In the 1970s, Buckminster Fuller proposed superconducting global-scale electrical grids to wheel solar energy collected on the daylight hemisphere halfway around the earth to the nighttime hemisphere.
Given the potential for catastrophic climate change, a question must be asked: What has happened to such far-out and disruptive – but not necessarily unfeasible – visions for a renewable-energy future? Right now, hundreds of new coal plants are on drawing boards around the world.
Today, the world uses about 13 terawatts of power, approximately 80 percent of it from carbon-dioxide-emitting fossil fuels. If we want to keep Earth’s average temperature low enough to prevent eventual large sea-level rises (see “The Messenger”) – and also accommodate continued 3 percent annual economic growth – we will need between 10 and 30 terawatts of new carbon-free power by 2050.
The time to start building a sustainable carbon-free energy infrastructure is now. We need Apollo-type research to accomplish this, beginning perhaps with funding of far-out programs along the lines of ARPA-E (“E” for energy), an initiative proposed by the National Academy of Sciences and modeled on the U.S. Advanced Research Projects Agency (now prefaced by “Defense”), which gave us the Internet.
Video: Scientists speak out about the threat of global warming and how to deal with it.
A global-energy-systems engineer – if such a profession existed – would probably have recourse to many technologies that are disruptive of today’s powerful coal, oil, and gas industries. Wind turbines are already economically competitive with conventional energy sources in some regions. Steadier and faster high-altitude winds might be harvested someday by flying wind turbines that transmit electricity to Earth through tethering wires.
The greatest potential for terawatt-scale renewable electric power lies in harvesting solar energy directly. About 2,000 megawatts of silicon-based photovoltaic cells have been manufactured, but the existing technology is expensive. A promising path to cost reduction is thin-film cells that include materials like copper indium diselenide, cadmium telluride, and amorphous silicon. Aggressive R&D and expanding markets will reduce costs, but a big push from government could help realize solar’s vast potential.
One weakness of solar power is its intermittency. But photo-voltaic panels in geostationary orbit could be positioned to receive constant sunlight and thereby furnish the earth with a reliable stream of electricity. They should be the focus of experiments on the scale of the International Thermonuclear Experimental Reactor scheduled to be built in France. Unlike fusion, space-solar technologies – including wireless power transmission – are well understood. The aesthetics, like those of offshore wind turbines, are contentious. But for me, the image of a ring of sun-reflecting solar-power satellites in the night sky evokes Yeats’s “golden apples of the sun” – humankind’s coming of age on star power. On Earth, we need entirely new electrical grids that are “smart,” store excess power, and minimize resistance to enable transmission of renewable but intermittent energy across continents.
There’s much more that can be done to promote “green” homes and offices through a more enlightened federal policy. Mass public exhibits of creative sun- and wind-powered technology, buildings, and communities could stimulate consumer demand in the way that General Motors’ “Futurama” exhibit at the 1939 World’s Fair created demand for cars and parkways and, by extension, suburban homes.
The late Nobel laureate Rick Smalley observed that even though our civilization has many problems, energy is central to all of them. Questions that begin “What is…?” are often the wrong ones; the better question is “What could possibly be?” Spurred by World War II, the United States went from biplanes to jets, from laboratory U-235 fission to Hiroshima, from microwaves to radar – all in less than a decade. The coming battle for a sustainable energy infrastructure will require every bit as much a team effort from government, researchers, and industry. We know where we must go eventually. Why not head there now?
Marty Hoffert is professor emeritus of physics at New York University.
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