2-D

Researchers in MIT’s Department of Mechanical Engineering have developed a technique to harvest 2-inch diameter wafers of 2-D material within just a few minutes.

Researchers quickly harvest 2-D materials, bringing them closer to commercialization

Efficient method for making single-atom-thick, wafer-scale materials opens up opportunities in flexible electronics.

October 11, 2018

Physicists at MIT and Harvard University have found that graphene, a lacy, honeycomb-like sheet of carbon atoms, can behave at two electrical extremes: as an insulator, in which electrons are completely blocked from flowing; and as a superconductor, in which electrical current can stream through without resistance.

Insulator or superconductor? Physicists find graphene is both

When rotated at a "magic angle," graphene sheets can form an insulator or a superconductor.

March 5, 2018

This summer, Jennifer Coulter worked on modeling the behavior of ferromagnetic particles with Alfredo Alexander-Katz, the Walter Henry Gale Associate Professor of Materials Science and Engineering at MIT.

Modeling how colloidal particles spin through a fixed array

Summer Scholar Jennifer Coulter works on computer simulations with associate professor of materials science Alfredo Alexander-Katz.

August 29, 2016

Membrane structures in plant xylem from different species are being investigated for use in water filtration.

J-WAFS Solutions program awards $750,000 in commercialization grants

Four new projects and one renewal receive $150,000 in funding for 2016-2017.

August 12, 2016

The process of making a stack of parallel sheets of graphene starts with a chemical vapor deposition process (I) to make a graphene sheet with a polymer coating; these layers are then stacked (II), folded and cut (III) and stacked again and pressed, multiplying the number of layers. The team used a related method the team to produce scroll-shaped fibers.

Borrowing from pastry chefs, engineers create nanolayered composites

Method to stack hundreds of nanoscale layers could open new vistas in materials science.

July 21, 2016

Emission spectra are a widely used method for identifying chemical compounds; the bright lines reveal the different frequencies of light that can be emitted by an atom. Here, a normal emission spectrum for an atom in a high-energy state (top) is compared to the emission from the same atom placed just a few nanometers (billionths of a meter) away from graphene that has been doped with charge carrie...

Study opens new realms of light-matter interaction

Some “forbidden” light emissions are in fact possible, could enable new sensors and light-emitting devices.

July 14, 2016

MIT postdoc Junwei Liu and collaborators are proposing a new random access memory (RAM) device architecture using ferroelectric tunneling RAM.

Charging up random access memory

Researchers demonstrate room-temperature ferroelectric states in ultra-thin films of tin and tellurium.

July 14, 2016

This illustration depicts the process of light emission from a sheet of graphene, which is represented as the blue lattice on the top surface of a carrier material. The light-colored arrow moving upwards at the center depicts a fast-moving electron. Because the electron is moving faster than light itself, it generates a shock wave, which spews out plasmons, shown as red squiggly lines, in two dire...

Researchers discover new way to turn electricity into light, using graphene

By slowing down light to a speed slower than flowing electrons, researchers create a kind of optical “sonic boom.”

June 13, 2016

Researchers used the spin of light to guide the flow of optical information. Shining right-circularly polarized light on nanoribbons made of special 2-D materials enables light to flow forward on one edge and backward on the other edge. Changing the polarization of the light causes the guided modes to reverse directions.

New way to control particle motions on 2-D materials

Study points the way to new photonic devices with one-way traffic lanes.

March 21, 2016

In Profile: Pablo Jarillo-Herrero

Experimental physicist explores the wild frontiers of graphene and other ultrathin materials.

February 24, 2016

Researchers used the MIT and Tim the Beaver logos to show photoluminescence emissions from a monolayer of molybdenum disulfide inlayed onto graphene. The arrow indicates the graphene-MoS2 lateral heterostructure, which could potentially form the basis for ultrathin computer chips.

New chip fabrication approach

Depositing different materials within a single chip layer could lead to more efficient computers.

January 27, 2016

Materials Processing Center Director Carl V. Thompson addresses the annual Materials Day Symposium, "Quantum Materials," at MIT on Oct. 14.

Quantum materials: A new paradigm for computing?

Diamond spintronics and graphene-based infrared detectors are among leading-edge technologies reported at annual Materials Day Symposium at MIT.

November 6, 2015

Desalination gets a graphene boost

Jeffrey Grossman applies new materials research to making desalination cheaper and more efficient.

November 2, 2015

How to make large 2-D sheets

MIT-led team develops method for scaling up production of thin electronic material.

September 21, 2015

Schematic of the Floquet-driven chiral edge state along the boundary of the laser-exposed region.

New findings could point the way to “valleytronics”

Researchers clear hurdles toward a new kind of 2-D microchip using different electron properties.

December 15, 2014

MIT News | Massachusetts Institute of Technology

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