Lockyer was the director of
Fermilab from September 3, 2013, to April 18, 2022. During his directorship, he oversaw the laboratory's
particle accelerators and experimental facilities. Approximately 4,000 scientists from over 50 countries use these facilities annually for research in particle physics. Fermilab has the most powerful neutrino beams in the world to explore the nature of
neutrinos and is proposing a project to host the first large-scale, international basic science project on U.S. soil. The
Deep Underground Neutrino Experiment, or DUNE, is a proposed world-leading neutrino experiment, which includes more than 1,000 scientists from more than 30 countries and 170 institutions, and involves construction at both Fermilab and the
Sanford Underground Research Facility (Sanford Lab) in
Lead, South Dakota.
CERN, representing European institutions, is a major partner in the experiment. CERN has developed a neutrino platform to advance technology for neutrino experiments, with a significant part of this effort focused on DUNE. Fermilab will improve its Short-Baseline Neutrino Program with three detectors: MicroBoone, which completed in 2021;
ICARUS, which arrived from CERN at the end of 2016 and started taking data in 2017; and the smaller
Short-Baseline Neutrino Experiment (SBND), which was completed in 2024 and has started taking data. All three detectors will work in unison to search for sterile neutrinos and to advance liquid
argon Time Project Chamber technology which has been adopted by DUNE. ICARUS, was refurbished at CERN after four years at the
Italian Institute for Nuclear Physics (INFN) Gran Sasso National Laboratory and was transported to Fermilab by a group of scientists led by
Carlo Rubbia,
Nobel Laureate in Physics. The facility required for the Deep Underground Neutrino Experiment, the Long-Baseline Neutrino Facility (LBNF) will comprise the world's highest-intensity neutrino beam at Fermilab and the infrastructure necessary to support detectors installed deep underground at Sanford Lab. Using accelerators at Fermilab, an intense beam of neutrinos would be produced and travel 1300
kilometers through the earth to an underground
neutrino detector at Sanford Lab. LBNF would be the most powerful tool in the world to study neutrinos and has been identified by the U.S. particle physics community as the highest priority domestic construction project. Excavation of an underground facility, including labs and neutrino detector in the
Black Hills of South Dakota began in 2017 and was completed in 2024, while construction at Fermilab is scheduled to be completed around 2030. In order to supply the required intense bean of neutrinos to the detectors at the new and far sites Fermilab has proposed the Proton Improvement Plan II (PIP-II). The project, which will improve Fermilab's particle accelerator complex with a major overhaul and power boost, will involve retiring the cooper linac and building a new
superconducting radio-frequency linac. The proposed upgrade to the linear accelerator involves an international collaboration with India, whose
Department of Atomic Energy will contribute hardware in exchange for experience in building high-intensity superconducting radio-frequency proton linacs. The largest of Fermilab's new projects is the recently completed
NOvA Neutrino Experiment at Fermilab and in Ash River,
Minnesota. NOvA will investigate
neutrino oscillations, a phenomenon that could hold important clues to the evolution of the early universe. The first NOvA results, which were released in August 2015, verify the experiment's massive
particle detector is detecting neutrinos fired from 800 kilometers away and making great progress towards its goal of a major leap in our understanding of neutrinos. Fermilab is a U.S. hub for research into the
Higgs boson and other high energy phenomena and is making major upgrades of the
Compact Muon Solenoid (CMS) detector—one of two large detectors located at the
Large Hadron Collider (LHC) at
CERN in Europe. Fermilab is involved in cosmic research through the
Dark Energy Survey, which includes over 120 scientists from 23 institutions in the United States, Spain, United Kingdom, Brazil, and Germany. The project relies on a Dark Energy camera, a high-resolution camera built at Fermilab for a telescope in
Chile that will look for evidence of
dark energy that is responsible for the expansion of the universe. In March 2015, a team of researchers using data collected during the first year of the survey discovered a rare
dwarf satellite galaxy orbiting the
Milky Way. In the fields of
astrophysics and particle physics, the nature of
Dark Matter is important, and Fermilab is engaged in several generation one dark matter searches, including DAMIC, SuperCDMS, PICO, and Darkside50. A new state-of-the-art facility being built at Fermilab, the Illinois Accelerator Research Center, or IARC, will provide resources for accelerator industrialization. The facility will allow not only scientists and engineers from Fermilab, but those from
Argonne National Laboratory and Illinois universities to collaborate with partners from industry to develop breakthroughs in accelerator technology and new applications in energy and environment, medicine, industry,
national security and
discovery science. ==Awards and honors==