Materials Science and Engineering

Ju Li, a professor in MIT’s departments of materials science and engineering and nuclear science and engineering.

Profile: Ju Li explores new nanomaterials

Working from the scale of atoms on up, he designs materials for future energy applications.

October 10, 2012

A solid-state lithium-air battery (highlighted in orange) is positioned inside a test chamber at the Advanced Light Source (ALS) at Lawrence Berkeley National Laboratory, in preparation for its testing using X-ray photoelectron microscopy.

New technique reveals lithium in action

Fundamental reactions behind advanced battery technology, revealed in detail by advanced imaging method, could lead to improved materials.

October 8, 2012

A dislocation in a crystal lattice, a disconnected region in its structure (represented by the array of atoms shown in blue) can separate from the rest of the lattice at a rate determined by the potential energy of the system, represented by the wavy surface. To the left, the higher potential energy (shown in red) prevents the defect from moving in that direction, but to the lower right (shown in ...

Probing the mysteries of cracks and stresses

Analysis of molecular-level fracture and stress mechanisms could have broad implications for understanding materials’ behavior.

September 28, 2012

From left to right, Ronald Ballinger, Thomas McKrell, Bilge Yildiz, Dennis Whyte, Michael Short, Sidney Yip, Linn Hobbs and Ju Li.

Understanding and predicting materials behavior

Department of Nuclear Science and Engineering takes an interdisciplinary approach

September 26, 2012

Abstract graphic of pink circles and half circles on a purple background

Oscillating microscopic beads could be key to biolab on a chip

MIT team finds way to manipulate and measure magnetic particles without contact, potentially enabling multiple medical tests on a tiny device.

September 25, 2012

Musician and instrument designer Mark Stewart.

World-class musician Mark Stewart comes to the Glass Lab

In a yearlong residency, the musician and instrument designer will build a glass orchestra with MIT students.

September 14, 2012

U.S. News ranks MIT sixth overall among U.S. universities

Institute’s undergraduate engineering program is again ranked No. 1; undergraduate business program is No. 2.

September 12, 2012

From left to right, graduate student Sha Huang, Principal Research Scientist Ming Dao, Research Scientist Monica Diez-Silva.

Protein impedes microcirculation of malaria-infected red blood cells

MIT-led research team finds that protein significantly reduces infected cells’ ability to squeeze through tiny channels compared to healthy cells.

August 30, 2012

Tongjai Chookajorn, left, and Heather Murdoch, the lead authors of <i>Science</i> paper on the design and production of new stable nanocrystalline metal alloys with exceptional strength and other properties.

Engineers achieve longstanding goal of stable nanocrystalline metals

Method developed by MIT researchers could produce materials with exceptional strength and other properties.

August 23, 2012

A scanning electron micrograph of carrot, top, and potato, bottom, showing relatively thin-walled cells. The oval objects within the potato tissue are starch granules.

Plants exhibit a wide range of mechanical properties, engineers find

Biological structures may help engineers design new materials.

August 14, 2012

An artist's representation of the structures produced by this self-assembly method shows a top-down view, with the posts produced by electron-beam lithography shown in blue, and the resulting self-assembled shapes shown in white.

Research update: Chips with self-assembling rectangles

New technique allows production of complex microchip structures in one self-assembling step.

July 19, 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

This electron microscope image shows two layers of nanowires produced through the MIT team's self-assembly process, showing how deviations in the pattern and connections between the layers can be included in the design.

Teaching self-assembling structures a new trick

MIT researchers produce 3-D configurations that could lead to new microchips and other devices.

June 7, 2012

Proteins (actin, red and vinculin, green) inside adult bone marrow-derived stem cells that were grown in the lab for three days, with (top image) and without (bottom) the 'crowder' particles. Cells grown with the crowders form neatly aligned structures, or matrices, outside the cell, which in turn align their internal actin networks; the structures both outside and inside the cells grown without t...

Crowding causes cells to produce an orderly matrix of molecules

Making proteins stand in line could lead to more lifelike lab tests.

May 24, 2012

MIT News | Massachusetts Institute of Technology

Browse By

Topics

Departments

Centers, Labs, & Programs

Schools

Department