Summary: The world is grappling with growth in atmospheric concentrations of greenhouse gases arising from burning of fossil fuels over the last 150 years. The increased amounts of greenhouse gases are thought to be responsible for global warming.
In this post we characterize the growth in the use of energy in the People’s Republic of China since the beginning of its market-based economy in 1978, practically all of which has been generated from the burning of fossil fuels that produce greenhouse gases. Here we summarize certain projections of China's future energy demand and its production, and conclude with an analysis of its stated policies concerning global warming. A companion analysis for the United States is presented in the next post.
Introduction: China is the most populous nation in the world. Yet, as the Table below shows, it is a developing country economically, as its per capita GDP for the year
Nation | Population 2008, millions | Est. pop. 2050, millions | Rate of growth of | Per capita | |
1,336.3 | 1,417 | 4,327 | 10.9 | 3,238 | |
89.7 | 146 | 167 | 5.5 | 1,860 | |
308.8 | 404 | 14,093 | 2.4 | 45,608 | |
61.9 | 68 | 2,857 | 1.8 | 46,160 |
Source: The Economist, Pocket World in Figures, 2011 Edition, Profile Books, London , 2010.
2008 reveals. It can be grouped with another developing country, chosen here to be the Philippines , as having a low per capita GDP value. These countries may be contrasted with developed countries such as the United States and France, both members of the Organization for Economic Cooperation and Development (OECD), whose per capita GDP numbers are almost 15 times greater than that of China. These numbers show that as China continues on its path toward further development, its GDP , and its per capita GDP , could expand by an order of magnitude.
The graphic below shows just that path of expanding GDP in China over the past 50 years, charted here up to 2005. It is apparent that GDP has been expanding rapidly since 1978, when market-based economic reforms were begun.
Source: http://upload.wikimedia.org/wikipedia/commons/b/b3/Prc1952-2005gdp.gif. Permission for copying granted on Wikimedia. The exchange rate was 8.27 yuan per US$ from 1997 to 2005 (http://en.wikipedia.org/wiki/Renminbi).
Such rapid economic growth can only be undertaken by the use of corresponding increases in energy use. To the extent that China ’s energy needs are filled by burning fossil fuels, its economic growth results in corresponding increases in greenhouse gas emissions. This post explores the energy landscape of China at present, its predicted continued expansion in future decades, and its impact on resolving the urgencies imposed on the world by global warming.
Overview of Current Energy Production in China
The Wall Street Journal on July 18, 2010 cited the International Energy Agency as reporting that China has become the world’s largest consumer of energy, outstripping the U. S. China ’s energy use has grown dramatically over the past two decades, as it has rapidly expanded its economy and developed new energy-intensive industries as well as constructed extensive new infrastructure projects (see the previous graphic and the graphic below).
Source: International Energy Agency. Format © The Wall Street Journal (http://online.wsj.com/article/SB10001424052748703720504575376712353150310.html?mod=googlenews_wsj#project%3DCHENERGY0719%26articleTabs%3Dinteractive). Total primary energy consumption in million tons of oil equivalent for 2000-2009; 2009 estimated. Rose bars, U. S.; yellow bars, China.
Producing steel and cement requires the input of large amounts of heat energy. In 2009 China consumed 2.3 billion tons of oil equivalent energy, which includes energy derived from all fossil fuels as well as renewables such as hydropower and wind, and nuclear energy. In contrast, the overall usage in the U. S. was 2.2 billion tons of oil equivalent. The U. S. has been the highest consumer of energy throughout the 20th century. As recently as 10 years ago, China ’s consumption had been only half that of the U. S. In the interim, consumption by the U. S. has remained essentially constant, and even declined slightly in 2008 and 2009 as the economic recession took hold (see the graphic).
Nevertheless, as a reflection of the per capita GDP data in the Introduction, the per capita energy use in China is far lower than in the U. S. (see the following graphic).
Source: International Energy Agency. Format © The Wall Street Journal (http://online.wsj.com/article/SB10001424052748703720504575376712353150310.html?mod=googlenews_wsj#project%3DCHENERGY0719%26articleTabs%3Dinteractive). Total primary energy consumption per capita in metric tons of oil equivalent for 2000-2009; 2009 estimated. Rose bars, U. S.; yellow bars, China.
The trend in China is increasing over the decade shown whereas that for the U.S. is steady or even declining in 2008 and 2009.
The distribution of fuels that provided the energy consumed by China in 2008 is shown in the following pie chart. It is seen that coal provides by far the largest portion of China ’s energy needs, as of 2008.
Source: U. S. Energy Information Agency (http://www.eia.doe.gov/cabs/China/Background.html).
