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One of the most urgent challenges of our time is discovering how to generate the energy and products we need sustainably – in a way that doesn’t compromise the well-being of future generations by depleting limited resources or accelerating climate...

Illustration of nanocrystals forming into superlattices at SLAC's SSRL

A cellphone-sized device automatically adjusts a home's power use up or down to save the consumer money and increase the resiliency of the electric grid.

Aerial image of workers installing solar panels on a home.

Islands of inactive lithium creep like worms to reconnect with their electrodes, restoring a battery’s capacity and lifespan.

Conceptual illustration shows an EKG-like pulse of energy flatlining as it enters a battery, then coming back to life as it exits

This illustration depicts a herringbone-like pattern in the atomic lattice of a quantum material created by researchers at SLAC and Stanford.

An illustration of a dramatic, herringbone-like pattern in the atomic lattice of a newly created quantum material. Against a black background, calcium atoms are seen as light blue spheres, cobalt atoms in dark blue and oxygen atoms in red. Lines connecting the oxygen atoms represent the atomic lattice.

The new SLAC-Stanford Battery Center creates a generational opportunity enabling translational research in electrochemical science and technology bridging across fundamental science to deployment.

Presented by Elizabeth Ryland

public lecture poster illustration of electrons going over a bridge

Presented by Ashley James

Researchers have discovered that crystals can twist when they are sandwiched between two substrates – a critical step toward exploring new material properties for electronics and other applications.

$This image shows a diffraction pattern of gold nanodics between substrates.$

The finding could help future efforts to design superconductors that work at higher temperatures.

This is a graphic drawing that represents how electrons lock together in a superconducting material.

Gustavo Cezar wears two colorful hats as an engineer with SLAC’s GISMo lab.

SLAC engineer Gustavo Cezar stands at a dairy farm in Central California.

The SLAC-Stanford team pulled hydrogen directly from ocean waters. Their work could help efforts to generate low-carbon fuel for electric grids, cars, boats and other infrastructure.

This photograph shows ocean water funneling over rocks on about half of the photograph and deeper ocean water on the other part of the photograph. It is a view of the ocean from above, in the sky.

By revealing the chemistry of plant secretions, or exudates, these studies build a basis for better understanding and conserving art and tools made with plant materials.

Who we are

SLAC science explained

NSF-DOE Vera C. Rubin Observatory LSST

Careers at SLAC

Revealing the Secrets of Transistors using Supercomputers

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Energy sciences

GISMo lab's innovative plan to make electricity cheaper, greener and more reliable

Revitalizing batteries by bringing ‘dead’ lithium back to life

Distorted quantum material

SLAC-Stanford Battery Center

Searching for Trolls under the Electron Bridge

Mercury Rising: The Toxicology of a Global Pollutant

Researchers add a ‘twist’ to classical material design

Researchers observe “locked” electron pairs in a superconductor cuprate

A day in the life of an electricity and cool cow engineer

Researchers devise new system for turning seawater into hydrogen fuel

Researchers aim X-rays at century-old plant secretions for insight into Aboriginal Australian cultural heritage