Daniel Nocera, The Henry Dreyfus Professor of Energy and Professor of Chemistry; ; ;
Description: Daniel Nocera is swimming very hard against the current of mainstream energy research. While many scientists are figuring out how to scale up wind, geothermal or biomass systems, Nocera is focusing on "personalized" energy units that can be manufactured, distributed and installed on the cheap. His main concern lies with the increasing energy demands of six billion people, primarily from developing nations, who will be marching onto the world stage by 2050 and likely doubling the planet's energy consumption, from around 13 to 26 terawatts (that's trillion watts). A "solution to the energy challenge rests in providing the non"legacy (developing) world a carbon"neutral, sustainable energy supply," says Nocera.
Nocera's science isn't about making big or efficient systems. For non"legacy populations, "cost means everything and efficiency is secondary." Nocera's metrics look at cost in terms of energy stored per weight of something, and so he plots a Boeing 777 plane, etching tools, and Big Macs on the same cost curve. Priced out this way, cars cost around $1 million. Pursuing this logic, Nocera wants to build large quantities of small energy systems and get them into the developing world before giant infrastructure"based energy takes root.
Nocera's vision builds on major research breakthroughs: He has figured out how to harness critical biological processes that may bring widespread solar power closer to reality. Nocera's innovations include replicating in the lab the process of photosynthesis in plants, using sunlight to split water molecules and store energy. "Chemically, I'm not doing anything in a sophisticated wayjust taking water, rearranging bonds and making fuel." A liter of water, energized by sunlight from a photovoltaic cell, can store 13 megajoules. The 3.2 million liters in MIT's pool could yield 43 terawatts _ enough energy "to take care of all of you." Nocera's photosynthesis uses a cobalt"phosphate cocktail that mimics the mineral"based catalytic process in a plant, and "keeps fixing itself," running endlessly on such humble fuels as Charles River water. His process even yields pure drinking water from waste.
Nocera's goal is to make each home its own power station, with photovoltaic arrays on the roof feeding the catalytic reaction that splits water into hydrogen and oxygen. Some of these elements are still pricey or unreliable -- in particular, fuel cells and photovoltaics are troublesome -- yet he envisions villages in India and Africa not long from now purchasing one of his basic systems for $800. While Nocera acknowledges his critics, he views them as institution"bound naysayers: "I always say when the scientists stop fighting, then you're screwed."
About the Speaker(s): Daniel Nocera is at the forefront of research on renewable energy at the molecular level, focusing on mechanisms of energy conversion involving the water molecule. In 2005, Nocera was awarded the Italgas Prize, and was elected to the American Academy of Arts and Sciences. Nocera has received the American Institute of Chemists Award, and was appointed a Presidential Young Investigator and an Alfred P. Sloan Fellow.
He serves on the Editorial Boards of Accounts of Chemical Research, Inorganic Chemistry, Journal of the American Chemical Society and Comments in Inorganic Chemistry. He was the inaugural Editor of Inorganic Chemistry Communications.
Nocera received his B.S. in 1979 from Rutgers University, and his Ph.D. from CalTech in 1984. He joined MIT in 1997.
Host(s): School of Humanities, Arts & Social Sciences, Knight Science Journalism Fellowships
It looks like no one has posted a comment yet. You can be the first!
You need to log in, in order to post comments.
More from MIT World — special events and lectures
Added 5 years ago | 01:45:00 | 3249 views
Added 5 years ago | 01:29:00 | 3933 views
Added 5 years ago | 02:02:00 | 8584 views
Added 5 years ago | 00:55:08 | 3374 views
Added 5 years ago | 01:38:00 | 4944 views
Added 5 years ago | 00:44:08 | 3228 views