%", "shortUnit": "%" } |
0 | biofuels__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#biofuels__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from biofuels | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
dd8c7b7047b6f1a02c433f6b8d9af0d9 | 75003ffff69ea72309bbe690c64d99eb | |||||||||||||||
943980 | Oil (% equivalent primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Oil", "unit": "%", "shortUnit": "%" } |
0 | oil__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#oil__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from oil | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
ddc3aa41cf878e4069e259ba48d3e755 | 2b05662fbe55389fd04f67c0ab985a83 | |||||||||||||||
943977 | Oil (% direct primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Oil", "unit": "%", "shortUnit": "%" } |
0 | oil__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#oil__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from oil | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
9443fbae4031044fa31984751bb7fa4b | 5e22e6ea0cfb584fc40163cb9a05a438 | |||||||||||||||
943973 | Gas (% direct primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Gas", "unit": "%", "shortUnit": "%" } |
0 | gas__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#gas__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from gas | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data.", "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data." ] |
float | [] |
7582e247243354e2e7e0110ae2508346 | 3d8a537f287dd853064adfcafa08026b | |||||||||||||||
943972 | Gas (% equivalent primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Gas", "unit": "%", "shortUnit": "%" } |
0 | gas__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#gas__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from gas | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data.", "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data." ] |
float | [] |
767f61e5991e233797ab3aa5dd6bb297 | 6d986dc32e2f5bf7fdd2373bbb087f58 | |||||||||||||||
943970 | Fossil fuels (% equivalent primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Fossil fuels", "unit": "%", "shortUnit": "%" } |
0 | fossil_fuels__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#fossil_fuels__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from fossil fuels | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
float | [] |
f7d84f845b0a24c5bfc6b88b6ae0feb9 | a683e47bd9335638043e15be23fdefb4 | |||||||||||||||
943967 | Fossil fuels (% direct primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Fossil fuels", "unit": "%", "shortUnit": "%" } |
0 | fossil_fuels__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#fossil_fuels__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from fossil fuels | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
float | [] |
cd33e871111cd1eee0f7324f4cb2f439 | d495fb47b05edcad58f73383d5477ac2 | |||||||||||||||
943964 | Coal (% equivalent primary energy) | % | 2024-06-25 14:50:34 | 2024-07-25 23:08:52 | 1965-2023 | Energy mix 6590 | % | { "name": "Coal", "unit": "%", "shortUnit": "%" } |
0 | coal__pct_equivalent_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#coal__pct_equivalent_primary_energy | 2 | major | Share of primary energy consumption that comes from coal | Using the substitution method | Measured as a percentage of the total primary energy, using the substitution method. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
float | [] |
6e99e421863f1d111bd75bee1f8e3723 | 2736e9f5a1440ab7c08402d8d3a71a01 | |||||||||||||||
943959 | Coal (% direct primary energy) | % | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | % | { "name": "Coal", "unit": "%", "shortUnit": "%" } |
0 | coal__pct_direct_primary_energy | grapher/energy/2024-06-20/energy_mix/energy_mix#coal__pct_direct_primary_energy | 2 | major | Share of direct primary energy consumption that comes from coal | In terms of direct primary energy | Measured as a percentage of the total (direct) primary energy. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
float | [] |
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943957 | Primary energy (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Primary energy", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | primary_energy__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#primary_energy__twh__equivalent | 2 | major | Primary energy consumption | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
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943954 | Solar and wind (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Solar and wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar_and_wind__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__twh__equivalent | 2 | major | Primary energy consumption from solar and wind power | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
51824984b8c1e72fa680a54d8eba69d6 | d1751aed7ee31e4b20db3d15c4ecd782 | |||||||||||||||
943952 | Low-carbon energy (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Low-carbon energy", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | low_carbon_energy__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__twh__equivalent | 2 | major | Primary energy consumption from low-carbon sources | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
c2cef320ad41784593b9fc9f8d4fc361 | 7ed590fe06db9f9208bbe4d5417a5fac | |||||||||||||||
943948 | Renewables (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | renewables__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__twh__equivalent | 2 | major | Primary energy consumption from renewables | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
