Highlights
| World marketed energy consumption is projected to increase by 44 percent
from 2006 to 2030. Total energy demand in the non-OECD countries increases
by 73 percent, compared with an increase of 15 percent in the OECD countries. |
In the IEO2009 reference case—which reflects a scenario in which current
laws and policies remain unchanged throughout the projection period—world
marketed energy consumption is projected to grow by 44 percent over the
2006 to 2030 period. Total world energy use rises from 472 quadrillion
British thermal units (Btu) in 2006 to 552 quadrillion Btu in 2015 and
then to 678 quadrillion Btu in 2030 (Figure 1). The current worldwide economic
downturn dampens world demand for energy in the near term, as manufacturing
and consumer demand for goods and services slows. In the longer term, with
economic recovery anticipated after 2010, most nations return to trend
growth in income and energy demand.
The most rapid growth in energy demand from 2006 to 2030 is projected for
nations outside the Organization for Economic Cooperation and Development
(non-OECD nations). Total non-OECD energy consumption increases by 73 percent
in the IEO2009 reference case projection, as compared with a 15-percent
increase in energy use among the OECD countries. Strong long-term GDP growth
in the emerging economies of the non-OECD countries drives the fast-paced
growth in energy demand. In all the non-OECD regions combined, economic
activity—measured by GDP in purchasing power parity terms—increases by
4.9 percent per year on average, as compared with an average of 2.2 percent
per year for the OECD countries.
The IEO2009 reference case projects increased world consumption of marketed
energy from all fuel sources over the 2006 to 2030 projection period (Figure
2). Fossil fuels (liquid fuels and other petroleum,1 natural gas, and coal)
are expected to continue supplying much of the energy used worldwide. Liquids
supply the largest share of world energy consumption over the projection
period; however, their share falls from 36 percent in 2006 to 32 percent
in 2030, as projected high world oil prices lead many energy users, especially
in the industrial and electric power sectors, to switch away from liquid
fuels when feasible.
Average world oil prices2 increased each year between 2003 and 2008. Spot
prices reached $147 per barrel (in nominal dollars) in mid-July 2008, when
they were well above the historical inflation-adjusted record price for
a barrel of oil, which was set in the early 1980s. After reaching the July
2008 high mark, however, prices fell sharply. As the world’s economies
recover, world oil prices are assumed to rebound and rise in real terms
through 2030. In the IEO2009 reference case, the price of light sweet crude
oil in the United States (in real 2007 dollars) rises from $61 per barrel
in 2009 to $110 per barrel in 2015 and $130 per barrel in 2030.
World Energy Use by Fuel Type
Liquids are expected to remain the world’s dominant energy source throughout
the IEO2009 reference case projection, given their importance in the transportation
and industrial end-use sectors. World use of liquids and other petroleum
grows from 85 million barrels per day in 2006 to 91 million barrels per
day in 2015 and 107 million barrels per day in 2030. Only in the transportation
sector are liquids relatively unaffected by the projected high world oil
prices. Although world oil prices in 2030 in the IEO2009 reference case
are 80 percent higher than projected in IEO2008 (Figure 3), liquids consumption
in the world transportation sector in 2030 is only 9 percent lower in this
year’s outlook, reflecting the expectation that, absent significant technological
advances, liquids will continue to be the primary energy source in the
world’s transportation sector.
To meet the increment in world liquids demand in the IEO2009 reference
case, total supply in 2030 is projected to be 22.0 million barrels per
day higher than the 2006 level of 84.6 million barrels per day. The reference
case assumes that OPEC will maintain a share of approximately 40 percent
of total world liquids production through 2030, consistent with recent
trends. Increasing volumes of conventional liquids (crude oil and lease
condensate, natural gas plant liquids, and refinery gain) from OPEC members
contribute 8.3 million barrels per day to the total increase in world liquids
production, and conventional liquids supplies from non-OPEC countries add
another 3.4 million barrels per day (Figure 4).
Unconventional resources (including oil sands, extra-heavy oil, biofuels,
coal-to-liquids, and gas-to-liquids) from both OPEC and non-OPEC sources
are expected to become increasingly competitive in the reference case.
