Stanford researchers have developed a simple and rapid epoxy-based method for transferring photonic crystal (PC) cavities to the tip of an optical fiber.
Stanford researchers have developed an efficient and low-cost device which increases the energy harvest of a system by recovering these losses through module-level maximum power point tracking (MPPT).
Researchers in Prof. William Dally's laboratory have designed a dragonfly topology that reduces the cost of high-radix networks by reducing the number of long, global cables.
Researchers in Prof. Lambertus Hesselink's laboratory have developed a compact, sensitive X-ray differential phase contrast (DPC) imaging system that improves field of view, increases fringe visibility and shortens imaging times.
Engineers in Prof. Arunava Majumdar's laboratory have formulated high-entropy phase-change materials that can split water to produce hydrogen at moderate temperatures using a scalable, carbon-free process.
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
This compact, low-cost, high resolution angular position sensor is designed to improve the movement of rotary joints. The capacitive sensor, which includes two flat discs patterned with conductive material can be packaged in tight spaces.
Engineers in Prof. Mark Cutkosky's laboratory have developed a gentle gripper device that can conform to, grasp, and lift a wide range of objects using an air bladder enhanced with gecko-inspired shear adhesion.
Stanford researchers have developed a depletion-mode MOSFET-based phototransistor with sub-wavelength dimensions, extremely high responsivity and a low dark current.
Stanford researchers have developed a novel method for wafer-scale production of aligned and ultra-high density carbon nanotubes (CNTs) and nanotube grid.
This patented technology is an Integrated Capacitance Bridge (ICB) that can perform ultra-high-resolution (aF), wide-temperature-range measurements of capacitance in nano-structures.
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.