Topic: Particle physics | SLAC National Accelerator Laboratory

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The upgraded experiment aims to discover if neutrinos are their own antiparticles.

News Feature

Scientists want to connect the fundamental forces of nature in one Grand Unified Theory.

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One: The Deep Underground Neutrino Experiment will look for more than just neutrinos.

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CERN physicist Edda Gschwendtner explains why we need big machines to study tiny particles.

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A bump in the LHC data has physicists electrified…but what does it mean?

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On the road to the world’s largest neutrino detector, take the “DUNE Buggy.”

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The latest measurements from the Daya Bay neutrino experiment in China don’t align with predictions from nuclear theory.

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Contributions to LIGO have come from many Stanford teams, including SLAC, Applied Physics, Mechanical Engineering, Aeronautics and Astronautics and the School of Earth, Energy...

News Feature

Dark matter hunters around the world pursue three approaches to look for fingerprints of ghostly WIMPs: on the Earth’s surface, underground and in space.

Researchers around the world pursue three approaches to look for fingerprints of dark matter's ghostly components.

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Radiation is everywhere. The question is: How much?

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The emptiest parts of the universe aren’t so empty after all.

News Feature

The mysterious particle could hold the key to why matter won out over antimatter in the early universe.

The upgraded experiment aims to discover if neutrinos are their own antiparticles.

Scientists want to connect the fundamental forces of nature in one Grand Unified Theory.

One: The Deep Underground Neutrino Experiment will look for more than just neutrinos.

CERN physicist Edda Gschwendtner explains why we need big machines to study tiny particles.

A bump in the LHC data has physicists electrified…but what does it mean?

On the road to the world’s largest neutrino detector, take the “DUNE Buggy.”

The latest measurements from the Daya Bay neutrino experiment in China don’t align with predictions from nuclear theory.

Contributions to LIGO have come from many Stanford teams, including SLAC, Applied Physics, Mechanical Engineering, Aeronautics and Astronautics and the School of Earth, Energy and Environmental Sciences.

Dark matter hunters around the world pursue three approaches to look for fingerprints of ghostly WIMPs: on the Earth’s surface, underground and in space.

Radiation is everywhere. The question is: How much?

The emptiest parts of the universe aren’t so empty after all.

The mysterious particle could hold the key to why matter won out over antimatter in the early universe.

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Particle physics

EXO-200 Resumes Its Underground Quest

A GUT Feeling about Physics

Five Fascinating Facts About DUNE

Why Are Particle Accelerators so Large?

Bump Watch 2016

Test of DUNE Tech Begins

Daya Bay Discovers a Mismatch

Stanford Scientists Celebrate Technological Advances that Finally Made Gravitational Wave Detection Possible

Three Ways to Bust Ghostly Dark Matter

This Radioactive Life

Our Imperfect Vacuum

Is the Neutrino its Own Antiparticle?

EXO-200 Resumes Its Underground Quest

A GUT Feeling about Physics

Five Fascinating Facts About DUNE

Why Are Particle Accelerators so Large?

Bump Watch 2016

Test of DUNE Tech Begins

Daya Bay Discovers a Mismatch

Stanford Scientists Celebrate Technological Advances that Finally Made Gravitational Wave Detection Possible

Three Ways to Bust Ghostly Dark Matter

This Radioactive Life

Our Imperfect Vacuum

Is the Neutrino its Own Antiparticle?