Stanford researchers have developed a label-free platform that combines surface-enhanced Raman spectroscopy (SERS) with machine learning to enable rapid, non-destructive profiling of cell identity and functional state at single-cell resolution.
Stanford researchers have developed an innovative metasurface-enabled, CMOS-compatible platform for high-density, on-chip oligonucleotide synthesis that enables precise, site-selective DNA production without mechanical scanning or complex photolithographic alignment.
Stanford scientists have developed a platform that combines Raman spectroscopy, nanomaterials, and machine learning to rapidly identify bacteria in wastewater without chemical labels.
Industry, government, and private investment in CO2 capture is growing to address climate change. Without carbon utilization, however, high costs impede large scale capture efforts.
Researchers in the Dionne lab (D-Lab) at Stanford University have designed an on-chip, optical spin processor for classical and quantum information systems.
Researchers at Stanford have developed force sensors that can operate on very small physical scales without the need for an external connection or power supply.
Stanford researchers within the Dionne Lab have developed a method to use copper titanium dioxide core-shell nanoparticles for the light driven production of green fuels or removal of contaminants in water.
Stanford scientists have invented a new PET-nanophotonic metamaterial scintillator that consists of tunable scintillating alkaline-earth rare-earth fluoride nanoparticles (MLnF) for low-dose, high-resolution PET imaging.
Stanford researchers have developed an integrated printer/scanner platform to screen biofluids for bacterial pathogens and other cells of interest at the single cell level.
Stanford researchers have designed a light-driven bimetallic alloyed plasmonic photocatalyst that can both effectively and selectively catalyze heterogenous hydrogenation.
Inventors at Stanford University have developed a colorimetric device to visualize microstructural features in tissue biopsies towards clinical diagnostics.
Determining a patient's drug susceptibility is currently a lengthy process requiring hundred to millions of cells. Currently, these cells are labelled, frozen or otherwise manipulated in ways that prevent sequential testing against multiple drugs on the same few cells.
Researchers in the Dionne group at Stanford have designed a nanoscale laser capable of self-isolated Raman Lasing, where lasing and isolation occurs within the same pumping mechanism.
The Dionne lab has developed ultrathin and compact devices for electrically driven beamsteering that fit on a semiconductor chip. These devices rely on resonant dielectric nanostructured surfaces known as "high quality factor" (high-Q) metasurfaces.