Energy Production in China : Coal
China became the world’s highest emitter of CO2 and other greenhouse gases in 2007, surpassing the U. S. (Wall Street Journal, July 18, 2010) This is due to China’s heavy reliance on coal-fired electricity generation, and the fact that burning coal emits much more CO2 per unit of energy produced than any other fossil fuel.
According to the Pew Center on Global Climate Change, coal costs about 1/6 as much per amount of heat produced on burning as does oil or natural gas, and China has vast deposits of coal. Thus China has a strong incentive to continue using coal as a major source of its energy supply. In 2006 China built new coal-fired plants with a total capacity of over 90 GW, or almost 2 large-capacity plants per week. Just these newly-built plants emitted 13% of China ’s 2006 total coal-fired greenhouse gases, adding about 500 million tons of CO2 to the atmosphere per year.
According to the U. S. Energy Information Agency (USEIA), China consumed an estimated 3.5 billion short tons of coal in 2009, (see the graphic below) which constituted 46 percent of the world total; this was a 180 percent increase since 2000. As seen in the graphic, coal consumption has been increasing over the last nine years, which is mirrored as well in the level of coal production, estimated at almost 3.4 billion short tons in 2009.
Source: USEIA (http://www.eia.doe.gov/cabs/China/Coal.html)
Energy Production in China : Oil
In 2009 China consumed about 8.3 million barrels of oil per day, of which 4.0 million was from domestic production and the rest was imported (USEIA). In that year China moved up to become the second largest importer of oil in the world, just outstripping Japan . The U. S. remains by far the largest importer, at 9.6 million barrels per day in 2009. USEIA estimates that Chinese demand for oil will continue to grow, reaching 9.6 million barrels per day in 2011, and about 17 million barrels per day by 2035. A significant portion of the imported oil originates in countries such as Saudi Arabia , Angola , Iran and Russia .
Energy Production in China : Gas
Natural gas contributes only a small fraction, 3%, of China ’s total energy consumption as of 2008. Both production and demand for natural gas has been expanding rapidly in recent years. The country expects to expand gas production and power generation using natural gas going forward, and is building several combined cycle (more efficient) natural gas plants (USEIA).
Electricity Generation in China
Explanation of Units. The watt is a unit of power, i.e., the rate of producing or using energy in a standard period of time. When watts are multiplied by the time elapsed, we get the total amount of energy produced or consumed; in electricity jargon this energy unit is a watt-hour, or W-h. More convenient amounts of power generation are measured in thousands of watts, or kilowatts (kW), and billions of watts, or gigawatts (GW). The total amount of energy produced or used over a period of time, is expressed in thousands of W-h, or kilowatt-hours,(kW-h, on a household scale), or in millions or billions of kW-h (on an industrial scale or higher).
As of 2008, China ’s actual capacity for generating electricity from all sources was about 800 GW. In 2009 the total amount of electricity generated was about 3,500 billion kW-h for the nation as a whole, for the entire year. As the graphic below shows, about 82% of this originated from conventional thermal generators, i.e., coal-, oil-, or natural gas-fired power plants. Hydroelectric power represented about 16%. According to USEIA, FACTS Global Energy estimated that overall generating capacity reached 950 GW by the end of 2010, a 19% increase. Electricity production and consumption have more than doubled since 2000. USEIA predicts that by 2035, the total annual electrical energy produced will be 10,555 billion kW-h, more than 3 times the amount produced in 2009. The graphic below shows the breakdown of sources for the electricity that China generated in the 20 year period 1989-2009.
Source: USEIA (http://www.eia.doe.gov/cabs/China/Electricity.html). Red, conventional thermal; blue, hydroelectric; yellow, nuclear energy; green, other renewables.
Wind
Wind power is the second largest source of renewable energy generation in China after hydroelectric power. China is the world’s 5th largest producer of wind power. Its wind generating capacity has roughly doubled each year from 2005 (USEIA). The most favorable wind sources are in the barren regions of western China . However, the power grid in this sparsely populated region lags far behind the generation capacity. The consumers of this power are far from its source. (Xinhua, September 21, 2010 , reported by the Manila Bulletin).
Solar
Dunhuang, in the northwestern Gansu Province of western China is the center of a burgeoning development of solar generation, as this region receives the most intense sunlight in China . By 2012 it is expected that solar photovoltaic panels (silicon wafers) will generate 300,000 kW, and ultimately 10 million kW. In addition, by 2012 50,000 kW of solar heat generation of electricity will be installed. This is part of a major program to bring the less-developed regions of western China closer to parity with the more wealthy coastal regions. (Xinhua, September 21, 2010 , reported by the Manila Bulletin).
