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World energy supply: Difference between revisions
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'''World energy supply''' refers to the global production and preparation of fuel (fossil and nuclear), generation of electricity, and energy transport. Here contemporary energy supply is outlined, statistical data rather than policy. Energy supply is a vast industry, powering the world economy. More than 10% of the world expenditures is used for energy purposes.<ref>[http://www.leonardo-energy.org/blog/world-energy-expenditures Energy expenditures]</ref> | '''World energy supply''' refers to the global production and preparation of fuel (fossil and nuclear), generation of electricity, and energy transport. Here contemporary energy supply is outlined, statistical data rather than policy. Energy supply is a vast industry, powering the world economy. More than 10% of the world expenditures is used for energy purposes.<ref>[http://www.leonardo-energy.org/blog/world-energy-expenditures Energy expenditures]</ref> | ||
Short lists of countries are given where most energy is produced<ref>Energy is used in the economic sense, not in the physical sense where it is conserved</ref> and where it is consumed, distinguishing fossil, nuclear and renewable energy. Of all produced energy 80% is fossil. Half of that is produced by China, the United States and the Persian Gulf States. The Gulf States and Norway export most of their production, largely to the European Union and Japan where not sufficient energy is produced to satisfy their users. | Short lists of countries are given where most energy is produced<ref>Energy is used in the economic sense, not in the physical sense where it is conserved</ref> and where it is consumed, distinguishing fossil, nuclear and renewable energy. Of all produced energy 80% is fossil. Half of that is produced by China, the [[United States]] and the Persian Gulf States. The Gulf States and Norway export most of their production, largely to the European Union and Japan where not sufficient energy is produced to satisfy their users. Energy production increases slowly, except for solar and wind energy which grows more than 20% per year. | ||
Produced energy, for instance crude oil, must be processed to make it suitable for consumption by end users. So the supply chain between production and final consumption involves many conversion activities and much trade and transport among countries. | Produced energy, for instance crude oil, must be processed to make it suitable for consumption by end users. So the supply chain between production and final consumption involves many conversion activities and much trade and transport among countries, causing a loss of one third of energy before it is consumed. | ||
Institutions such as the International Energy Agency (IEA) and the U.S. Energy Information Administration (EIA) collect, | Institutions such as the International Energy Agency (IEA) and the U.S. Energy Information Administration (EIA) collect, analyze and publish comprehensive energy data periodically. In the country lists below these data are used. | ||
In view of contemporary energy policy of countries the IEA expects<ref name="outlook">{{cite web|title=World Energy Outlook 2016|url=http://www.iea.org/Textbase/npsum/WEO2016SUM.pdf|website=International Energy Agency|publisher=IEA}}</ref> that the worldwide energy consumption in 2040 will have increased 30% and that the goal, set in the Paris Agreement about Climate Change, will not nearly be reached. The IEA concludes that a major reallocation of investment capital in the energy sector is required. | Worldwide carbon dioxide emission from fuel combustion was 32 gigaton in 2013.<ref>http://www.iea.org/statistics/statisticssearch/report/?year=2013&country=WORLD&product=Indicators</ref> In view of contemporary energy policy of countries the IEA expects<ref name="outlook">{{cite web|title=World Energy Outlook 2016|url=http://www.iea.org/Textbase/npsum/WEO2016SUM.pdf|website=International Energy Agency|publisher=IEA}}</ref> that the worldwide energy consumption in 2040 will have increased 30% and that the goal, set in the Paris Agreement about Climate Change, will not nearly be reached. The IEA concludes that a major reallocation of investment capital in the energy sector is required. | ||
== Energy production == | == Energy production == | ||
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The table lists the world-wide production and the countries/regions producing most (90%) of that. | The table lists the world-wide production and the countries/regions producing most (90%) of that. | ||
