MOCVD system to drive exploration of next-gen nitride materials

A laboratory upgrade at Cornell will help forge new directions for nitride semiconductors – materials best known for enabling LEDs and 5G communications – by expanding the capabilities of nitrides to support technologies such as quantum computers and next generation radiofrequency and power devices.

The upgrade includes the installation of a custom-built, metal-organic chemical vapor deposition (MOCVD) system in Duffield Hall. The system works by injecting vapors of carefully designed chemicals, known as precursors, onto a heated substrate, where the materials react and form ultra-thin crystalline layers. This process, known as epitaxial growth, allows researchers to build semiconductor structures with atomic-level precision and performance.

MOCVD has been used to grow the traditional family of nitride semiconductors – gallium nitride, aluminum nitride and indium nitride – that revolutionized energy-efficient lighting and high-frequency electronics.

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Programmable optical chip merges photons to change color

Cornell researchers have built a programmable optical chip that can change the color of light by merging photons, without requiring a new chip for new colors.

This form of nonlinear photonics could potentially be used for classical and quantum communications networks, all-optical signal processing and computation, spectroscopy and sensing.

“Previously, for each combination of colors you wanted to produce, you needed to fabricate a new device with a different design,” said Peter McMahon, associate professor of applied and engineering physics in Cornell Engineering, who led the project. “We now have a sort of universal device that lets you do any conversions you want, reprogrammably.”

The findings were published Oct. 8 in Nature. The paper’s first author is Ryotatsu Yanagimoto, a former postdoctoral researcher in the McMahon Lab and visiting scientist from NTT Research.

Read the full story in the Cornell Chronicle.

‘Bottling’ human intuition for AI-led materials discovery

Many properties of the world’s most advanced materials are beyond the reach of quantitative modeling. Understanding them also requires a human expert’s reasoning and intuition, which can’t be replicated by even the most powerful artificial intelligence, mixed with fortuitous accident, according to Eun-Ah Kim, the Hans A. Bethe Professor of physics in the College of Arts and Sciences and director of the Cornell-led National Science Foundation AI-Materials Institute. 

Kim and collaborators have developed a machine-learning model that encapsulates and quantifies the valuable intuition of human experts in the quest to discover new quantum materials. The model, Materials Expert-Artificial Intelligence (ME-AI), “bottles” this intuition into descriptors that predict the functional property of a material. The team used the method to solve a quantum materials problem.

Read the full story in the Cornell Chronicle.