Nuclear
A small nuclear power capacity in China is represented by its 11 operational reactors, with 8 more under construction and another 8 being planned. Uranium ore is available domestically and more is imported. USEIA estimates that nuclear power contributed 2% of electricity produced in 2009, and will grow to about 6% in 2035.
Future Trends
USEIA estimates that coal consumption will continue to increase although its share of total energy will fall to about 62% by 2035. China’s announced intention is to reduce carbon intensity (CO2 equivalents emitted per unit of GDP ) by at least 40% from the level during 2005 by 2020; yet in view of the country’s large population and rapidly expanding economy it is expected that the total consumption of coal will nearly double to 112 quadrillion British thermal units over this time (see China’s Response to Global Warming, below).
In the 12th Five Year Plan covering 2011-2015 China expects to close many older, smaller and less efficient coal plants in favor of larger ones (USEIA). Many of the new plants supplanting the coal plants will use natural gas.
The Chinese government has forecast that conventional thermal power generation will remain the prevalent source over the next 1-2 decades, at about 67% of the total. This may be understood at least partly in view of China ’s vast reserves of coal. Thermal power generation capacity is estimated to increase from 650 GW in 2009 to 1,000 GW by 2020. USEIA’s estimate is more conservative at about 810 GW in 2020.
Renewable and Hydroelectric Sources
The International Energy Agency (IEA; not to be confused with the USEIA) is an autonomous organization associated with the Organization for Economic Cooperation and Development (OECD). The IEA recently published its World Energy Outlook (WEO) 2010, which analyzes present and projected world-wide production and consumption of energy over the period 2010-2035, and assesses scenarios for meeting various objectives for limiting the effects of global warming. WEO 2010 formed the basis of an earlier post on this blog. WEO 2010 presents forecasts of future greenhouse gas emissions and some indices of economic development, based primarily on the “New Policies Scenario” resulting from measures to be taken in response to the Copenhagen commitments of 2009 (nonbinding and inadequate though they may be). WEO 2010 judges that under this Scenario CO2 emissions continue to rise, by 21% over the level of 2008; this “trend would make it all but impossible to achieve the 2 deg C goal, as the required reductions in emissions after 2020 would be too steep” (emphasis in the original). Rather, what is needed, in the view of WEO 2010, is early adoption of more drastic steps to keep the atmospheric CO2 level below 450 parts per million, in order to restrain average global temperatures from increasing more than 2 deg C (3.6 deg F) above the level that prevailed before the industrial revolution of the 19th century (the “450 Scenario”). This limit was agreed to at Copenhagen , and confirmed at the recent Cancun conference (see the post).
Under the New Policies Scenario, WEO 2010 predicts worldwide coal usage shown in the following graphic. It is seen that the contribution predicted for China alone is
a major part of the overall demand for coal.
China ’s demand for all sources of energy is expected to continue growing at similar high rates in coming years. These observations may be further visualized in the following graphic, which includes China ’s share of projected changes in sources of energy demand (orange bars).
It is important to note that, in the preceding graphic, the contribution from coal, as well as from other fossil fuels not shown, provide annual increments to atmospheric CO2 once burned. In a previous post the atmosphere was likened to a bathtub containing CO2. These annual increments act to fill the bathtub even higher than it is today. Only zero increments, barring any compensating decreases, can keep the CO2 bathtub at a constant level.
Reproduced from World Energy Outlook 2010 © OECD/IEA.
The color scheme is the same as in the first graphic, above. The bars for coal and oil to the left of the “0” line represent decreases in usage for these fuels over the period 2008-2035 in the OECD countries. Bars to the right of the “0” line represent increases in usage. Single-handedly China (orange) accounts for profound increases in demand for fossil fuels over this period, as well as for renewable sources of energy. Mtoe, energy demand (consumption) expressed as equivalents of millions of tons of oil.
It should be noted, nevertheless, that perhaps China may be changing its approach to reducing global warming. In a press conference webcast from the Cancun climate conference held Nov. 29-Dec. 10, 2010 , the representative of the People’s Republic of China , Xie Zhenhua, emphasized China ’s progress in limiting its carbon intensity. In the current (11th) 5-year plan, carbon intensity has diminished by 20%. In response to a question, Mr. Xie summarized China’s position that the industrialized nations have already attained high levels of economic prosperity, whereas China is still a developing country with a high level of poverty and increasing extents of urbanization still proceeding. Nevertheless, he stated that China is building into the next (12th) 5-year plan a goal of reaching a peak in carbon emissions (implying a subsequent decrease). This statement may reveal an appreciation of the need to address total greenhouse gas emissions rather than carbon intensity.
© 2010 Henry Auer
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