Stanford researchers at the Poon Lab have developed a method for battery-less, short range transmission of data with very low power and very high data rates. It can potentially replace current near field communications (NFC) systems due to these advantages.
Stanford researchers have designed a frequency-multiplexed neural probe architecture that enables massive scaling of electrophysiological recording from neurons.
Stanford researchers have patented a design for electronically pumping photonic crystal membrane nanocavities using a lateral p-i-n junction. The p-i-n junction can be defined by any number of methods, including ion implantation, regrowth, or diffusion doping.
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 at the Khuri-Yakub Lab have developed a new sensor topology that will enable high-resolution touch sensing and reliable authentication on portable electronics.
Stanford researchers have developed a new strategy for designing, making and collecting data from a passive (non-powered), flexible pressure sensor for intra-cranial pressure (ICP) monitoring at the optimal Ghz frequencies for wireless transmission in biological tissues.
Stanford researchers have developed a wearable, flexible, high sensitivity pressure sensor that provides information about cardiovascular health, emotional state, and other aspects of human physiology.
Stanford researchers are using nanowires (NWs) to raise the performance of organic solar cells. Organic solar cells' main weakness is their lack of efficiency compared to in-organic solar cells.