The Persian Gulf States are Saudi Arabia, Iran, Qatar, Arab Emirates, Kuwait, Iraq and Oman, in order of production. | The Persian Gulf States are Saudi Arabia, Iran, Qatar, Arab Emirates, Kuwait, Iraq and Oman, in order of production. | ||
The amounts are given in million tonnes of oil equivalent per year (Mtoe/a, 1 Mtoe = 11.63 TWh). The data are of 2013.<ref name=balances>[http://www.iea.org/statistics/statisticssearch/ IEA Statistics search] | The amounts are given in million tonnes of oil equivalent per year (Mtoe/a, 1 Mtoe = 11.63 TWh). The data are of 2013.<ref name=balances>[http://www.iea.org/statistics/statisticssearch/ IEA Statistics search] select Country/Region, Balances, Year.</ref><ref>The International Energy Agency uses the energy unit Mtoe. Corresponding data are presented by the US Energy Information Administration http://www.eia.doe.gov/ expressed in quads. 1 quad = 10<sup>15</sup> BTU = 25.2 Mtoe. The US EIA follows different rules to assess renewable electricity generation. | ||
See [http://www.eia.gov/tools/glossary/index.cfm EIA Glossary], Primary energy production.</ref> | See [http://www.eia.gov/tools/glossary/index.cfm EIA Glossary], Primary energy production.</ref> | ||
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| Kazakhstan ||align="right"| 169 ||align="right"| 31% ||align="right"| 69% ||align="right"| 0% ||align="right"| 0% | | Kazakhstan ||align="right"| 169 ||align="right"| 31% ||align="right"| 69% ||align="right"| 0% ||align="right"| 0% | ||
|} | |} | ||
Two third of the world renewable supply is non-commercial solid biofuel in developing countries.<ref name="trend">[http://www.iea.org/publications/freepublications/publication/KeyRenewablesTrends.pdf IEA Key Renewables Trends]</ref> | |||
The top producers of the USA are Texas 20%, Wyoming 11%, Pennsylvania 8%, W Virginia 5% and Oklahoma 4%. <ref>[http://www.eia.gov/state/?sid=US EIA US Overview]</ref> | The top producers of the USA are Texas 20%, Wyoming 11%, Pennsylvania 8%, W Virginia 5% and Oklahoma 4%. <ref>[http://www.eia.gov/state/?sid=US EIA US Overview]</ref> | ||
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In the EU France (136, mainly nuclear), Germany (120), UK (110), Poland (71, mainly coal) and Netherlands (69, mainly natural gas) produce most. | In the EU France (136, mainly nuclear), Germany (120), UK (110), Poland (71, mainly coal) and Netherlands (69, mainly natural gas) produce most. | ||
=== Trend === | |||
From 2012 to 2014 worldwide production increased 3%, nuclear and fossil rose at about the same rate, renewables increased 6%.<ref>Compare World: [http://www.iea.org/statistics/statisticssearch/ Balances] for 2012 and 2014.</ref> | |||
A small part of the renewables, solar and wind energy, increased much more, 46% in this period<ref name="electrheat">[http://www.iea.org/statistics/statisticssearch/ IEA Statistics search], select Country/Region, Electricity and Heat.</ref> in line with the strong growth since 1990.<ref name="trend" /> | |||
In Brazil windpower inceased 140%, in China not only solar and wind increased fast, 81%, but also nuclear production, 36% from 2012 to 2014.<ref name="electrheat" /> | |||
== Between production and final consumption == | == Between production and final consumption == | ||
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| India ||align="right"| 72 ||align="right"| 327 | | India ||align="right"| 72 ||align="right"| 327 | ||
|- | |- | ||
| S-Korea ||align="right"| 57 ||align="right"| 291 | | [[South Korea|S-Korea]] ||align="right"| 57 ||align="right"| 291 | ||
|} | |} | ||
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* Fossil fuel: natural gas, fuel derived from petroleum (LPG, gasoline, kerosene, gas/diesel, fuel oil), from coal (anthracite, bituminous coal, coke, lignite, blast furnace gas) | * Fossil fuel: natural gas, fuel derived from petroleum (LPG, gasoline, kerosene, gas/diesel, fuel oil), from coal (anthracite, bituminous coal, coke, lignite, blast furnace gas) | ||
* Renewable fuel: biofuel and fuel derived from waste, so far as it is traded. | * Renewable fuel: biofuel and fuel derived from waste, so far as it is traded. | ||
* District heating.<ref>In energy statistics this is not part of fuel but a separate part of final consumption | * District heating.<ref>In energy statistics this is not part of fuel but a separate part of final consumption like electricity, see [http://www.iea.org/statistics/statisticssearch/ IEA Statistics search], select Country/Region, Electricity and Heat.</ref> | ||
