A Solar Grand Plan
By 2050 solar power could end U.S. dependence on foreign oil and slash greenhouse gas emissions
By Ken Zweibel, James Mason and Vasilis Fthenakis
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High prices for gasoline and home heating oil are here to stay. The U.S. is at war in the Middle East at least in part to protect its foreign oil interests. And as China, India and other nations rapidly increase their demand for fossil fuels, future fighting over energy looms large. In the meantime, power plants that burn coal, oil and natural gas, as well as vehicles everywhere, continue to pour millions of tons of pollutants and greenhouse gases into the atmosphere annually, threatening the planet.
Well-meaning scientists, engineers, economists and politicians have proposed various steps that could slightly reduce fossil-fuel use and emissions. These steps are not enough. The U.S. needs a bold plan to free itself from fossil fuels. Our analysis convinces us that a massive switch to solar power is the logical answer.
Solar energy’s potential is off the chart. The energy in sunlight striking the earth for 40 minutes is equivalent to global energy consumption for a year. The U.S. is lucky to be endowed with a vast resource; at least 250,000 square miles of land in the Southwest alone are suitable for constructing solar power plants, and that land receives more than 4,500 quadrillion British thermal units (Btu) of solar radiation a year. Converting only 2.5 percent of that radiation into electricity would match the nation’s total energy consumption in 2006.
To convert the country to solar power, huge tracts of land would have to be covered with photovoltaic panels and solar heating troughs. A direct-current (DC) transmission backbone would also have to be erected to send that energy efficiently across the nation.
The technology is ready. On the following pages we present a grand plan that could provide 69 percent of the U.S.’s electricity and 35 percent of its total energy (which includes transportation) with solar power by 2050. We project that this energy could be sold to consumers at rates equivalent to today’s rates for conventional power sources, about five cents per kilowatt-hour (kWh). If wind, biomass and geothermal sources were also developed, renewable energy could provide 100 percent of the nation’s electricity and 90 percent of its energy by 2100.
The federal government would have to invest more than $400 billion over
the next 40 years to complete the 2050 plan. That investment is substantial,
but the payoff is greater. Solar plants consume little or no fuel, saving
billions of dollars year after year. The infrastructure would displace 300
large coal-fired power plants and 300 more large natural gas plants and all
the fuels they consume. The plan would effectively eliminate all imported
oil, fundamentally cutting U.S. trade deficits and easing political tension
in the Middle East and elsewhere. Because solar technologies are almost
pollution-free, the plan would also reduce greenhouse gas emissions from
power plants by 1.7 billion tons a year, and another 1.9 billion tons from
gasoline vehicles would be displaced by plug-in hybrids refueled by the
solar power grid. In 2050 U.S. carbon dioxide emissions would be 62 percent
below 2005 levels, putting a major brake on global warming.
Photovoltaic Farms
In the past few years the cost to produce photovoltaic cells and modules has
dropped significantly, opening the way for large-scale deployment. Various
cell types exist, but the least expensive modules today are thin films made
of cadmium telluride. To provide electricity at six cents per kWh by 2020,
cadmium telluride modules would have to convert electricity with 14 percent
efficiency, and systems would have to be installed at $1.20 per watt of
capacity. Current modules have 10 percent efficiency and an installed system
cost of about $4 per watt. Progress is clearly needed, but the technology is
advancing quickly; commercial efficiencies have risen from 9 to 10 percent
in the past 12 months. It is worth noting, too, that as modules improve,
rooftop photovoltaics will become more cost-competitive for homeowners,
reducing daytime electricity demand.
In our plan, by 2050 photovoltaic technology would provide almost 3,000
gigawatts (GW), or billions of watts, of power. Some 30,000 square miles of
photovoltaic arrays would have to be erected. Although this area may sound
enormous, installations already in place indicate that the land required for
each gigawatt-hour of solar energy produced in the Southwest is less than
that needed for a coal-powered plant when factoring in land for coal mining.
Studies by the National Renewable Energy Laboratory in Golden, Colo., show
that more than enough land in the Southwest is available without requiring
use of environmentally sensitive areas, population centers or difficult
terrain. Jack Lavelle, a spokesperson for Arizona’s Department of Water
Conservation, has noted that more than 80 percent of his state’s land is not
privately owned and that Arizona is very interested in developing its solar
potential. The benign nature of photovoltaic plants (including no water
consumption) should keep environmental concerns to a minimum.
The main progress required, then, is to raise module efficiency to 14
percent. Although the efficiencies of commercial modules will never reach
those of solar cells in the laboratory, cadmium telluride cells at the
National Renewable Energy Laboratory are now up to 16.5 percent and rising.
