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Researchers use advanced scientific tools at SLAC to study materials that could be used to make better solar cells.

Perovskites’ response to light.

News Feature

Tanner works on self-assembling nanocrystals, which could be the basis for less expensive, easier to build displays and solar cells.

Christian Tanner
Press Release

With up to a million X-ray flashes per second, 8,000 times more than its predecessor, it transforms the ability of scientists to explore atomic-scale...

LCLS-II first light
News Feature

A promising lead halide perovskite is great at converting sunlight to electricity, but it breaks down at room temperature. Now scientists have discovered how...

Lead halide material being squeezed in a diamond anvil cell.
News Feature

These fleeting disruptions, seen for the first time in lead hybrid perovskites, may help explain why these materials are exceptionally good at turning sunlight...

An illustration shows polarons as bubbles of distortion in a perovskite lattice
News Feature

A new study is a step forward in understanding why perovskite materials work so well in energy devices and potentially leads the way toward...

Scattered neutrons off perovskite material.
News Feature

Four scientists discuss X-ray experiments at SLAC’s synchrotron that reveal new insights into how a promising solar cell material forms.

Photo: Aryeh Gold-Parker, Chris Tassone, Kevin Stone and Mike Toney
News Feature

Research conducted at the atomic scale could help explain how electric currents move efficiently through hybrid perovskites, promising materials for solar cells.

Illustration of what happens when simulated sunlight hits perovskite
Press Release

SLAC’s ultrafast “electron camera” reveals unusual atomic motions that could be crucial for the efficiency of next-generation perovskite solar cells.

UED Perovskites
Press Release

Scientists have used X-rays to observe exactly how silver electrical contacts form during manufacturing of solar modules.

News Feature

A SLAC/Stanford manufacturing technique could help make inexpensive polymer-based solar cells an attractive alternative to silicon-crystal wafers.