Researchers at Stanford have developed a process for modifying metal powder stock to enable printing of high reflectivity metals using moderate laser powers (200-400 W) in commercially available printing systems (200-400W).
Stanford inventors have discovered a single plant protein, FLOE1, that controls a variety of processes that are crucial to timely and robust germination of seeds.
Optimizing battery performance currently relies on empirical testing using arbitrary parameters, under-validated physiochemical models, and limited data analysis of summary trends.
Jennifer Cochran and Carolyn Bertozzi have collaborated to develop a bifunctional molecule called a polyspecific integrin-binding peptide (PIP)-LYTAC that can bind to integrins expressed on the surface of cancer cells and trigger their degradation via the lysosome.
Researchers at Stanford have developed a clinically applicable method of bone marrow conditioning for stem cell transplantation or treatment of hematologic malignancies.
Stanford researchers designed and built a light sheet microscope that can be used for deconvolution-free, high resolution volumetric imaging of cleared tissue specimens.
Researchers at Stanford University have developed a deep learning software algorithm that allows physicians running clinical trials to predict control patient outcomes using virtual control arms.
Stanford researchers have developed a method for etching microchannels through silicon substrates. Specifically, this method can produce wafers where the two sides have different features as well as through channels.
Researchers in the Stanford University Power Electronics Research Lab have designed an easy to implement, high-efficiency, high-frequency power amplifier with low voltage stress.
Stanford scientists have invented an inexpensive device to detect the first signs of lithium plating during fast-charging of lithium ion batteries, enabling early onboard detection of this issue during battery development or use.