Researchers at Stanford have developed a technique that can rapidly and sequentially separate multiple sets of III-V solar cell thin films grown as a stack on one III-V wafer.
Researchers at Stanford University have developed a multilayered immiscible polymer system capable of autonomously realigning its layers to enhance the healing process after damage.
Researchers in the Stanford University Power Electronics Research Lab developed an effective ring electrode that removes spurious modes in piezoelectric resonators.
Researchers at Stanford have developed practical applications that use germline information (e.g., germline epitope burden) for diagnosis, monitoring and treatment of cancer.
Obtaining pure cell types from mixed cell populations continues to be a significant obstacle in the fields of stem cell biology and regenerative medicine.
Stanford researchers have developed a novel technique, enabling specific labeling and purification of regenerating and non-regenerating retinal ganglion cells from the same animals with the same genetic background/modification/injuries.
Stanford researchers have developed a method for targeted focused ultrasound application to peripheral nerves to suppress acute pain. This invention can non-invasively concentrate ultrasound waves onto peripheral nerves without impacting surrounding tissue.
Cell culture is a central technique used for a plethora of research applications including in the modeling of complex diseases, creating transgenic animals, gene therapy, cell therapy, regenerating lost tissue, and organ biogenesis.
Introducing a groundbreaking advancement in lithium metal anode technology, Stanford researchers have developed an innovation that leverages a flower-like nanostructured hard carbon host (CF) to unlock the full potential of lithium metal.
We present a revolutionary advancement in ferroelectric materials that is set to redefine the landscape of embedded memories and semiconductor technologies.
For the first time, researchers in Prof. Yan Xia's laboratory have synthesized a new ladder type microporous polymide (PIM) by linking an arene-norbornene building block to a Tröger's base which can be used for high-performance gas separation membranes.