Quantum computing

The 2017 MIT recipients of the U.S. Department of Energy Computational Science Graduate Fellowships are (clockwise from top left) Peter Ahrens, Miriam Rathbun, Annie Yuan Wei, and Kevin Silmore.

Grad students earn Department of Energy computational fellowships

Ahrens, Rathbun, Silmore, and Wei are recognized for tackling complex science and engineering problems of national importance.

October 11, 2017

This vacuum chamber with apertures for several laser beams was used to cool molecules of sodium-potassium down to temperatures of a few hundred nanoKelvins, or billionths of a degree above absolute zero. Such molecules could be used as a new kind of qubit, a building block for eventual quantum computers.

Ultracold molecules hold promise for quantum computing

New approach yields long-lasting configurations that could provide long-sought “qubit” material.

July 27, 2017

A micrograph of the MIT researchers’ new device, with a visualization of electrical-energy measurements and a schematic of the device layout superimposed on it.

Toward optical quantum computing

Prototype device enables photon-photon interactions at room temperature.

June 16, 2017

A team of researchers from MIT, Harvard University, and Sandia National Laboratories reports a new technique for creating targeted defects in diamond materials, which is simpler and more precise than its predecessors and could benefit diamond-based quantum computing devices.

Toward mass-producible quantum computers

Process for positioning quantum bits in diamond optical circuits could work at large scales.

May 26, 2017

MIT physicists have found that a flake of graphene, when brought in close proximity with two superconducting materials, can inherit some of those materials’ superconducting qualities. As graphene is sandwiched between superconductors, its electronic state changes dramatically, even at its center. Pictured is the experimental concept and device schematic.

Sandwiched between superconductors, graphene adopts exotic electronic states

Platform may be used to explore avenues for quantum computing.

May 4, 2017

“I fell in love with physics,” says senior Zachary Hulcher. “I appreciate light bouncing off a mirror, and smoke billowing up, and light going through it in a different way. … The small things I took for granted when I didn’t understand them, I appreciate now. Everything is just a little prettier.”

From football to physics

Zachary Hulcher, Marshall Scholar and offensive lineman, will study high-energy physics in the U.K.

February 27, 2017

In this illustration, each colored line represents a different state of a “spin chain,” which can be thought of as the magnetic orientations, or spins, of a string of quantum particles. Where the line rises, the spin is up; where it falls, the spin is down; and where it’s flat, the spin is zero. MIT researchers modeled the entanglement of a quantum system as the “superposition” of such s...

Entanglement bonanza

Relatively simple quantum computers could be much more powerful than previously realized.

November 18, 2016

This image shows the basic setup that enables researchers to use lasers as optical “tweezers” to pick individual atoms out from a cloud and hold them in place. The atoms are imaged onto a camera, and the traps are generated by a laser that is split into many different focused laser beams. This allows a single atom to be trapped at each focus.

Scientists set traps for atoms with single-particle precision

Technique may enable large-scale atom arrays for quantum computing.

November 3, 2016

“Learning from this model, we can understand what’s really going on in these superconductors, and what one should do to make higher-temperature superconductors, approaching hopefully room temperature,” says Martin Zwierlein, professor of physics and principal investigator in MIT’s Research Laboratory of Electronics.

For first time, researchers see individual atoms keep away from each other or bunch up as pairs

Observations of atomic interactions could help pave way to room-temperature superconductors.

September 15, 2016

Toward practical quantum computers

Built-in optics could enable chips that use trapped ions as quantum bits.

August 8, 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 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

Stabilizing quantum bits

Feedback technique used on diamond “qubits” could make quantum computing more practical.

April 6, 2016

Researchers have designed and built a quantum computer from five atoms in an ion trap. The computer uses laser pulses to carry out Shor’s algorithm on each atom, to correctly factor the number 15.

The beginning of the end for encryption schemes?

New quantum computer, based on five atoms, factors numbers in a scalable way.

March 3, 2016

Crunching quantum code

MIT physics graduate student Sagar Vijay co-develops error correction method for quantum computing based on special electronic states called Majorana fermions.

February 12, 2016

MIT News | Massachusetts Institute of Technology

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