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943943 | Primary energy (TWh - direct) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Primary energy", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | primary_energy__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#primary_energy__twh__direct | 2 | major | Primary energy consumption | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
float | [] |
56bd9cc58ebae87678e6b6418b5ffbc1 | 9acaba94607317dfb723452ca0c73d9c | |||||||||||||||
943940 | Solar and wind (TWh - direct) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Solar and wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar_and_wind__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#solar_and_wind__twh__direct | 2 | major | Primary energy consumption from solar and wind power | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
afd3d7f5dabc6cb2787bb9ecbc8711c7 | 5fe042b598681dbc4de22dfc582700c5 | |||||||||||||||
943936 | Renewables (TWh - direct) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | renewables__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#renewables__twh__direct | 2 | major | Primary energy consumption from renewables | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [] |
float | [] |
f906dfbd3efc09b9d54b6df23c7f46f0 | f94640fb503fdbaffd66f3ff257f2c60 | |||||||||||||||
943934 | Low-carbon energy (TWh - direct) | terawatt-hours | 2024-06-25 14:50:33 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Low-carbon energy", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | low_carbon_energy__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#low_carbon_energy__twh__direct | 2 | major | Primary energy consumption from low-carbon sources | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
86e1d168218f07a545e836fcd748bebe | f77152d2cfd78c0823c08317e3f68b40 | |||||||||||||||
943926 | Fossil fuels (TWh) | terawatt-hours | 2024-06-25 14:50:32 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Fossil fuels", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | fossil_fuels__twh | grapher/energy/2024-06-20/energy_mix/energy_mix#fossil_fuels__twh | 2 | major | Primary energy consumption from fossil fuels | Measured in terawatt-hours. | [ "Includes commercial solid fuels only, i.e. bituminous coal and anthracite (hard coal), and lignite and brown (sub-bituminous) coal, and other commercial solid fuels. Excludes coal converted to liquid or gaseous fuels, but includes coal consumed in transformation processes. Differences between the consumption figures and the world production statistics are accounted for by stock changes, and unavoidable disparities in the definition, measurement or conversion of coal supply and demand data.", "Includes inland demand plus international aviation and marine bunkers and refinery fuel and loss. Consumption of biogasoline (such as ethanol) and biodiesel are excluded while derivatives of coal and natural gas are included. Differences between the world consumption figures and world production statistics are accounted for by stock changes, consumption of non-petroleum additives and substitute fuels and unavoidable disparities in the definition, measurement or conversion of oil supply and demand data.", "Excludes natural gas converted to liquid fuels but includes derivatives of coal as well as natural gas consumed in Gas-to-Liquids transformation. The difference between the world consumption figures and the world production statistics is due to variations in stocks at storage facilities and liquefaction plants, together with unavoidable disparities in the definition, measurement or conversion of gas supply and demand data." ] |
float | [] |
d023ca51550d1e89b7e49fb659758dfd | 45f7e4f77d986b82c4b3d3e557b8f4a2 | ||||||||||||||||
943922 | Biofuels (TWh) | terawatt-hours | 2024-06-25 14:50:32 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Biofuels", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | biofuels__twh | grapher/energy/2024-06-20/energy_mix/energy_mix#biofuels__twh | 2 | major | Primary energy consumption from biofuels | Measured in terawatt-hours. | [ "Includes biogasoline (such as ethanol) and biodiesel. Volumes have been adjusted for energy content." ] |
float | [] |
c80fb3a6e22686e8b2c847939d44d0a9 | 8bb1e237db00ea09af0cb2661e5bd140 | ||||||||||||||||
943919 | Other renewables (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:32 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Other renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | other_renewables__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__twh__equivalent | 2 | major | Primary energy consumption from other renewables | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
5af9d90af154ed75e428623204c7df49 | f98bc84f1b4712b38c3c26445fba9497 | |||||||||||||||
943916 | Wind (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:32 | 2024-07-25 23:08:51 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | wind__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__twh__equivalent | 2 | major | Primary energy consumption from wind power | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
c9e0f1a64024b69efe52c0989bb231a0 | 892bcc4080184d59b1f095efae347103 | |||||||||||||||
943911 | Solar (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:32 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Solar", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__twh__equivalent | 2 | major | Primary energy consumption from solar power | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
18ec49bb1508526b2854db69f28d1180 | d11c8241076455b00a076c1aa5bfc10d | |||||||||||||||
943900 | Nuclear (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:31 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Nuclear", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | nuclear__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#nuclear__twh__equivalent | 2 | major | Primary energy consumption from nuclear power | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
