Technology innovation

As QuantISED enters its next phase in its effort to develop quantum technologies capable of exploring some of the universe’s biggest unanswered questions, scientists reflect on what the first round made possible and what comes next.

Researchers reengineered an ePix10k detector for use in ultrafast electron diffraction, empowering studies of chemical processes that were previously out of reach. 

Argonne, SLAC researchers designed a chip that compresses and processes detector data instantly, letting scientists analyze results and steer experiments as they happen.

SLAC experts discuss how microelectronics impacts our lives and where the future lies in this Q&A.

NLCTA staff helped undergraduates from Harvey Mudd College use the facility’s electron beam to test a detector they designed. 

Quantum networking is the framework that uses the strange properties of quantum mechanics to transmit quantum information, encoded in qubits, from one quantum device to another.

Shweta Saraf and her team work to ensure the LCLS beamline runs without interruption. 

He met with SLAC staff and toured the lab’s cutting-edge facilities, diving into world-leading research in X-ray and ultrafast science, artificial intelligence, astrophysics and more.

The microelectronics that power daily life and speed discoveries in science and technology are the focus of a bold new vision to make them more energy efficient and able to operate in extreme environments.

AI is playing a key role in helping SLAC researchers find new galaxies and tiny neutrinos, and discover new drugs.

Researchers across the lab are developing AI tools to harness data and particle beams in real time and make molecular movies, speeding up the discovery process in the era of big data.

Digital design engineer Abhilasha Dave’s passion for connecting machine learning and hardware is helping SLAC solve big data challenges.