Materials science and engineering

Illustration shows the layered structure of the new device, starting with a flexible layer of graphene, a one-atom-thick carbon material. A layer of polymer is bonded to that, and then a layer of zinc-oxide nano wires (shown in magenta), and finally a layer of a material that can extract energy from sunlight, such as quantum dots or a polymer-based material.

Flexible, light solar cells could provide new opportunities

MIT researchers develop a new approach using graphene sheets coated with nanowires.

December 21, 2012

F. William Herbert of materials science and engineering (left) and Bilge Yildiz of nuclear science and engineering are examining how nanoscale disruptions in the crystalline structure of metals affect those materials’ vulnerability to stress corrosion cracking.

New experiments, new insights into stress corrosion cracking

MIT researchers now have new insights into how 'stress corrosion cracking' may be affected by nanoscale disruptions in the crystalline structure of metallic materials.

December 20, 2012

This fluorescent microscope image shows the tiny barbs that coat the tip of a porcupine's quills.

Inspiration from a porcupine’s quills

Understanding the mechanisms behind quill penetration and extraction could help engineers design better medical devices.

December 10, 2012

Arfa Aijazi has taken full advantage of MIT's opportunities, conducting research in England, Tanzania and Brazil.

Building a better world

From fuel cells to bamboo, and from Tanzania to Brazil, MIT senior Arfa Aijazi crosses borders and disciplines to make an impact.

December 4, 2012

A simulated water droplet on a sheet of suspended graphene.

How ‘transparent’ is graphene?

MIT researchers find that adding a coating of graphene has little effect on how a surface interacts with liquids — except in extreme cases.

December 4, 2012

Associate Professor of Mechanical Engineering Kripa K. Varanasi

Varanasi selected as outstanding young manufacturing engineer by SME

MIT professor of mechanical engineering is one of just seven recipients of the award this year.

November 30, 2012

This diagram of the molecular structure of one of the artificially produced versions of spider silk depicts one that turned out to form strong, well-linked fibers. A different structure, made using a variation of the same methods, was not able to form into the long fibers needed to make it useful. Musical compositions based on the two structures helped to show how they differed.

The music of the silks

Researchers synthesize a new kind of silk fiber — and find that music can help fine-tune the material’s properties.

November 28, 2012

A visualization of the broad-spectrum solar energy funnel.

Funneling the sun’s energy

MIT engineers propose a new way of harnessing photons for electricity, with the potential for capturing a wider spectrum of solar energy.

November 25, 2012

Shannon Taylor holds up an ingot, which is 30 percent by weight copper and 70 percent by weight silver, which is similar composition to some artifacts she studies.

The mysteries in materials

MIT senior Shannon Taylor researches 500-year-old artifacts and art to understand and restore materials.

October 24, 2012

MIT chemists designed a new type of pencil lead consisting of carbon nanotubes, allowing them to draw carbon nanotube sensors onto sheets of paper.

Drawing a line, with carbon nanotubes

New low-cost, durable carbon nanotube sensors can be etched with mechanical pencils.

October 9, 2012

Diagram shows the flat-sheet structure of the material used by the MIT team, molybdenum disulfide. Molybdenum atoms are shown in teal, and sulfur atoms in yellow.

One-molecule-thick material has big advantages

MIT researchers produce complex electronic circuits from molybdenum disulfide, a material that could have many more applications.

August 23, 2012

An image (made with Raman spectroscopy) of a graphene layer on top of a patterned substrate shows the difference in chemical reactivity of the side opposite the substrate. The wide red stripe is an area over a silicon dioxide substrate, making the top surface of the graphene highly reactive. The narrow blue stripe is graphene over a layer of hydrocarbon (called OTS), and there is almost no reactiv...

Graphene’s behavior depends on where it sits

New findings show that the material beneath the thin carbon sheets determines how they react chemically and electrically.

August 13, 2012

This illustration shows how a molten fiber, because of a phenomenon known as Rayleigh instability, naturally breaks up into spherical droplets. Researchers from MIT and UCF have figured out how to use this natural tendency as a way to make large quantities of perfectly uniform particles, which can have quite complex structures.

Dripping faucets inspire new way of creating structured particles

Researchers find new method for making spherical particles, from nanoscale to pinhead-sized — including complex beach-ball-like shapes.

July 18, 2012

Illustration of a sheet of graphene with a bunch of other molecules floating on either side

A new approach to water desalination

Graphene sheets with precisely controlled pores have potential to purify water more efficiently than existing methods.

July 2, 2012

An atomic-force microscope image of a layer of single-walled carbon nanotubes deposited on a silicon surface, as the first step in manufacturing the new type of solar cell developed by an MIT team. Individual nanotubes can be seen in the image.

All-carbon solar cell harnesses infrared light

New type of photovoltaic device harnesses heat radiation that most solar cells ignore.

June 21, 2012

MIT News | Massachusetts Institute of Technology

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