Stephen Tsai and researchers at Stanford University's Structures and Composite Laboratory have designed a composite grid-stiffened skin structure, which is ultra-lightweight, stiff, strong, and easier and less expensive to manufacture.
Researchers at Stanford have developed a distributed digital "black box" audit trail design for connected and automated vehicle data and software assurance.
Stanford researchers at the Okamura Lab have prototyped a new retraction device that can reverse growth of a soft growing robot without undesired buckling.
Stanford researchers have developed a simple optical device for low-power, active light tuning. The device tunes the color of light across the visible spectrum and at select wavelengths by electrical biasing an array of micron sized pixels or nanowires.
Encapsulation of therapeutic cells can increase its efficacy, but current methods are non-uniform and inefficient. This inconsistency leads to varying interactions between each encapsulated cell and the extracellular matrix (ECM).
This invention is a set of structures and associated processes to integrate GaN with Diamond to develop a full complementary CMOS device capable of operation in high power and high temperature applications.
Stanford researchers have demonstrated a self healing electrode that can dramatically enhance the cycle lifetime of lithium ion batteries by applying Si microparticles with a thin layer of self-healing conductive composite.
Stanford researchers have designed a high-voltage cascode GaN/SiC device combining the advantages of both a GaN and an SiC device (i.e. reduced gate loss/simple gate drive requirements)
Magnetic field measurements using currently available devices require complex switching circuitry to mitigate the offset and noise present in measurements.
Researchers at Stanford University and SLAC National Accelerator Laboratory have developed a new coating design which makes lithium metal batteries stable and promising for further development.
Stanford researchers have developed a high-performance, ultrafast, thermoresponsive polymer that can act as a circuit breaker to prevent fires in next-generation high-energy-density batteries by rapidly and reversibly turning off when overheated.
Researchers in Prof. Yi Cui's laboratory have used a novel electrospinning process to fabricate a unique, transparent, highly conductive metal nanofiber material that could be used to replace indium tin oxide (ITO) in transparent electrodes.
Current injectable hydrogel materials have fast erosion and limited tunability of their mechanical properties at different stages of applications, limiting their biomedical applications.