Stanford researchers at the Jaramillo, Nørskov, and Cargnello Labs have developed an improved system to generate NH3 (ammonia) from N2 and H2O via a low-pressure, electro-thermochemical, sustainable alternative to the conventional Haber-Bosch p
Researchers in Prof. Hongjie Dai's laboratory have combined graphene with metals and other inorganic elements to create a variety of hybrid materials that can be used for high performance electrocatalytic or electrochemical devices such as batteries and fuel cells.
Researchers in Prof. Hongjie Dai's laboratory have developed nanocarbon/inorganic nanoparticle hybrid materials for various electrocatalytic and electrochemical applications, such as batteries and fuel cells. Three types of hybrid materials have been created:
A multidisciplinary team of Stanford researchers have developed a new class of tunable, zinc-based sorbents that use catalytic carbonate chemistry to efficiently capture carbon in the presence of water vapor.
Stanford researchers developed a 'self-healing' polymer coating that conforms to and stabilizes lithium metal battery electrodes. The polymer is an extremely stretchy, flexible and adaptive protective layer.
Using bamboo inspired carbon nanofibers, Stanford researchers at the Yi Cui Lab have created a freestanding, flexible and elastic electrode for energy storage devices.
Stanford researchers developed a method to increase microbial fermentation gas transfer – a limiting factor in the production of bio products such as polyhydroxyalkanoates (PHAs).
A new method for underground mapping and imaging allows the use of the underground reflections of electromagnetic pulses caused by lightning (occurring up to thousands of miles away) to be used for geologic imaging.
Rechargeable lithium sulfur batteries have attracted great interest in recent years because of their high theoretical specific energy, which is several times that of current lithium-ion batteries.
This invention provides a novel strategy for depolymerizing polyesters and polycarbonates with alcohols through the use of nucleophilic N-heterocyclic carbenes as catalysts.
Researchers in Prof. Juan Santiago's laboratory have developed a novel isotachophoresis (ITP) method to easily and seamlessly integrate various electrophoresis-based detection techniques with ITP preconcentration.