Professor Marc Levoy and collaborators have enhanced the performance of the light field microscope (LFM) by solving the problem of non-uniform spatial resolution across the working range, especially the low spatial resolution at the native objective plane (in the middle of the
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.
Researchers in the Molecular Imaging Instrumentation Laboratory at Stanford University have developed a system for digitizing high energy photon readings for high energy photon-radionuclide detection systems, including PET (positron emission tomography).
Researchers in Prof. Karl Deisseroth's laboratory have developed an optical imaging and optogenetics two photon laser system that uses a single beam to illuminate many sites in three-dimensions.
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. Lambertus Hesselink's laboratory have developed a compact, sensitive X-ray differential phase contrast (DPC) imaging system that improves field of view, increases fringe visibility and shortens imaging times.
Researchers in Dr. Hanlee Ji's lab have developed a targeted sequencing method known as short tandem repeat (STR) sequencing (STR-Seq) which improves target selection specificity to generate only the STR spanning reads.
Stanford Prof. Juan Santiago and a team of engineers have developed a method of speeding up chemical reactions between a probe on a surface and a molecule in solution.
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.
Stanford researchers have developed a method that can tune the ratio between reversible (RE) and irreversible (IRE) electroporation through waveform adjustments.
Stanford researchers have developed a depletion-mode MOSFET-based phototransistor with sub-wavelength dimensions, extremely high responsivity and a low dark current.
Researchers at Stanford have developed a ferumoxytol-based dual-modality imaging probe that allows for long-term stem cell tracking through MRI and early diagnosis of cell apoptosis through simultaneous fluorescence imaging.
Researchers at Stanford University have developed a system for improved scatter correction in CT scans by simultaneously collecting image projection data and scatter data in a single scan.
This patented technology is an Integrated Capacitance Bridge (ICB) that can perform ultra-high-resolution (aF), wide-temperature-range measurements of capacitance in nano-structures.