Stanford researchers have developed a highly conductive, stretchable polymer that is durable enough for wearable electronics. To improve flexibility they doped poly(3,4-ethylenedioxythiophene) polystyrene sulfonate (PEDOT:PSS)with ionic liquid plasticizer.
Researchers in Prof. Zhenan Bao's laboratory have developed an intrinsically stretchable and healable semiconductor polymer to fabricate high performance organic field-effect transistors for flexible and wearable electronic devices.
Stanford researchers have for the first time, demonstrated the use of scaffolding to increase the mechanical and chemical stability of perovskite solar cells.
Stanford researchers have developed a new way to deposit robust and efficient photoactive perovskite materials in open-air and at rapid linear processing rates in excess of 1 cm/s.
Researchers in Prof. Shanhui Fan's laboratory have developed a flexible, transparent, nanostructured material that enables daytime radiative cooling while preserving the color of the underlying substrate.
Stanford researchers have developed a novel method for wafer-scale production of aligned and ultra-high density carbon nanotubes (CNTs) and nanotube grid.
Using bamboo inspired carbon nanofibers, Stanford researchers at the Yi Cui Lab have created a freestanding, flexible and elastic electrode for energy storage devices.
Researchers in Stanford's Nanoscale Prototyping Laboratory have developed a low-temperature process for fabricating etch-resistant, pinhole-free spacer dielectrics a few nanometers thick.
Stanford researchers have patented a crystalline germanium nanostructure device and method of forming a continuous polycrystalline Ge film (5-500nm thick poly-Ge) with crystalline Ge islands of preferred orientation.
Stanford University and Samsung researchers have patented a microfluidic-based platform that can rapidly fabricate and characterize Organic Thin Film Transistor (OTFT) arrays composed of solution-processable organic semiconducting polymers.
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 an ultra-sensitive resistive pressure sensor based on an elastic, microstructured conducting polymer (EMCP) thin film.
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 have developed a stretchable, low power consumption, highly tunable resistive pressure sensor and organic electrochromic device (ECD). This electronic skin detects and distinguishes varying pressure through real-time visible color change.