Researchers in Dr. Alfred Spormann's lab have developed a method of using co-cultures to enhance microbial electrosynthesis to allow more efficient production of desired products such as biofuel.
Engineers in Prof. H.-S. Philip Wong's laboratory have developed a lower power, three-dimensional resistive random access memory (RRAM) device using an atomically thin graphene edge electrode.
Researchers at Stanford have developed methods for preparing photo-, and chemical-, cross-linkable three-dimensional matrices for the controlled delivery of bioactive molecules for therapeutic applications.
Solar cells containing halide perovskite absorbers have shown large improvements in power conversion efficiency over the last eight years and now exceed 20%. This makes them competitive with many commercial technologies like polycrystalline silicon and CdTe.
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.
This patented technology is a scalable, reliable non-volatile memory device that uses graphene as a thermal barrier to improve energy efficiency and reliability of phase change material (PCM).
Researchers in Prof. Richard Zare's laboratory have developed a low-cost, thin, flexible, reusable polymer matrix to be utilized as an ionization vehicle for ambient mass spectrometry.
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.
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.
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.
Researchers working at Stanford University and the University of California, Berkeley have developed a novel method for establishing effective electrical contact inside electronic devices that contain carbon nanostructures.
Stanford researchers have developed a novel method for wafer-scale production of aligned and ultra-high density carbon nanotubes (CNTs) and nanotube grid.