05e47134fef2f2e5eafb184b95325ade | c2640d881f24ee8b0a1ca9fab532b5c1 | |||||||||||||||
943899 | Wind (TWh - direct) | terawatt-hours | 2024-06-25 14:50:31 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Wind", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | wind__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#wind__twh__direct | 2 | major | Primary energy consumption from wind power | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
1d9bfc941ba295c39f51919d43af3f0d | 93c16b79c6cc4292cad924de801f455d | |||||||||||||||
943895 | Hydro (TWh - equivalent) | terawatt-hours | 2024-06-25 14:50:31 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Hydro", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | hydro__twh__equivalent | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__twh__equivalent | 2 | major | Primary energy consumption from hydropower | Using the substitution method | Measured in terawatt-hours, using the substitution method. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Primary energy is measured using the \"substitution method\" (also called \"input-equivalent\" primary energy). This method is used for non-fossil sources of electricity (namely renewables and nuclear), and measures the amount of fossil fuels that would be required by thermal power stations to generate the same amount of non-fossil electricity.\nFor example, if a country's nuclear power generated 100 TWh of electricity, and assuming that the efficiency of a standard thermal power plant is 38%, the input-equivalent primary energy for this country would be 100 TWh / 0.38 = 263 TWh = 0.95 EJ. This input-equivalent primary energy takes account of the inefficiencies in energy production from fossil fuels and provides a better approximation of each source's share of energy consumption. You can find more details in [the Statistical Review of World Energy's methodology document](https://www.energyinst.org/__data/assets/pdf_file/0003/1055541/Methodology.pdf)." ] |
float | [] |
e8b8952f5fbfdd862451af49cbd288d0 | 89a91d2e8b630ff4915c541c001193ed | |||||||||||||||
943891 | Other renewables (TWh - direct) | terawatt-hours | 2024-06-25 14:50:31 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Other renewables", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | other_renewables__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#other_renewables__twh__direct | 2 | major | Primary energy consumption from other renewables | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
e07180a41925a204e885c5ef2e1bd9a0 | 67421a7425d166285369f252e211637f | |||||||||||||||
943887 | Solar (TWh - direct) | terawatt-hours | 2024-06-25 14:50:30 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Solar", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | solar__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#solar__twh__direct | 2 | major | Primary energy consumption from solar power | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
dbf882ef607c0756448a9231daef2ec8 | 997f743ce70272c9d2f0a9b26389e217 | |||||||||||||||
943885 | Hydro (TWh - direct) | terawatt-hours | 2024-06-25 14:50:30 | 2024-07-25 23:08:50 | 1965-2023 | Energy mix 6590 | TWh | { "name": "Hydro", "unit": "terawatt-hours", "shortUnit": "TWh" } |
0 | hydro__twh__direct | grapher/energy/2024-06-20/energy_mix/energy_mix#hydro__twh__direct | 2 | major | Primary energy consumption from hydropower | In terms of direct primary energy | Measured in terawatt-hours of direct primary energy. | [ "Figures are based on gross generation and do not account for cross-border electricity supply.", "Direct primary energy of non-fossil electricity sources corresponds to electricity generation." ] |
float | [] |
4c3b8011a251e734fad421a49c490051 | 6640d96993d1ab264edd1b1809906071 |
Advanced export
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CREATE TABLE "variables" ( "id" INTEGER PRIMARY KEY AUTOINCREMENT, "name" VARCHAR(750) NULL , "unit" VARCHAR(255) NOT NULL , "description" TEXT NULL , "createdAt" DATETIME NOT NULL DEFAULT CURRENT_TIMESTAMP , "updatedAt" DATETIME NULL , "code" VARCHAR(255) NULL , "coverage" VARCHAR(255) NOT NULL , "timespan" VARCHAR(255) NOT NULL , "datasetId" INTEGER NOT NULL , "sourceId" INTEGER NULL , "shortUnit" VARCHAR(255) NULL , "display" TEXT NOT NULL , "columnOrder" INTEGER NOT NULL DEFAULT '0' , "originalMetadata" TEXT NULL , "grapherConfigAdmin" TEXT NULL , "shortName" VARCHAR(255) NULL , "catalogPath" VARCHAR(767) NULL , "dimensions" TEXT NULL , "schemaVersion" INTEGER NOT NULL DEFAULT '1' , "processingLevel" VARCHAR(30) NULL , "processingLog" TEXT NULL , "titlePublic" VARCHAR(512) NULL , "titleVariant" VARCHAR(255) NULL , "attributionShort" VARCHAR(512) NULL , "attribution" TEXT NULL , "descriptionShort" TEXT NULL , "descriptionFromProducer" TEXT NULL , "descriptionKey" TEXT NULL , "descriptionProcessing" TEXT NULL , "licenses" TEXT NULL , "license" TEXT NULL , "grapherConfigETL" TEXT NULL , "type" TEXT NULL , "sort" TEXT NULL , "dataChecksum" VARCHAR(64) NULL , "metadataChecksum" VARCHAR(64) NULL, FOREIGN KEY("datasetId") REFERENCES "datasets" ("id") ON UPDATE RESTRICT ON DELETE RESTRICT, FOREIGN KEY("sourceId") REFERENCES "sources" ("id") ON UPDATE RESTRICT ON DELETE RESTRICT ); CREATE UNIQUE INDEX "idx_catalogPath" ON "variables" ("catalogPath"); CREATE UNIQUE INDEX "unique_short_name_per_dataset" ON "variables" ("shortName", "datasetId"); CREATE UNIQUE INDEX "variables_code_fk_dst_id_7bde8c2a_uniq" ON "variables" ("code", "datasetId"); CREATE INDEX "variables_datasetId_50a98bfd_fk_datasets_id" ON "variables" ("datasetId"); CREATE UNIQUE INDEX "variables_name_fk_dst_id_f7453c33_uniq" ON "variables" ("name", "datasetId"); CREATE INDEX "variables_sourceId_31fce80a_fk_sources_id" ON "variables" ("sourceId");