At least one manufacturer, First Solar in Perrysburg, Ohio, increased module
efficiency from 6 to 10 percent from 2005 to 2007 and is reaching for 11.5
percent by 2010.
Pressurized Caverns
The great limiting factor of solar power, of course, is that it generates
little electricity when skies are cloudy and none at night. Excess power
must therefore be produced during sunny hours and stored for use during dark
hours. Most energy storage systems such as batteries are expensive or
inefficient.
Compressed-air energy storage has emerged as a successful alternative.
Electricity from photovoltaic plants compresses air and pumps it into vacant
underground caverns, abandoned mines, aquifers and depleted natural gas
wells. The pressurized air is released on demand to turn a turbine that
generates electricity, aided by burning small amounts of natural gas.
Compressed-air energy storage plants have been operating reliably in Huntorf,
Germany, since 1978 and in McIntosh, Ala., since 1991. The turbines burn
only 40 percent of the natural gas they would if they were fueled by natural
gas alone, and better heat recovery technology would lower that figure to 30
percent.
Studies by the Electric Power Research Institute in Palo Alto, Calif.,
indicate that the cost of compressed-air energy storage today is about half
that of lead-acid batteries. The research indicates that these facilities
would add three or four cents per kWh to photovoltaic generation, bringing
the total 2020 cost to eight or nine cents per kWh.
Electricity from photovoltaic farms in the Southwest would be sent over
high-voltage DC transmission lines to compressed-air storage facilities
throughout the country, where turbines would generate electricity
year-round. The key is to find adequate sites. Mapping by the natural gas
industry and the Electric Power Research Institute shows that suitable
geologic formations exist in 75 percent of the country, often close to
metropolitan areas. Indeed, a compressed-air energy storage system would
look similar to the U.S. natural gas storage system. The industry stores
eight trillion cubic feet of gas in 400 underground reservoirs. By 2050 our
plan would require 535 billion cubic feet of storage, with air pressurized
at 1,100 pounds per square inch. Although development will be a challenge,
plenty of reservoirs are available, and it would be reasonable for the
natural gas industry to invest in such a network.
Hot Salt
Another technology that would supply perhaps one fifth of the solar energy
in our vision is known as concentrated solar power. In this design, long,
metallic mirrors focus sunlight onto a pipe filled with fluid, heating the
fluid like a huge magnifying glass might. The hot fluid runs through a heat
exchanger, producing steam that turns a turbine.
For energy storage, the pipes run into a large, insulated tank filled
with molten salt, which retains heat efficiently. Heat is extracted at
night, creating steam. The molten salt does slowly cool, however, so the
energy stored must be tapped within a day.
Nine concentrated solar power plants with a total capacity of 354 megawatts
(MW) have been generating electricity reliably for years in the U.S. A new
64-MW plant in Nevada came online in March 2007. These plants, however, do
not have heat storage. The first commercial installation to incorporate it—a
50-MW plant with seven hours of molten salt storage—is being constructed in
Spain, and others are being designed around the world. For our plan, 16
hours of storage would be needed so that electricity could be generated 24
hours a day.
Existing plants prove that concentrated solar power is practical, but costs
must decrease. Economies of scale and continued research would help. In 2006
a report by the Solar Task Force of the Western Governors’ Association
concluded that concentrated solar power could provide electricity at 10
cents per kWh or less by 2015 if 4 GW of plants were constructed. Finding
ways to boost the temperature of heat exchanger fluids would raise operating
efficiency, too. Engineers are also investigating how to use molten salt
itself as the heat-transfer fluid, reducing heat losses as well as capital
costs. Salt is corrosive, however, so more resilient piping systems are
needed.
Concentrated solar power and photovoltaics represent two different
technology paths. Neither is fully developed, so our plan brings them both
to large-scale deployment by 2020, giving them time to mature. Various
combinations of solar technologies might also evolve to meet demand
economically. As installations expand, engineers and accountants can
evaluate the pros and cons, and investors may decide to support one
technology more than another.
Direct Current, Too
The geography of solar power is obviously different from the nation’s
current supply scheme. Today coal, oil, natural gas and nuclear power plants
dot the landscape, built relatively close to where power is needed. Most of
the country’s solar generation would stand in the Southwest. The existing
system of alternating-current (AC) power lines is not robust enough to carry
power from these centers to consumers everywhere and would lose too much
energy over long hauls. A new high-voltage, direct-current (HVDC) power
transmission backbone would have to be built.
