Materials science and engineering

Comparison of graphene oxide before (left) and after (right) the new annealing treatment. The graphene sheet is represented by yellow carbon spheres, while the oxygens and hydrogens are represented as red and white spheres. Annealing causes oxygen atoms to form clusters, creating areas of pure graphene (as shown in the right image). This results in increased light absorption, improved conduction ...

New graphene treatment could unleash new uses

MIT team develops simple, inexpensive method that could help realize material’s promise for electronics, solar power, and sensors.

December 15, 2013

Silvija Gradečak seeks to better the world through new materials

Looking for better materials for solar cells, LEDs, and other technology, one molecule at a time.

December 6, 2013

The MIT team's experimental setup is pictured above.

Magnetic nanoparticles could aid heat dissipation

Particles suspended in cooling water could prevent hotspots in nuclear plant cooling systems and electronics.

November 19, 2013

Better batteries through biology?

MIT researchers find a way to boost lithium-air battery performance, with the help of modified viruses.

November 13, 2013

A MADMEC attendee tries out Wristify's thermoelectric bracelet.

‘Cool’ invention wins first place at MADMEC

Thermoelectric bracelet that helps people maintain a comfortable body temperature takes home $10,000 from MIT’s annual materials-science design competition.

October 17, 2013

Cracked metal, heal thyself

Unexpected result shows that in some cases, pulling apart makes cracks in metal fuse together.

October 9, 2013

Pyrite, also known as fool's gold, forms cubic crystals that have a yellowish metallic sheen, sometimes leading prospectors to mistake it for gold.

Probing the surface of pyrite

Common mineral gets first detailed examination of its surface electronic properties, thanks to team of MIT researchers.

October 1, 2013

Caroline Ross uses models to demonstrate the crystal structures of complex metal oxides, such as spinel and perovskite phases.

Faculty highlight: Caroline Ross

New techniques for combining complex oxide thin films promise electrical control of magnetic properties for data storage and computing.

September 27, 2013

When subjected to a load, the molecular structure of the ceramic material studied by the MIT-Singapore team deforms rather than cracking. When heated, it then returns to its original shape. Though they have the same chemical composition, the two molecular configurations correspond to different natural minerals, called austenite and martensite.

How to make ceramics that bend without breaking

New materials developed at MIT could lead to actuators on a chip and self-deploying medical devices.

September 26, 2013

Cryoelectron microscope image of the nanoparticles developed by MIT researchers to deliver vaccines to mucosal surfaces.

Nanoparticle vaccine offers better protection

Particles that deliver vaccines directly to mucosal surfaces could defend against many infectious diseases.

September 25, 2013

Robert E. Ogilvie, DMSE professor emeritus, dies at 89

September 25, 2013

A sample of the mineral herbertsmithite.

Understanding a new kind of magnetism

Researchers use low-frequency laser pulses to probe the properties of a kind of fluctuating magnetism known as a spin-liquid state.

September 23, 2013

On typical hydrophobic coatings, droplets forming from high-temperature steam soon spread out to coat the surface, quickly degrading their performance. The new coating, seen here, maintains its ability to foster droplet formation over long periods.

Water-shedding surfaces can be made to last

New approach to hydrophobic material could benefit power plants, cooling systems.

September 20, 2013

A diagram of the molecular structure of double perovskite shows how atoms of barium (green) and a lanthanide (purple) are arranged within a crystalline structure of cobalt (pink) and oxygen (red).

New materials improve oxygen catalysis

Highly active catalysts could be key to improved energy storage in fuel cells and advanced batteries.

September 17, 2013

In a new graphene-on-silicon photodetector, electrodes (gold) aredeposited, slightly asymmetrically, on either side of a silicon waveguide(purple). The asymmetry causes electrons kicked free by incoming light toescape the layer of graphene (hexagons) as an electrical current.

Graphene could yield cheaper optical chips

Researchers show that graphene — atom-thick sheets of carbon — could be used in photodetectors, devices that translate optical signals to electrical.

September 15, 2013

MIT News | Massachusetts Institute of Technology

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