Stanford researchers in the Kanan Lab have developed a scalable method for achieving verifiable, safe, and permanent carbon removal at relatively low energy demand.
Stanford researchers within the Dionne Lab have developed a method to use copper titanium dioxide core-shell nanoparticles for the light driven production of green fuels or removal of contaminants in water.
Researchers at Stanford University have developed gas diffusion layers with engineered surface roughness within the gas pathway of electrochemical devices that improves catalyst utilization.
Stanford researchers have developed a novel approach to make a stable and active platinum-alumina catalyst that maintains high activity under harsh conditions.
Researchers at Stanford have developed a frequency-selective MHz power amplifier for generating dielectric barrier discharge (DBD) plasma. Commercial applications include plasma-assisted nitrogen fixation for fertilizer production.
Stanford researchers in the Swartz lab have developed a method for improving the productivity of biosynthetic processes via enzymatic detoxification of aberrant forms of NAD(P)H.
Stanford inventors have developed a cell-free method for carbon-negative biosynthetic production of commodity biochemicals by using hydrogen gas as a source of reducing equivalents.
Stanford researchers in the Swartz lab have proposed a method to synthesize metabolic cofactors from inexpensive substrates for protein synthesis and commodity production applications.
Stanford University researchers have developed a system that achieves atmospheric water harvesting with high specific productivity, defined as the rate of water collected per mass of absorbent material.
Chemical engineers at Stanford have developed miscible antifoams that are easy to incorporate and do not separate out from the target liquid during operation.
Stanford researchers have developed a patented microscopy method which can provide chemical identification of molecular structures with radiation spectroscopy at nanometer or near-atomic scales, which is one of the most challenging problems in microscopy.
Wastewater treatment is energy and cost intensive. Demand charges on electricity bills often account for a large share of electricity costs, creating strong incentives for shifting load peaks away from time-of-use periods.