The amounts are based on lower heating value. | The amounts are based on lower heating value. | ||
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| Norway ||align="right"| 9 ||align="right"| 11% ||align="right"| 9 ||align="right"| 98% ||align="right"| 3.6 | | Norway ||align="right"| 9 ||align="right"| 11% ||align="right"| 9 ||align="right"| 98% ||align="right"| 3.6 | ||
|} | |} | ||
=== Energy for energy === | |||
Some fuel end electricity is used to construct, maintain and demolish/recycle installations that produce fuel and electricity, such as oil rigs, uranium isotope separators and wind turbines. | |||
For these producers to be economic the ratio of '''energy returned on energy invested''' (EROEI) or '''energy return on investment''' (EROI) should be large enough. | |||
There is little consensus in the technical literature about methods and results in calculating these ratios, but it is likely that for fuels (fossil and nuclear), hydro power and wind turbines the ratio is at least 10, for solar panels about 7 and for solar collectors (hot water) only 2.<ref>Charles Hall, http://www.theoildrum.com/node/3810 (2008).</ref> | |||
In southern European countries solar EROEI exceeds ten<ref>Ugo Bardi, http://http://www.resilience.org/stories/2016-05-24/but-what-s-the-real-energy-return-of-photovoltaic-energy/ (2016).</ref> but more to the North it is less as it takes a greater part of the life time to regain the invested energy, | |||
== Outlook until 2040 == | == Outlook until 2040 == | ||
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"Providing all global energy with wind, water, and solar power" in [[Mark Jacobson]]. | "Providing all global energy with wind, water, and solar power" in [[Mark Jacobson]]. | ||
== Notes | == Notes == | ||
{{refs}} | |||
[[Category:energy policy]] |
Latest revision as of 20:16, 27 February 2019
World energy supply refers to the global production and preparation of fuel (fossil and nuclear), generation of electricity, and energy transport. Here contemporary energy supply is outlined, statistical data rather than policy. Energy supply is a vast industry, powering the world economy. More than 10% of the world expenditures is used for energy purposes.[1]
Short lists of countries are given where most energy is produced[2] and where it is consumed, distinguishing fossil, nuclear and renewable energy. Of all produced energy 80% is fossil. Half of that is produced by China, the United States and the Persian Gulf States. The Gulf States and Norway export most of their production, largely to the European Union and Japan where not sufficient energy is produced to satisfy their users. Energy production increases slowly, except for solar and wind energy which grows more than 20% per year.
Produced energy, for instance crude oil, must be processed to make it suitable for consumption by end users. So the supply chain between production and final consumption involves many conversion activities and much trade and transport among countries, causing a loss of one third of energy before it is consumed.
Institutions such as the International Energy Agency (IEA) and the U.S. Energy Information Administration (EIA) collect, analyze and publish comprehensive energy data periodically. In the country lists below these data are used.
Worldwide carbon dioxide emission from fuel combustion was 32 gigaton in 2013.[3] In view of contemporary energy policy of countries the IEA expects[4] that the worldwide energy consumption in 2040 will have increased 30% and that the goal, set in the Paris Agreement about Climate Change, will not nearly be reached. The IEA concludes that a major reallocation of investment capital in the energy sector is required.
Energy production
World primary energy production | ||||
Note the different y-axis for world (left) en regional (right) production |
This is the world-wide production of primary energy (PE) from fossil, nuclear and renewable sources. Primary means: extracted or captured directly from natural sources. Note the strong production increase of China.
Energy sources are usually classified as
- fossil, using coal, lignite, petroleum and natural gas,
- nuclear, using uranium,
- renewable, using hydro power, biomass, wind and solar energy, among others.
Primary energy assessment follows certain rules[6] to ease measurement and comparison of different kinds of energy. Due to these rules uranium is not counted as PE but as the natural source of nuclear PE. Similarly water and air flow energy that drives hydro and wind turbines, and sunlight that powers solar panels, are not taken as PE but as PE sources (PES).
