Solar

Fine-tuning photosynthesis

MIT analysis shows how synthetic systems for capturing the sun’s energy could be made more efficient.

November 5, 2010

Solar panels in a field with wind turbines in the distance

Power to the people

Entrepreneurs at MIT’s Legatum Center are trying to bring clean-energy solutions to developing countries.

October 28, 2010

A molecule of fulvalene diruthenium, seen in diagram, changes its configuration when it absorbs heat, and later releases heat when it snaps back to its original shape.

Catching the sun’s heat

Storing thermal energy in chemical form has the potential to make it indefinitely storable and transportable.

October 26, 2010

This filament containing about 30 million carbon nanotubes absorbs energy from the sun as photons and then re-emits photons of lower energy, creating the fluorescence seen here. The red regions indicate highest energy intensity, and green and blue are lower intensity.

Solar funnel

New antenna made of carbon nanotubes could make photovoltaic cells more efficient by concentrating solar energy.

September 13, 2010

From left to right, Associate Professor Michael Strano with graduate student Ardemis Boghossian and postdoctoral fellow Moon-Ho Ham, in one of the labs where they carried out their experiments.

Solar cell, heal thyself

New self-assembling photovoltaic technology can keep repairing itself to avoid any loss in performance.

September 7, 2010

A tiny silicon chip — the glowing orange square at the center of this special heating device — is heated to a temperature well below silicon’s melting point, and then very slowly cooled down. The chip inside this heating device was placed in the path of a synchrotron beam to probe its changes at a molecular level as it went through the retrograde melting process.

Silicon can be made to melt in reverse

Material that shows melting while cooling might someday lead to applications in solar cells and other devices

August 2, 2010

A computer simulation shows phonons, depicted as color variations, traveling through a crystal lattice. The lattice in this case is broken up by round rods whose spacing has been chosen to block the passage of phonons of certain wavelengths.

Explained: Phonons

When trying to control the way heat moves through solids, it is often useful to think of it as a flow of particles.

July 8, 2010

Bubbly wave of water with a jagged black line splitting the image in half

New water-splitting catalyst found

Research by MIT’s Dan Nocera expands the list of potential electrode materials that could be used to store energy.

May 14, 2010

Eleanor charges her battery pack in the hot Australian sun before a test drive in the 2009 World Solar Challenge in October.

Racing with the sun

MIT students' solar-vehicle team makes a strong showing down under.

May 5, 2010

Paolo Scaroni, left, CEO of the Italian energy company Eni, and MIT President Susan Hockfield cut the ribbon to celebrate the opening of the Eni-MIT Solar Frontiers Center (SFC), headquartered on the MIT campus.

New solar research center inaugurated

Eni-MIT Solar Frontiers Center, funded by Italian oil company, will support research by 21 MIT faculty members

May 4, 2010

Angela Belcher, the Germeshausen Professor of Materials Science and Engineering and Biological Engineering, demonstrates a virus-templated catalyst solution used in harnessing energy from water.

Viruses harnessed to split water

MIT team’s biologically based system taps the power of sunlight directly, with the aim of turning water into hydrogen fuel.

April 12, 2010

Personalized Energy for One (x 6 Billion)

Lecture, with professor Daniel Nocera, presented by the Knight Science Journalism Fellowship

December 10, 2009

MIT team finishes fifth overall in solar electric vehicle race

Places second in the Silicon category — comprising cars that raced with off-the-shelf, terrestrial-grade silicon solar cells

November 3, 2009

MIT Sloan launches "Clean Energy Ventures"

New workshop on building and sustaining clean energy businesses

October 23, 2009

One project that received MITEI seed funds involves developing remote-controlled robots that can walk along deep-sea oil pipes and drilling facilities, performing critical inspection and maintenance tasks. Key to the design is a foot inspired by that of the gecko, which can stick to and traverse all kinds of surfaces. The project builds on previous work in which the researchers developed "Stickybo...

MITEI awards third round of seed grants

May 5, 2009

MIT News | Massachusetts Institute of Technology

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