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Citizen scientists dive into particle physics and astrophysics research.

Two new research projects support the Stanford Institute for Materials and Energy Sciences in the study of exotic new materials that could enable future innovative electronic and photonic applications.

When SuperCDMS SNOLAB turns on in 2018 at the underground science laboratory in Canada, it will be able to see dark matter particles 10 times lighter than previous searches.

For the first time, researchers have produced a 3-D image revealing some of the inner structure of an intact, infectious virus.

$Image - This rendering shows a 3-D reconstruction of a Mimivirus, based on an analysis of a collection of X-ray diffraction patterns obtained in an experiment at SLAC's Linac Coherent Light Source X-ray laser. (Uppsala University)$

The LSST system will alert scientists to changes in space in near-real time.

Presented by Siegfried Glenzer. Normally we think of hydrogen as a gas. But elsewhere in the universe, hydrogen under extreme pressure can exist in more exotic states. In the center of Jupiter, hydrogen becomes liquid or even solid. In the...

stillframe public lecture jupiter in a bottle

Two recent meetings at SLAC brought together experts working on computer hardware and software for LSST – a future telescope that will provide unprecedented views of the sky and may solve some of the biggest mysteries of the universe.

Reports by groups including Dark Energy Survey and Large Area Telescope scientists may provide new clues about the properties of mysterious dark matter.

Developed at SLAC’s LCLS, it could also yield new information from hard-to-study samples in materials science, chemistry and other fields.

SLAC study of tiny nanocrystals provides new insight on the design and function of nanomaterials

Image - In this illustration, intense X-rays produced at SLAC's Linac Coherent Light Source strike nanowires to study an ultrafast "breathing" response in the crystals induced quadrillionths of a second earlier by pulses of optical laser light.

A SLAC experiment has provided the first detailed look at the creation of an exotic superhot, compressed concoction known as "warm dense matter" – the stuff believed to be at the core of giant gas planets like Jupiter.

IMAGE - A study at SLAC's Linac Coherent Light Source X-ray laser provides the most detailed measurements yet of a material's temperature and compression as it transitions into a mysterious state known as "warm dense matter."

Using a newly identified set of supernovae, researchers have found a way to measure distances in space twice as precisely as before.

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Physics for the people

New Programs Enhance SIMES Role in Studying Exotic New Materials

SLAC Assumes a Leading Role for SuperCDMS SNOLAB

Giant Virus Revealed in 3-D Using X-ray Laser

A Telescope that Tells You When to Look Up

Jupiter in a Bottle: Extreme States of Matter in the Laboratory

Scientists Gather at SLAC to Prepare for Large Synoptic Survey Telescope

Possible Rare Dwarf Galaxies Found Orbiting Milky Way

New 2-Color X-ray Laser Technique Could Reveal Atomic Detail of Medically Important Proteins

Scientists Watch Quantum Dots 'Breathe' in Response to Stress

Experiment Provides the Best Look Yet at 'Warm Dense Matter' at Cores of Giant Planets

Better ‘Cosmic Candles’ to Illuminate Dark Energy