Measurement of dissolved CO2 has critical applications in healthcare monitoring and consumer goods quality control, yet is difficult to measure directly.
Stanford researchers have designed and tested an electrochemical gas sensor which can detect volatile organic species in the gas phase and differentiate multiple species with a single chip.
Stanford researchers have developed a streamlined method for simultaneously estimating a broad range of hydrocarbon fuel physical and chemical properties for a wide range of fuels.
Researchers in Prof. Ronald K. Hanson's laboratory have developed a non-intrusive gas sensor designed for high performance temperature and species concentration measurements in high pressure, particulate laden environments.
Stanford researchers have invented a fully water-soluble, orange hydrazine sensor that can robustly quantify the toxin hydrazine in liquids such as drinking water, waste water (treated and untreated), and bodily fluids.
Stanford researchers have discovered a novel method of doping nanowires (NW) and thin films (TF) that greatly improves surface area and performance. The sol-flame method is a fast, simple and low cost way to introduce dopants into NW and TF for a wide variety of applications.
Using bamboo inspired carbon nanofibers, Stanford researchers at the Yi Cui Lab have created a freestanding, flexible and elastic electrode for energy storage devices.
Engineers in Prof. Butrus Khuri-Yakub's laboratory have developed a patented, simple, cost efficient, CMUT (capacitive micromachined ultrasonic transducers) fabrication process with incomparable precision and performance.