Controlling light is an important technological challenge—not just at the large scale of optics in microscopes and telescopes ...

A device smaller than a grain of dust may help unlock the kind of quantum computers people have only dreamed about. Built on ...

A new microchip-sized device could dramatically accelerate the future of quantum computing. It controls laser frequencies with extreme precision while using far less power than today’s bulky systems.

The lithium niobate thin-film modulator was designed to achieve a modulation frequency of 350 kHz within the 0–2π phase range, further realizing high speed control of optical field coherence.

A tiny device can control laser light very precisely while using much less power, making it possible to build bigger and ...

HyperLight, creator of the TFLN Chiplet™platform, today announced the launch of the industry’s first 110 GHz IQ packaged modulators, available in both standard and low-Vπ versions. These 110 GHz IQ ...

Innovation paves the way for a high-volume, silicon photonics 400G/lane platform to meet next-generation 3.2T optical communication architectures for datacom and AI applications. The integrated ...

Computational fluorescence microscopy (CFM) requires accurate point spread function (PSF) characterization for high-quality ...

Spatial Light Modulators that use both translucent and reflective liquid crystal micro-display technology to dynamically modify the amplitude and/or phase of incident light one pixel at a time. Users ...

Improved absorption during plasma-dispersion pushes modulators to perform better. Absorption is used to push the modulators to perform better. Research by the University of Southampton’s Silicon ...