Stanford researchers at the Bao Lab have designed hydrophobic perfluoropolyether (PFPE) polymers that can be applied in underwater conditions, at room temperature, without any solvent or curing steps, and can be reused and recycled.
Background: Researchers at Stanford have discovered a method to create lattice microneedle structures using high resolution continuous liquid interface printing (CLIP) technology.
Stanford scientists have invented a new suite of adaptable hydrogel biomaterials that are optically transparent and injectable for cell encapsulation, tissue engineering, and drug delivery.
Stanford researchers have developed a novel approach to make a stable and active platinum-alumina catalyst that maintains high activity under harsh conditions.
Researchers led by Stanford University's Stephen Tsai have developed new design and manufacturing approaches for glueless/boltless joining of metallic grid and carbon composite skins.
Researchers at Stanford have developed an additive manufacturing approach, called VIA, that enables rapid printing of solid 3D geometries with high viscosity composite resins and multimaterials.
As part of a comprehensive optofluidic platform, researchers at Stanford have developed an integrated dynamic flat-optics system enabling microlens-free metasurface planar light-field displays.
As part of a comprehensive optofluidic platform, researchers at Stanford have developed an integrated dynamic flat-optics system that supports unprecedented compact configurations.
As part of a comprehensive optofluidic platform, researchers at Stanford have developed a new type of reflective display technology for achieving transparent displays, which allow users to receive visual information from the external world through the display at the same time.
Stanford researchers have developed a method to form orthogonal overlapping joints at the 4 corners of the starting square. In order to have constant height of each beam, inserts in the beams between the joints will be required.
Stanford inventors have developed a molecular design concept that allows for the development of stretchable electronics with desirable elasticity, solvent resistance, and photopatternability using covalently-embedded in-situ rubber matrix formation (iRUM).
Researchers at Stanford have reported the first high energy density shape memory polymer based on the formation of strain-induced supramolecular nanostructures, which immobilize stretched chains to store entropic energy.
Researchers at Stanford have developed a new synthetic strategy for self-assembling layered heterostructures into large single crystals and films useful in microelectronics.