Research

• Batteries last longer

• Data centers use less energy

• Satellites work better

• Infections are observed

• New materials are discovered

This happens by applying our core competencies in thermal physics, vibrational spectroscopy, nanophotonics, and 2D-solids.

Meta-Spectroscopy

Problem: Spectroscopy measures light to get information. Current systems are too big, “general purpose” and not sensitive enough.

Path: Combine ultrasharp nanophotonic filters, compressed sensing and advanced spectroscopic fitting to make spectrometers “application specific,” ultrasensitive, and contained to a single microchip.

Polaritonic Energy Transport

Problem: Heating in electronics limits performance and reliability. Transporting heat is inefficient in microelectronics because the heat carriers (i.e., phonons) are too “big” relative to the devices through which they move. A new heat carrier is needed.

Path: Polaritons are this heat carrier. Being a hybrid of light (i.e., a photon) and a phonon or electron, they become more efficient at moving heat as their surroundings get smaller. We seek ways of designing polaritons to maximize their heat carrying ability.

Emerging Material Systems 

Problem: New materials are needed for applications in computing, sensing, water-treatment, and imaging. Material development requires means to determine the links between process and properties.

Path: Advanced spectroscopic techniques like Raman, FTIR, and IR-ellipsometry provide such information. We use these techniques to help advance next-generation ferroelectrics, oxides, and 2D-materials.