The table lists the world-wide production and the countries/regions producing most (90%) of that. The Persian Gulf States are Saudi Arabia, Iran, Qatar, Arab Emirates, Kuwait, Iraq and Oman, in order of production. The amounts are given in million tonnes of oil equivalent per year (Mtoe/a, 1 Mtoe = 11.63 TWh). The data are of 2013.[7][8]
Total Mtoe/a |
Coal | Oil & Gas | Nuclear | Renewable | |
---|---|---|---|---|---|
WORLD | 13600 | 29% | 52% | 5% | 14% |
China | 2560 | 74% | 12% | 1% | 13% |
United States | 1880 | 25% | 55% | 11% | 8% |
Persian Gulf States | 1742 | 0% | 100% | 0% | 0% |
Russia | 1316 | 14% | 81% | 3% | 2% |
Africa | 1129 | 13% | 53% | 0% | 33% |
European Union | 793 | 20% | 26% | 29% | 26% |
India | 523 | 46% | 13% | 2% | 39% |
Indonesia | 460 | 61% | 23% | 0% | 16% |
Canada | 435 | 8% | 75% | 6% | 11% |
Australia | 344 | 77% | 21% | 0% | 2% |
Brazil | 253 | 1% | 50% | 2% | 47% |
Mexico | 217 | 3% | 89% | 1% | 7% |
Venezuela | 192 | 0% | 96% | 0% | 4% |
Norway | 192 | 1% | 92% | 0% | 7% |
Kazakhstan | 169 | 31% | 69% | 0% | 0% |
Two third of the world renewable supply is non-commercial solid biofuel in developing countries.[9]
The top producers of the USA are Texas 20%, Wyoming 11%, Pennsylvania 8%, W Virginia 5% and Oklahoma 4%. [10]
The top producers in Africa are Nigeria (256), S-Africa (166) and Algeria (138).
In the EU France (136, mainly nuclear), Germany (120), UK (110), Poland (71, mainly coal) and Netherlands (69, mainly natural gas) produce most.
Trend
From 2012 to 2014 worldwide production increased 3%, nuclear and fossil rose at about the same rate, renewables increased 6%.[11]
A small part of the renewables, solar and wind energy, increased much more, 46% in this period[12] in line with the strong growth since 1990.[9]
In Brazil windpower inceased 140%, in China not only solar and wind increased fast, 81%, but also nuclear production, 36% from 2012 to 2014.[12]
Between production and final consumption
Primary energy is converted in many ways to energy carriers, also known as secondary energy.
- Lignite and coal mainly go to thermal power stations. Coke is derived by destructive distillation of bituminous coal.
- Crude oil goes mainly to oil refineries and is also used to generate electricity and to make coke.
- Natural-gas goes to processing plants to remove contaminants such as water, carbon dioxide and hydrogen sulfide, and mixed to adjust the heating value.
- Nuclear reaction heat is used to generate electricity.
- Biomass is converted to biofuel.
Electricity generators are driven by
Export | Import | |
---|---|---|
Persian Gulf States | 1167 | 21 |
Russia | 620 | 27 |
Indonesia | 301 | 56 |
Canada | 263 | 78 |
Norway | 166 | 8 |
European Union | 539 | 1451 |
Japan | 18 | 455 |
India | 72 | 327 |
S-Korea | 57 | 291 |
- Steam or gas turbines in a thermal plant,
- or water turbines in a hydropower station,
- or wind turbines, stand-alone or in a wind farm.
The invention of the PV cell in 1954 started electricity generation by solar panels, connected to a power inverter. Around 2000 mass production of panels made this economical.
Primary and converted energy is much traded among countries. The table lists countries/regions that export most of their energy, followed by countries that must import much for their economies. The quantities are expressed in Mtoe/a and the data are of 2013.[7]
Big transport goes by tanker ship, tank truck, LNG carrier, rail freight transport, pipeline and by electric power transmission.
32% of primary production is used for conversion and transport, and 6% for non-energy products like lubricants, asphalt and petrochemicals. 62% remains for end-users.
Final consumption
This is the world-wide consumption of energy by end-users. This energy consists of fuel (80%) and electricity (20%). The tables lists amounts, expressed in million tonnes of oil equivalent per year (1 Mtoe = 11.63 TWh), and how much of these is renewable energy. Non-energy products are not considered here. The data are of 2013.[7]
Fuel:
- Fossil fuel: natural gas, fuel derived from petroleum (LPG, gasoline, kerosene, gas/diesel, fuel oil), from coal (anthracite, bituminous coal, coke, lignite, blast furnace gas)
- Renewable fuel: biofuel and fuel derived from waste, so far as it is traded.
- District heating.[13]
The amounts are based on lower heating value.
Electricity:
- See World electricity consumption for details, but note that the table there includes also internal consumption of power plants, about 10% of the totals.
