Stanford Institute for Materials & Energy Sciences (SIMES)
Precisely flawed nanodiamonds could produce next-generation tools for imaging and communications.
Many technologies rely upon nanomaterials that can absorb or release atoms quickly and repeatedly. New work provides a first look inside these phase-changing nanoparticles.
Laser light exposes the properties of materials used in batteries and electronics.
Adding pressure could improve the performance of solar cells made of perovskites, a promising photovoltaic material.
Wrapping silicon anode particles in custom-fit graphene cages could solve two major obstacles to using silicon in high-capacity lithium ion batteries.
SLAC and Stanford scientists discovered that a single layer of tiny diamonds increases an electron gun’s emission 13,000 fold. Potential applications include electron microscopes and semiconductor manufacturing.
The Precourt Institute for Energy and the TomKat Center for Sustainable Energy at Stanford have awarded 12 faculty seed grants totaling $2.1 million for groundbreaking research on clean energy, including three grants to SLAC-Stanford collaborations.
SIMES scientists have discovered how to make the electrical wiring on top of solar cells nearly invisible to incoming light. The new design, which uses silicon nanopillars to hide the wires, could dramatically boost solar-cell efficiency.
SLAC, Stanford scientists discover that bombarding and stretching a catalyst opens holes on its surface and makes it much more reactive. Potential applications include making hydrogen fuel.
A team led by SLAC scientists combined powerful magnetic pulses with some of the brightest X-rays on the planet to discover a surprising 3-D effect that appears linked to a mysterious phenomenon known as high-temperature superconductivity.