Computer chips

Chips that can steer light

Record-setting ‘optical phased arrays’ could lead to better laser rangefinders, smaller medical-imaging devices and even holographic TVs.

January 9, 2013

In this micrograph of an experimental transistor, blue highlighting indicates areas of "strain," where germanium atoms have been forced closer together than they find comfortable. One of the reasons for the transistor's record-setting performance is that the strain has been relaxed in the lateral direction.

Researchers demonstrate record-setting p-type transistor

New design for a basic component of all computer chips boasts the highest ‘carrier mobility’ yet measured.

January 3, 2013

A cross-section transmission electron micrograph of the fabricated transistor. The central inverted V is the gate. The two molybdenum contacts on either side are the source and drain of the transistor. The channel is the indium gallium arsenide light color layer under the source, drain and gate.

Tiny compound semiconductor transistor could challenge silicon’s dominance

MIT researchers develop the smallest indium gallium arsenide transistor ever built.

December 10, 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

New chip captures power from multiple sources

System developed at MIT could combine power harvested from light, heat and vibrations to run monitoring systems.

July 9, 2012

A photo of an Xilinx field-programmable gate array, or FPGA.

Simulating tomorrow’s chips

A new system makes hardware models of multicore chips more efficient, easier to design and more reliable.

April 13, 2012

Chips as mini Internets

The data-routing techniques that undergird the Internet could increase the efficiency of multicore chips while lowering their power requirements.

April 10, 2012

The Center for Polymer Microfabrication is designing processes for manufacturing microfluidic chips. Pictured here is a chip fabricated by the center's tailor-made production machines.

Moving microfluidics from the lab bench to the factory floor

The Center for Polymer Microfabrication designs manufacturing processes for a new generation of diagnostic tools.

March 29, 2012

Testing unbuilt chips

A new software-simulation system promises much more accurate evaluation of promising — but potentially fault-ridden — multicore-chip designs.

March 9, 2012

A new approach helps researchers make tiny three-dimensional structures. Pictured are two packaged microchips, each with tiny bridges fabricated on their surfaces.

Tiny 3-D chips

MIT researchers develop a new approach to producing three-dimensional microchips.

February 28, 2012

A new test chip developed by Vladimir Stojanovic, Rajeev Ram and their colleagues, which monolithically integrates electrical and optical components and was produced on an existing IBM manufacturing line.

Microchips’ optical future

To keep energy consumption under control, future chips may need to move data using light instead of electricity — and the technical expertise to build them may reside in the United States.

February 15, 2012

Research update: Sharpening the lines

New advance could lead to even smaller features in the constant quest for more compact, faster microchips.

December 14, 2011

Caroline Ross, the Toyota Professor of Materials Science and Engineering at MIT

Important step toward computing with light

Research at MIT produces long-sought component to allow complete optical circuits on silicon chips.

November 23, 2011

Fabricated analog very-large-scale integration (VLSI) chip used to mimic neuronal processes involved in memory and learning.

Mimicking the brain, in silicon

New computer chip models how neurons communicate with each other at synapses.

November 15, 2011

Controlling the collapse of tiny pillars deposited on a silicon substrate can produce intricate patterns.

Building chips from collapsing nanopillars

By turning a common problem in chip manufacture into an advantage, MIT researchers produce structures only 30 atoms wide.

September 1, 2011

MIT News | Massachusetts Institute of Technology

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