The first table lists world-wide final consumption and the countries/regions which use most (83%). In developing countries fuel consumption per person is low and more renewable. Canada, Venezuela and Brazil generate most electricity with hydropower.
Fuel Mtoe/a |
of which renewable | Electricity Mtoe/a |
of which renewable | Energy pp toe/a | |
---|---|---|---|---|---|
WORLD | 6800 | 17% | 1680 | 21% | 1.2 |
China | 1390 | 16% | 387 | 20% | 1.3 |
United States | 1050 | 7% | 325 | 13% | 4.4 |
European Union | 801 | 10% | 238 | 13% | 2.1 |
Africa | 485 | 62% | 51 | 13% | 0.5 |
India | 415 | 41% | 77 | 16% | 0.4 |
Russia | 300 | 1% | 64 | 21% | 2.6 |
Japan | 191 | 2% | 82 | 12% | 2.2 |
Brazil | 170 | 34% | 42 | 82% | 1.1 |
Indonesia | 135 | 40% | 16 | 11% | 0.6 |
Canada | 133 | 9% | 42 | 59% | 5.0 |
Iran | 130 | 0% | 18 | 5% | 1.9 |
Mexico | 91 | 9% | 21 | 23% | 1.0 |
S-Korea | 82 | 4% | 42 | 2% | 2.5 |
Australia | 58 | 8% | 18 | 9% | 3.0 |
Ukraine | 53 | 2% | 12 | 8% | 1.4 |
Argentina | 45 | 1% | 10 | 41% | 1.3 |
Venezuela | 36 | 2% | 8 | 65% | 1.5 |
The next table shows countries consuming most (83%) in the European Union, and Norway. The last four countries generate electricity largely renewable.
Fuel Mtoe/a |
of which renewable | Electricity Mtoe/a |
of which renewable | Energy pp toe/a | |
---|---|---|---|---|---|
Germany | 158 | 9% | 45 | 25% | 2.5 |
France | 106 | 12% | 38 | 16% | 2.2 |
United Kingdom | 96 | 2% | 27 | 13% | 1.9 |
Italy | 90 | 10% | 25 | 32% | 1.9 |
Spain | 56 | 9% | 20 | 31% | 1.6 |
Poland | 51 | 12% | 11 | 11% | 1.6 |
Netherlands | 38 | 3% | 9 | 14% | 2.8 |
Belgium | 26 | 8% | 7 | 14% | 3.0 |
Sweden | 19 | 32% | 11 | 55% | 3.1 |
Portugal | 11 | 20% | 4 | 60% | 1.5 |
Denmark | 11 | 13% | 3 | 48% | 2.3 |
Norway | 9 | 11% | 9 | 98% | 3.6 |
Energy for energy
Some fuel end electricity is used to construct, maintain and demolish/recycle installations that produce fuel and electricity, such as oil rigs, uranium isotope separators and wind turbines. For these producers to be economic the ratio of energy returned on energy invested (EROEI) or energy return on investment (EROI) should be large enough. There is little consensus in the technical literature about methods and results in calculating these ratios, but it is likely that for fuels (fossil and nuclear), hydro power and wind turbines the ratio is at least 10, for solar panels about 7 and for solar collectors (hot water) only 2.[14] In southern European countries solar EROEI exceeds ten[15] but more to the North it is less as it takes a greater part of the life time to regain the invested energy,
Outlook until 2040
Based on examination of the Paris Agreement pledges, covering some 190 countries, the IEA expects[4] that the worldwide energy consumption in 2040 will have increased 30% by industrialising India, Southeast Asia and China. Renewable energy sees the fastest growth, natural gas consumption rises by 50%, oil demand tops by 2040 and coal use will not grow.
With this policy the goal, set in the Paris Agreement, will not nearly be reached according to the IEA. More stringent decarbonisation options examined in the IEA Outlook include the 450 Scenario (450 ppm CO2 in the air being associated with 2 C warming). In this scenario nearly 60% of the power generated in 2040 comes from renewables, almost half of this from wind and solar PV. The power sector is largely decarbonised. Structural changes to the design and operation of the power system are needed to integrate high shares of variable wind and solar power. This requires a major reallocation of cumulative investment capital in the energy sector, estimated at $40 trillion. By 2040 the share going to fossil fuels drops towards one-third.
See also
"Providing all global energy with wind, water, and solar power" in Mark Jacobson.
Notes
References: |
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