Light

Images showing interference patterns (top) and a Wilson loop (bottom) were produced by the researchers to confirm the presence of non-Abelian gauge fields created in the research.

Exotic physics phenomenon is observed for first time

Observation of the predicted non-Abelian Aharonov-Bohm Effect may offer step toward fault-tolerant quantum computers.

September 5, 2019

Chip design drastically reduces energy needed to compute with light

Simulations suggest photonic chip could run optical neural networks 10 million times more efficiently than its electrical counterparts.

June 5, 2019

MIT researchers have developed novel photography optics, dubbed “time-folded optics,” that captures images based on the timing of reflecting light inside the lens, instead of the traditional approach that relies on the arrangement of optical components. The invention opens doors for new capabilities for ultrafast time- or depth-sensitive cameras.

Novel optics for ultrafast cameras create new possibilities for imaging

Technique can capture a scene at multiple depths with one shutter click — no zoom lens needed.

August 13, 2018

Researchers at MIT and Israel's Technion used a thin-film material composed of layers of gallium-arsenide and indium-gallium-arsenide, overlaid with a layer of graphene, as shown in this diagram, to produce strong interactions between light and particles that could someday enable highly tunable lasers or LEDs.

Researchers devise new way to make light interact with matter

Reducing the wavelength of light could allow it to be absorbed or emitted by a semiconductor, study suggests.

June 4, 2018

This cloaking grenade, used for hiding troop operations from view on the battlefield, is an example of nanoparticles that reflect a particular color of light based on their exact size and composition. New work by MIT researchers provides a way to predict the light-scattering properties of layered nanoparticles – or to design particles to match a desired type of light-scattering behavior.

AI-based method could speed development of specialized nanoparticles

Neural network could expedite complex physics simulations.

June 1, 2018

A drawing illustrates the unusual topological landscape around a pair of features known as exceptional points (red dots), showing the emergence of a Fermi arc (pink line at center), and exotic polarization contours that form a Mobius-strip-like texture (top and bottom strips).

New exotic phenomena seen in photonic crystals

Researchers observe, for the first time, topological effects unique to an “open” system.

January 11, 2018

Researchers have created in simulations the first system in which can be manipulated by a beam of ordinary light rather than the expensive specialized light sources required by other systems.

Tiny “motors” are driven by light

Researchers demonstrate nanoscale particles that ordinary light sources can set spinning.

June 30, 2017

This futuristic drawing shows programmable nanophotonic processors integrated on a printed circuit board and carrying out deep learning computing.

New system allows optical “deep learning”

Neural networks could be implemented more quickly using new photonic technology.

June 12, 2017

This image shows simulated iso-frequency contours of a photonic crystal slab superimposed on each other and tiled.

New method for analyzing crystal structure

Exotic materials called photonic crystals reveal their internal characteristics with new method.

November 25, 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

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

A mild temperature change radically alters the degree to which a solid-fluid mixture bends light.

Mixing solids and liquids enhances optical properties of both

New approach can dramatically change the extent to which optical devices scatter light.

June 9, 2016

A proof-of-concept device built by MIT researchers demonstrates the principle of a two-stage process to make incandescent bulbs more efficient. This device already achieves efficiency comparable to some compact fluorescent and LED bulbs.

A nanophotonic comeback for incandescent bulbs?

Researchers combine the warm look of traditional light bulbs with 21st-century energy efficiency.

January 11, 2016

This image shows the spatial distribution of charge for an accelerating wave packet, representing an electron, as calculated by this team’s approach. Brightest colors represent the highest charge levels. The self-acceleration of a particle predicted by this work is indistinguishable from acceleration that would be produced by a conventional electromagnetic field.

Particles accelerate without a push

New analysis shows a way to self-propel subatomic particles, extend the lifetime of unstable isotopes.

January 20, 2015

Plot of radiative quality factor as a function of wave vector for a photonic crystal slab. At five positions, this factor diverges to infinity, corresponding to special solutions of Maxwell equations called bound states in the continuum. These states have enough energy to escape to infinity but remain spatially localized.

Trapping light with a twister

New understanding of how to halt photons could lead to miniature particle accelerators, improved data transmission.

December 22, 2014

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