Researchers in Professor Christina Smolke's laboratory have developed an advanced, high-throughput directed evolution platform for designing and discovering RNA devices that can sense and respond to various target ligands in real-time.
Researchers at Stanford are developing a device that uses quantum engineered states and interactions to detect electromagnetic waves with a sensitivity and bandwidth beyond that possible with existing technology.
Cancer specific antigenic epitopes called neoantigens are necessary for effective adoptive T cell therapies. Neoantigens generate cytotoxic T lymphocytes (CTLs) and CTLs can be exploited to safely target and eliminate cancerous cells.
Stanford researchers have developed a method to use conditional generative adversarial networks (C-GANs) for solving highly complex optimization problems, e.g., with 1050 to 10 80 dimensions.
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 in the Vuckovic group have developed an optical phased array (OPA) for solid-state beam-steering in optical systems such as LIDAR, projectors, and microscopy.
Researchers at Stanford have developed technology to bring new dimensions to wearable haptic devices and better reflect the breadth of haptic interactions in our lives.
Researchers at Stanford have developed an ultracompact, high-quality-factor (high-Q) metasurface that enables more convenient phase contrast imaging. Phase contrast imaging is a critical technique in biology and medicine to image essentially transparent objects such as cells.
This invention facilitates the realization of optical elements with spatially multiplexed/interleaved phase profiles to achieve a high packing density of distinct optical elements on a surface.
Stanford researchers in The Fan Group have developed an optical device that can fine tune the color of each photon in a stream of light. Existing methods simply reroute photons of a particular frequency, but do not actually change the photons frequencies.
Stanford researchers have developed a portable sensor device for rapid detection of heavy metal ions using a sulfidation process and concentrator for increased visual detection.
Researchers in Stanford's Yi Cui Lab have developed an ultra-light, fire-retardant battery current collector. Commercial Cu-Al current collectors account for 15-50 wt.% of the total battery weight – dead weight that dramatically limits battery density.
Stanford researchers have developed a high efficiency OLED device by nanopatterning the electrode layer to create a high impedance metasurface (HIM) that reduces 'plasmonic' losses. A typical metal cathode traps a large portion of generated light in an OLED.