World production of unconventional resources, which totaled only 3.1 million
barrels per day in 2006, increases to 13.4 million barrels per day and
accounts for 13 percent of total world liquids supply in 2030.
Biofuels, including ethanol and biodiesel, will be an increasingly important
source of unconventional liquids supply, reaching 5.9 million barrels per
day in 2030. Particularly strong growth in biofuels consumption is projected
for the United States, where production of biofuels increases from 0.3
million barrels per day in 2006 to 1.9 million barrels per day in 2030,
supported by legislation in the Energy Independence and Security Act of
2007 that mandates increased U.S. use of biofuels. Other regions with sizable
projected increases in biofuels production include OECD Europe, non-OECD
Asia, and Central and South America. Those regions, together with the United
States, account for 75 percent of the world increase in biofuels production.
Natural gas consumption worldwide increases in the IEO2009 reference case
from 104 trillion cubic feet in 2006 to 153 trillion cubic feet in 2030.
With world oil prices rebounding from their early 2009 level, as the world
economy recovers from the current downturn, and then continuing to grow
in real terms through the end of the projection period, consumers opt for
comparatively less expensive natural gas for their energy needs whenever
possible. As a result, natural gas remains a key energy source in the industrial
sector and for electricity generation. The industrial sector currently
consumes more natural gas than any other end-use sector, and this is expected
to remain true in the reference case through 2030, when 40 percent of the
world’s natural gas supply is used for industrial purposes. Electricity
generation accounts for 35 percent of the world’s total natural gas consumption
in 2030, up from 32 percent in 2006.
To meet the projected growth in demand for natural gas, the world’s producers
will need to increase annual production in 2030 to a level that is 49 trillion
cubic feet higher than the 2006 total. Much of the increase in natural
gas production is expected to come from the non-OECD countries. In the IEO2009 reference case, natural gas production in the non-OECD nations
in 2030 is 41 trillion cubic feet higher than in 2006, accounting for about
84 percent of the total increase in world supply. By region, the Middle
East, non-OECD Europe and Eurasia, and non-OECD Asia each supplies about
20 percent of the increase (Figure 5). Africa, which is an important source
of new natural gas production, provides 15 percent of the total world increment.
Natural gas production from the OECD nations is projected to increase by
7.8 trillion cubic feet from 2006 to 2030 in the reference case. The largest
increase among the OECD nations is projected for the United States, at
5.3 trillion cubic feet. Unconventional natural gas is the largest contributor
to the growth in U.S. production, as rising prices and improvements in
drilling technology provide the economic incentives necessary for exploitation
of more costly resources. Unconventional natural gas production—both from
natural gas in tight sand formations and from shale formations—increases
from 47 percent of the U.S. total in 2006 to 56 percent in 2030.
In the absence of national policies and/or binding international agreements
that would limit or reduce greenhouse gas emissions, world coal consumption
is projected to increase from 127 quadrillion Btu in 2006 to 190 quadrillion
Btu in 2030, an average annual rate of 1.7 percent. Much of the projected
increase in coal use occurs in the non-OECD Asia region, which accounts
for nearly 90 percent of the total world increase in coal use from 2006
to 2030. In fact, much of the region’s increase in energy demand is expected
to be met by coal, particularly in the electric power and industrial sectors.
For example, installed coal-fired generating capacity in China is projected
to nearly triple from 2006 to 2030, and coal use in China’s industrial
sector grows by nearly 60 percent. The development of China’s electric
power and industrial sectors will require not only large-scale infrastructure
investments but also substantial investment in both coal mining and coal
transportation infrastructure.
World net electricity generation increases by 77 percent in the reference
case, from 18.0 trillion kilowatthours in 2006 to 23.2 trillion kilowatthours
in 2015 and 31.8 trillion kilowatthours in 2030. Although the current economic
downturn is expected to dampen electricity demand in the near term, the IEO2009 reference case assumes that growth in electricity demand will return
to trend after 2010. In general, the growth in OECD countries, where electricity
markets are well established and consuming patterns are mature, is slower
than in the non-OECD countries, where a large amount of potential demand
remains unsatisfied. In the reference case, total net generation in the
non-OECD countries increases by an average of 3.5 percent per year, compared
with an average of 1.2 percent per year in the OECD nations.
