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Researchers at MIT have discovered new way of using laser light to tune electronic energy levels in two-dimensional films of crystal. The discovery could ultimately pave the way for the development of so-called “valleytronic” devices, which harness the way electrons gather around two equal energy states, known as valleys.

Toward “valleytronic” devices for data storage or computer logic systems

Researchers have discovered a new way to tune electronic energy levels in some 2-D materials.

March 9, 2017

MIT graduate student Changmin Lee stands by an experimental setup that uses light pulses to map the magnetic direction and strength of a buried interface between two exotic materials, bismuth selenide and europium sulfide.

Mapping buried magnetism

MIT researchers use an optical technique to probe magnetism at a hidden interface between two exotic thin films.

October 25, 2016

Twelve School of Science faculty appointed to career development professorships

September 2, 2016

At left: A single crystal compound of gadolinium, platinum, and bismuth made with naturally occurring elements. At right, a single crystal of this material made with isotopically enriched gadolinium for neutron scattering experiments. Both crystals are approximately 1 mm in size.

Mixing topology and spin

MIT-led team demonstrates paired topology and intrinsic magnetism in compound combining gadolinium, platinum, and bismuth.

July 19, 2016

These graphs, known as Riemann surfaces, describe the energy-momentum relationships of electrons in the surfaces of exotic new materials called topological semimetals.

Physicists predict previously unseen phenomena in exotic materials

Better understanding of topological semimetals could help usher in future electronics.

June 6, 2016

Arrows indicate the spin direction in the ferromagnetic insulator (EuS, shown in red) and topological insulator (Bi2Se3, shown in blue) at the interface between the two materials.

Researchers find unexpected magnetic effect

Combining two thin-film materials yields surprising room-temperature magnetism.

May 9, 2016

MIT postdoc Cui-Zu Chang works with equipment that can monitor topological insulator thin-film quality as it grows. The bright green vertical bar on computer screen is an indicator of very high-quality film growth. Chang led work in the Moodera group showing the first zero-resistance edge state in a circuit.

Achieving zero resistance in energy flow

MIT postdoc Cui-Zu Chang makes a spintronic breakthrough in the Moodera group.

May 6, 2016

MIT Senior Research Scientist Jagadeesh Moodera stands in front of a custom-built system used to fabricate ultrathin films. His work includes devices that exhibit resistance-free, spin-polarized electrical current; enabling memory storage at the level of single molecules; and the search for the elusive Majorana fermions sought for quantum computing.

Research highlight: Jagadeesh Moodera

Step-by-step, the Moodera Research Group is building the essential knowledge and hardware for next-generation quantum computers.

April 29, 2016

Synthesizing new physics: MIT assistant professor of physics Joseph Checkelsky (center) and graduate students Linda Ye (left) and Aravind Devarakonda are working to uncover new properties linked to collective behavior of electrons. Their work blends materials science and solid state physics and makes extensive use of high-temperature furnaces (behind them in photo) to produce interesting new compo...

Faculty highlight: Joseph Checkelsky

Synthesizing new physics: Assistant professor blends materials science and solid state physics to uncover new properties linked to collective behavior of electrons.

March 16, 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

Faculty highlight: Nuh Gedik

Associate professor's work on topological insulators and atomically thin materials yields new, laser-driven approaches to materials for electronics.

October 9, 2015

How to make large 2-D sheets

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

September 21, 2015

This diagram shows the layered structure analyzed for its magnetic properties. Yellow spheres represent tellurium atoms; light blue spheres represent antimony-bismuth; and purple spheres represent sulfur. The black sphere with an arrow represents an atom of dopant, and green spheres with arrows show atoms of europium. Different colored arrows show various ways an europium ion can be affected by th...

Unusual magnetic behavior observed at a material interface

Findings could lead to a building block for future quantum computers, and a research tool for physics.

August 18, 2015

Geoffrey Beach, Kripa Varanasi, Michael Watts, Anne White, Hamsa Balakrishnan, Constantinos Daskalakis, Jacquin Niles, Rohit Karnik, Wojciech Matusik, Colette Heald, Benoit Forget, Alfredo Alexander-Katz, Maria Yang

Newly tenured engineers

Thirteen tenure appointments are made in seven of eight academic departments in the School of Engineering.

May 19, 2015

Faculty highlight: Pablo Jarillo-Herrero

MIT physics professor has played a leading role in the development of revolutionary new artificial materials.

May 6, 2015

MIT News | Massachusetts Institute of Technology

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