Studies by Oak Ridge National Laboratory indicate that long-distance HVDC
lines lose far less energy than AC lines do over equivalent spans. The
backbone would radiate from the Southwest toward the nation’s borders. The
lines would terminate at converter stations where the power would be
switched to AC and sent along existing regional transmission lines that
supply customers.
The AC system is also simply out of capacity, leading to noted shortages in
California and other regions; DC lines are cheaper to build and require less
land area than equivalent AC lines. About 500 miles of HVDC lines operate in
the U.S. today and have proved reliable and efficient. No major technical
advances seem to be needed, but more experience would help refine
operations. The Southwest Power Pool of Texas is designing an integrated
system of DC and AC transmission to enable development of 10 GW of wind
power in western Texas. And TransCanada, Inc., is proposing 2,200 miles of
HVDC lines to carry wind energy from Montana and Wyoming south to Las Vegas
and beyond.
Stage One: Present to 2020
We have given considerable thought to how the solar grand plan can be
deployed. We foresee two distinct stages. The first, from now until 2020,
must make solar competitive at the mass-production level. This stage will
require the government to guarantee 30-year loans, agree to purchase power
and provide price-support subsidies. The annual aid package would rise
steadily from 2011 to 2020. At that time, the solar technologies would
compete on their own merits. The cumulative subsidy would total $420 billion
(we will explain later how to pay this bill).
About 84 GW of photovoltaics and concentrated solar power plants would be
built by 2020. In parallel, the DC transmission system would be laid. It
would expand via existing rights-of-way along interstate highway corridors,
minimizing land-acquisition and regulatory hurdles. This backbone would
reach major markets in Phoenix, Las Vegas, Los Angeles and San Diego to the
west and San Antonio, Dallas, Houston, New Orleans, Birmingham, Ala., Tampa,
Fla., and Atlanta to the east.
Building 1.5 GW of photovoltaics and 1.5 GW of concentrated solar power
annually in the first five years would stimulate many manufacturers to scale
up. In the next five years, annual construction would rise to 5 GW apiece,
helping firms optimize production lines. As a result, solar electricity
would fall toward six cents per kWh. This implementation schedule is
realistic; more than 5 GW of nuclear power plants were built in the U.S.
each year from 1972 to 1987. What is more, solar systems can be manufactured
and installed at much faster rates than conventional power plants because of
their straightforward design and relative lack of environmental and safety
complications.
Stage Two: 2020 to 2050
It is paramount that major market incentives remain in effect through 2020,
to set the stage for self-sustained growth thereafter. In extending our
model to 2050, we have been conservative. We do not include any
technological or cost improvements beyond 2020. We also assume that energy
demand will grow nationally by 1 percent a year. In this scenario, by 2050
solar power plants will supply 69 percent of U.S. electricity and 35 percent
of total U.S. energy. This quantity includes enough to supply all the
electricity consumed by 344 million plug-in hybrid vehicles, which would
displace their gasoline counterparts, key to reducing dependence on foreign
oil and to mitigating greenhouse gas emissions. Some three million new
domestic jobs—notably in manufacturing solar components—would be created,
which is several times the number of U.S. jobs that would be lost in the
then dwindling fossil-fuel industries.
The huge reduction in imported oil would lower trade balance payments by
$300 billion a year, assuming a crude oil price of $60 a barrel (average
prices were higher in 2007). Once solar power plants are installed, they
must be maintained and repaired, but the price of sunlight is forever free,
duplicating those fuel savings year after year. Moreover, the solar
investment would enhance national energy security, reduce financial burdens
on the military, and greatly decrease the societal costs of pollution and
global warming, from human health problems to the ruining of coastlines and
farmlands.
Ironically, the solar grand plan would lower energy consumption. Even with 1
percent annual growth in demand, the 100 quadrillion Btu consumed in 2006
would fall to 93 quadrillion Btu by 2050. This unusual offset arises because
a good deal of energy is consumed to extract and process fossil fuels, and
more is wasted in burning them and controlling their emissions.
To meet the 2050 projection, 46,000 square miles of land would be needed for
photovoltaic and concentrated solar power installations. That area is large,
and yet it covers just 19 percent of the suitable Southwest land. Most of
that land is barren; there is no competing use value. And the land will not
be polluted. We have assumed that only 10 percent of the solar capacity in
2050 will come from distributed photovoltaic installations—those on rooftops
or commercial lots throughout the country. But as prices drop, these
applications could play a bigger role.
2050 and Beyond
Although it is not possible to project with any exactitude 50 or more years
into the future, as an exercise to demonstrate the full potential of solar
energy we constructed a scenario for 2100. By that time, based on our plan,
total energy demand (including transportation) is projected to be 140
quadrillion Btu, with seven times today’s electric generating capacity.
