Whether in a smartphone or laptop, semiconductors form the basis of modern electronics and accompany us constantly in everyday life. The processes taking place inside these materials are the subject ...

What do microplastics, water color, and satellites have in common? Dr. Karl Kaiser, professor of marine and coastal ...

High-Pressure Photoelectron Spectroscopy (HPPES) advances catalysis research by enabling real-time surface analysis under ambient and high-pressure conditions.

Scientists are learning how to temporarily reshape materials by nudging their internal quantum rhythms instead of blasting ...

But this breakthrough doesn't stand alone; recent developments in plastic science and recycling include pyrolysis research to ...

Physical Chemistry applies the principles and concepts of physics to understand the basics of chemistry and explain how and why transformations of ...

Bioxytran, Inc. (OTCQB: BIXT) (“Bioxytran” or the “Company”), a clinical-stage biotechnology company developing platform technologies spanning glycovirology, hypoxia, and degenerative diseases, announ ...

The discovery of catalytic RNA transformed our understanding of life's beginnings. Clare Sansom explores how the RNA world ...

The Materials Science Learning Center (MSLC) offers resources and expert insights to enhance materials characterization and accelerate scientific breakthroughs.

NASA’s EMIT sensor uses imaging spectroscopy and spectral libraries to support large-scale tracking of plastic and other marine debris from space.

The fusion of biophotonics and AI is transforming healthcare, enhancing diagnostics and treatment with advanced light-based ...

Engineers at UNSW Sydney have developed a way to monitor solar cells at a microscopic level while they are operating to discover exactly how damage caused by ultraviolet light can be naturally ...