Stanford researchers have developed a novel technique to control proton beams for radiation therapy to deliver a very high, full dose across a tumor in less than one second.
Stanford researchers have developed a technique to interpret contact events between a human and a device equipped with a force sensor. It can detect and classify distinct touch interactions such as tap, touch, grab, and slip.
Researchers at Stanford, the University of Massachusetts and the Chan Zuckerberg Biohub have developed methods to increase or decrease RNA interference target cleavage rates.
Researchers at Stanford have developed a technique that leverages multifocal widefield optics to enable high-speed, synchronous, genetically-specified recording of neural activity across the entirety of mouse dorsal cortex at near-cellular resolution.
The Heilshorn group has developed a platform for 3D bioprinting which stiffens the structure post-printing using chemistry that is completely bioorthogonal.
Ear infections are a serious condition, especially in children, and represent a $4B market. Otitis media (OM) is when the middle ear becomes inflamed and affects 90% of children worldwide.
Stanford researchers have shown how to use fluorescent and phosphorescent materials to provide plants with photons in the photosynthetically active radiation (PAR) range for increased crop yields and CO2 fixation.
This single-stage resonant inverter architecture achieves constant power and efficiency over a large bandwidth, solving one of the largest problems with state-of-the-art resonant inverter power amplifier architectures.
Stanford researchers have developed a scanning mirror and method for Rhodonea (Rose) scanning patterns, which are superior to Lissajous patterns for almost all imaging and ranging applications.
Researchers at Stanford and the Chan Zuckerberg Biohub have discovered a Cas9 protein variant from Ignavibacterium that is thermostable at elevated temperatures.
Researchers in the Fuller group have designed a platform and method for measuring the thickness profiles of dynamic thin liquid films at high frequencies. The key steps in the new method called as dynamic hyperspectral interferometry are as follows.
This methodology computes the marginal energy utilization for supplying individual water users based on the existing topology of the water distribution network (WDN), pipe sizes and baseline flows.