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From New Scientist, Jan. 25, 2021: The Big Bang left us the universe — and a major set of mysteries around antimatter, dark matter, dark energy, and cosmic inflation. While the Large Hadron Collider looks at what the laws of physics were like a trillionth of a second after the Big Bang, Dan Hooper, head of theoretical astrophysics at Fermilab, thinks the answers to these puzzles may depend on better understanding that first fraction of a second — even closer to the universe’s beginning.

From Big Think, Jan. 10, 2021: The quantum breakthrough Fermilab and its partners made in teleporting qubits over a fiber-optic network more than 27 miles highlights how close — and how far — modern science is from sci fi.

From University of Glasgow, Jan. 13, 2021: Fermilab will take part in an international collaboration, led by Cardiff University, on quantum-enhanced interferometry for new physics. The project’s four table-top experiments may help explore new parameter spaces of photon-dark matter interaction, and seek answers to the long-standing question at the heart of modern science: How can gravity be united with the other fundamental forces?

From CERN, Jan. 26, 2021: This week marks the 50th anniversary of the first proton collisions in CERN’s Intersecting Storage Rings, the first hadron collider ever built. To celebrate, see hadron colliders of the last half-century — including the Tevatron and the Large Hadron Collider — through a historical lens, with an eye toward the quest for high luminosity and new energy frontiers.

From Mashable, Jan. 19, 2021: In a huge breakthrough, a team of researchers from Caltech, Fermilab, AT&T, Harvard, NASA and the University of Calgary teleported quantum information over a fiber-optic network of 44 kilometers. This video shares how high-fidelity quantum teleportation lays the groundwork for a functional quantum internet, making the internet faster and more secure, and its technological and societal implications.

From Science, Jan. 27, 2021: Physicists await the Muon g-2 experiment’s results, which could come as early as this spring, to see whether they confirm that muons are slightly more magnetic than theory predicts. If so, it will signal new physics. Fermilab scientists discuss the experiment, as well as the secrecy required to blind themselves from affecting the results.

From Oak Ridge National Laboratory, Jan. 26, 2021: The COHERENT particle physics experiment at Oak Ridge National Laboratory has firmly established the existence of a new kind of neutrino interaction. To observe this interaction, scientists used CENNS-10, a liquid argon detector built at and on loan from Fermilab.

Scientists wrote over 1500 letters sharing what they hope the next decade of particle physics will bring. One motif: studying long-lived particles in a variety of ways — including an idea using a detector atop the CMS experiment at the Large Hadron Collider at CERN.

Organizers of the planning exercise that helps shape the future of U.S. particle physics have moved its final workshop back by one year.

From Forbes, Jan. 22, 2021: Fermilab scientist Don Lincoln describes recent findings of scientists studying an unexplained excess of hard X-rays emanating from neutron stars. The explanation for the excess could lie in a hypothesized dark matter candidate called the axion.