To be conservative, again, we estimated how much solar plant capacity
would be needed under the historical worst-case solar radiation conditions
for the Southwest, which occurred during the winter of 1982–1983 and in 1992
and 1993 following the Mount Pinatubo eruption, according to National Solar
Radiation Data Base records from 1961 to 2005. And again, we did not assume
any further technological and cost improvements beyond 2020, even though it
is nearly certain that in 80 years ongoing research would improve solar
efficiency, cost and storage.
Under these assumptions, U.S. energy demand could be fulfilled with the
following capacities: 2.9 terawatts (TW) of photovoltaic power going
directly to the grid and another 7.5 TW dedicated to compressed-air storage;
2.3 TW of concentrated solar power plants; and 1.3 TW of distributed
photovoltaic installations. Supply would be rounded out with 1 TW of wind
farms, 0.2 TW of geothermal power plants and 0.25 TW of biomass-based
production for fuels. The model includes 0.5 TW of geothermal heat pumps for
direct building heating and cooling. The solar systems would require 165,000
square miles of land, still less than the suitable available area in the
Southwest.
In 2100 this renewable portfolio could generate 100 percent of all U.S.
electricity and more than 90 percent of total U.S. energy. In the spring and
summer, the solar infrastructure would produce enough hydrogen to meet more
than 90 percent of all transportation fuel demand and would replace the
small natural gas supply used to aid compressed-air turbines. Adding 48
billion gallons of biofuel would cover the rest of transportation energy.
Energy-related carbon dioxide emissions would be reduced 92 percent below
2005 levels.
Who Pays?
Our model is not an austerity plan, because it includes a 1 percent annual
increase in demand, which would sustain lifestyles similar to those today
with expected efficiency improvements in energy generation and use. Perhaps
the biggest question is how to pay for a $420-billion overhaul of the
nation’s energy infrastructure. One of the most common ideas is a carbon
tax. The International Energy Agency suggests that a carbon tax of $40 to
$90 per ton of coal will be required to induce electricity generators to
adopt carbon capture and storage systems to reduce carbon dioxide emissions.
This tax is equivalent to raising the price of electricity by one to two
cents per kWh. But our plan is less expensive. The $420 billion could be
generated with a carbon tax of 0.5 cent per kWh. Given that electricity
today generally sells for six to 10 cents per kWh, adding 0.5 cent per kWh
seems reasonable.
Congress could establish the financial incentives by adopting a national
renewable energy plan. Consider the U.S. Farm Price Support program, which
has been justified in terms of national security. A solar price support
program would secure the nation’s energy future, vital to the country’s
long-term health. Subsidies would be gradually deployed from 2011 to 2020.
With a standard 30-year payoff interval, the subsidies would end from 2041
to 2050. The HVDC transmission companies would not have to be subsidized,
because they would finance construction of lines and converter stations just
as they now finance AC lines, earning revenues by delivering electricity.
Although $420 billion is substantial, the annual expense would be less than
the current U.S. Farm Price Support program. It is also less than the tax
subsidies that have been levied to build the country’s high-speed
telecommunications infrastructure over the past 35 years. And it frees the
U.S. from policy and budget issues driven by international energy conflicts.
Without subsidies, the solar grand plan is impossible. Other countries have
reached similar conclusions: Japan is already building a large, subsidized
solar infrastructure, and Germany has embarked on a nationwide program.
Although the investment is high, it is important to remember that the energy
source, sunlight, is free. There are no annual fuel or pollution-control
costs like those for coal, oil or nuclear power, and only a slight cost for
natural gas in compressed-air systems, although hydrogen or biofuels could
displace that, too. When fuel savings are factored in, the cost of solar
would be a bargain in coming decades. But we cannot wait until then to begin
scaling up.
Critics have raised other concerns, such as whether material constraints
could stifle large-scale installation. With rapid deployment, temporary
shortages are possible. But several types of cells exist that use different
material combinations. Better processing and recycling are also reducing the
amount of materials that cells require. And in the long term, old solar
cells can largely be recycled into new solar cells, changing our energy
supply picture from depletable fuels to recyclable materials.
The greatest obstacle to implementing a renewable U.S. energy system is not
technology or money, however. It is the lack of public awareness that solar
power is a practical alternative—and one that can fuel transportation as
well. Forward-looking thinkers should try to inspire U.S. citizens, and
their political and scientific leaders, about solar power’s incredible
potential. Once Americans realize that potential, we believe the desire for
energy self-sufficiency and the need to reduce carbon dioxide emissions will
prompt them to adopt a national solar plan.
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