The rapid increase in world energy prices from 2003 to 2008, combined with
concerns about the environmental consequences of greenhouse gas emissions,
has led to renewed interest in the development of alternatives to fossil
fuels. With high world oil prices expected to return and growth in demand
for liquids and other energy expected to resume when economies begin to
recover from the current global downturn, renewable energy is the fastest-growing
source of world electricity generation in the IEO2009 reference case, supported
both by the expected high prices for fossil fuels and by government incentives
for the development of alternative energy sources.
From 2006 to 2030, world renewable energy use for electricity generation
grows by an average of 2.9 percent per year (Figure 6), and the renewable
share of world electricity generation increases from 19 percent in 2006
to 21 percent in 2030.3 Natural gas and coal are the second and third fastest-growing
energy sources for electricity generation in the projection; however, the
outlook for coal, in particular, could be altered substantially by any
future legislation that would reduce or limit the growth of greenhouse
gas emissions.
Much of the world increase in renewable electricity supply is fueled by
hydropower and wind power. Of the 3.3 trillion kilowatthours of new renewable
generation added over the projection period, 1.8 trillion kilowatthours
(54 percent) is attributed to hydropower and 1.1 trillion kilowatthours
(33 percent) to wind. Except for those two sources, most renewable energy
technologies are not economically competitive with fossil fuels over the
projection period, outside a limited number of niche markets. Solar power,
for instance, typically is uneconomical but can be economical where electricity
prices are high and government incentives are available. In fact, government
incentives or policies typically provide the primary support for construction
of any renewable generation facilities.
The mix of renewable fuels consumed differs between the OECD and non-OECD
regions in the IEO2009 reference case projection. In the OECD nations,
the majority of economically exploitable hydroelectric resources already
have been used, and there are few large-scale hydroelectric power projects
planned for the future (Figure 7). As a result, most of the growth in renewable
energy use in the OECD countries is expected for other sources, led by
wind and biomass. In the non-OECD nations, hydropower is the predominant
source of renewable energy growth, with mid- to large-scale hydroelectric
plants expected to be completed in China, India, Brazil, and a number of
nations in Southeast Asia, including Vietnam and Laos. Wind-powered electricity
generation also is expected to grow significantly in the non-OECD countries,
including substantial additions of wind electricity to the grid in China.
Electricity generation from nuclear power is projected to increase from
about 2.7 trillion kilowatthours in 2006 to 3.8 trillion kilowatthours
in 2030, as concerns about rising fossil fuel prices, energy security,
and greenhouse gas emissions support the development of new nuclear generation
capacity. Higher fossil fuel prices allow nuclear power to become economically
competitive with generation from coal, natural gas, and liquids despite
the relatively high capital and maintenance costs associated with nuclear
power plants. Moreover, higher capacity utilization rates have been reported
for many existing nuclear facilities, and it is anticipated that most of
the older nuclear power plants in the OECD countries and non-OECD Eurasia
will be granted extensions to their operating lives.
Despite the growing worldwide interest in nuclear power development, there
is considerable uncertainty associated with this energy source. Issues
that could slow the expansion of nuclear power in the future include plant
safety, radioactive waste disposal, and concerns that weapons-grade uranium
may be produced from facilities installed to enrich uranium for civilian
nuclear power programs. These issues continue to raise public concerns
in many countries and may hinder the development of new nuclear power reactors.
Nevertheless, the IEO2009 reference case incorporates the improved prospects
for world nuclear power. The IEO2009 projection for nuclear electricity
generation in 2025 is 25 percent higher than the projection published in IEO2004 only 5 years ago.
On a regional basis, the IEO2009 reference case projects the strongest
growth in nuclear power for the countries of non-OECD Asia, where nuclear
power generation is projected to grow at an average rate of 7.8 percent
per year from 2006 to 2030. Nuclear generation is projected to increase
by 8.9 percent per year in China and by 9.9 percent per year in India. Outside
Asia, the largest increase in installed nuclear capacity among the non-OECD
nations is projected for Russia, with increases in nuclear power generation
averaging 3.5 percent per year. In contrast, OECD Europe—where some national
governments, including Germany and Belgium, still have plans in place to
phase out nuclear programs entirely—is expected to see a small decline
in nuclear power generation.
World Delivered Energy Use by Sector
The industrial sector uses more energy than any other end-use sector, currently
consuming about one-half of the world’s total delivered energy. Energy
is consumed in the industrial sector by a diverse group of industries—including
manufacturing, agriculture, mining, and construction—and for a wide range
of activities, such as processing and assembly, space conditioning, and
lighting. Worldwide, industrial energy consumption is expected to grow
from 175.0 quadrillion Btu in 2006 to 245.6 quadrillion Btu in 2030.
Industrial energy demand varies across regions and countries of the world,
based on levels and mixes of economic activity and technological development,
among other factors. About 94 percent of the world increase in industrial
sector energy consumption is projected to occur in the non-OECD economies,
where—driven by rapid economic growth—industrial energy consumption grows
at an average annual rate of 2.1 percent in the reference case. The key
engines of non-OECD growth in the projection are the so-called “BRIC” countries
(Brazil, Russia, India, and China), which account for more than two-thirds
of the growth in non-OECD industrial energy use through 2030 (Figure 8).
Because the OECD nations have been undergoing a transition from manufacturing
economies to service economies in recent decades and have relatively slow
projected growth in economic output, industrial energy use in the OECD
region as a whole grows by an average of only 0.2 percent per year from
2006 to 2030.
The transportation is second only to the industrial sector in terms of
world energy use, and it is of particular importance given the role of
liquid fuels in meeting transportation demand. The transportation share
of total liquids consumption increases from 51 percent in 2006 to 56 percent
in 2030 in the IEO2009 reference case, accounting for nearly 80 percent
of the total increase in world liquids consumption. Much of the growth
in transportation energy use is projected for the non-OECD nations, where
rapidly expanding economies are expected to see strong growth in liquids
consumption as transportation systems become motorized and rising per-capita
incomes increase the demand for personal motor vehicle ownership. Non-OECD
transportation energy use increases by an average of 2.7 percent per year
from 2006 to 2030.
Major urban areas in the non-OECD nations are expected to address transportation
congestion and strains on infrastructure with a variety of solutions, including
development of mass transit (bus and/or rail) and urban design that reduces
vehicle-miles traveled, among other improvements in transportation networks.
In non- OECD Asia, for example, the reference case projects that energy
use for personal motor vehicles (light-duty cars and trucks, as well as
two- and three-wheel vehicles) will increase by 3.6 percent per year from
2006 to 2030, while energy use for public passenger travel (rail and bus)
also shows robust growth in energy use, averaging 2.9 percent per year.
In the OECD nations, transportation energy consumption grows by a relatively
modest average of 0.3 percent per year over the projection period. Transportation
infrastructure in the OECD countries generally is well established. Roads
and highways connect most population centers, and motorization levels (vehicles
per 1,000 people), which already are high, probably will reach saturation
by 2030. As the OECD economies have become more service-oriented, the link
between income and the transportation of goods has weakened, and their
relatively slow rates of GDP growth and population growth in the IEO2009 reference case lead to the expectation that total transportation energy
demand in the OECD countries will increase only modestly from 2006 to 2030.
World Carbon Dioxide Emissions
World carbon dioxide emissions are projected to rise from 29.0 billion
metric tons in 2006 to 33.1 billion metric tons in 2015 and 40.4 billion
metric tons in 2030—an increase of 39 percent over the projection period.
With strong economic growth and continued heavy reliance on fossil fuels
expected for most of the non-OECD economies, much of the increase in carbon
dioxide emissions
is projected to occur among the developing, non-OECD nations. In 2006,
non-OECD emissions exceeded OECD emissions by 14 percent. In 2030, however,
non-OECD emissions are projected to exceed OECD emissions by 77 percent
(Figure 9).
Notes & Sources |
