Scientist in Radiation Chemistry

John Hill named director of Brookhaven National Laboratory. May 26, 2026 Brookhaven Science Associates (BSA) has named physicist John Hill as director of the U.S. Department of Energy's (DOE) Brookhaven National Laboratory, effective May 21. Hill is a longtime employee at Brookhaven Lab, who has served as interim lab director since September 2025. BSA's board of directors selected Hill after a competitive international search. Hill will also serve as BSA's president. BSA - a partnership between Stony Brook University and Battelle - manages and operates Brookhaven Lab on behalf of DOE's Office of Science. "We are delighted to have John Hill selected to lead Brookhaven National Laboratory at a pivotal moment for science and national impact," said BSA Board Chair and Battelle's Executive Vice President of National Laboratory Management and Operations Juan Alvarez. "He brings the leadership and vision needed to advance the Lab's future - delivering transformative discovery through the Electron-Ion Collider and accelerating impact across AI and embodied intelligence, distributed quantum systems, microelectronics and a future upgrade to the Lab's National Synchrotron Light Source II (NSLS-II). Under John's leadership, we are confident Brookhaven will continue to expand its science-ready infrastructure and strategic public-private partnerships in service to the nation." As director, Hill will work with stakeholders including DOE, policymakers, collaborating institutions and community members, as he leads Brookhaven toward strategic growth and scientific opportunity. "I am thrilled that, following a very competitive international search, John Hill has emerged as the very best leader for Brookhaven National Laboratory at this exciting juncture," said BSA Board Co-Chair and Stony Brook University President Andrea Goldsmith. "John's deep expertise, vision and leadership skills will be essential as the Lab looks to usher in a new era of fundamental physics discovery at the Electron-Ion Collider, while continuing its groundbreaking research in quantum systems, AI, microelectronics, materials science and high-resolution imaging. Stony Brook is proud to co-manage and partner with Brookhaven to advance the frontiers of discovery to benefit our country's innovation, economic vitality and national security. John's leadership will be essential to ensuring the Lab's success and impact long into the future." Hill will oversee a team of 3,000 scientists, engineers, technicians and professionals in many fields. They are supporting initiatives to explore building blocks of the universe, lead in discovery with light-enabled science and develop next-generation information science and capabilities, including AI and quantum. DOE's Genesis Mission underpins all these efforts. The Genesis Mission is a national initiative in artificial intelligence to build the world's most powerful scientific platform to accelerate discovery science, strengthen national security and drive energy innovation. Much of Hill's attention will be focused on delivering the Electron-Ion Collider (EIC) - a world-leading nuclear physics research facility being built at Brookhaven through a partnership among DOE, Brookhaven and DOE's Thomas Jefferson National Accelerator Facility in Virginia, with strong support from New York State. The EIC will enable researchers to unlock the secrets of the strongest force in nature - the "glue" that binds the building blocks of all visible matter in the universe. The EIC project will draw on expertise across DOE's National Labs and from universities and research institutions worldwide.

Brookhaven National Laboratory supports international DUNE collaboration. Brookhaven National Laboratory is playing a key role in an international effort to understand neutrinos, as evidenced by its support of the recent DUNE Software and Computing Week hosted at Argonne National Laboratory. More than 50 scientists from over 200 institutions worldwide convened to refine software and computing infrastructure for the Deep Underground Neutrino Experiment, or DUNE, which aims to investigate the imbalance between matter and antimatter in the universe. The experiment, slated to begin data collection in 2029, will utilize detectors at Fermilab in Illinois and a larger facility a mile underground in South Dakota to study these elusive particles. "The DUNE Core Software and Computing Consortium is tackling some of the most complex challenges in modern physics," said Michael Kirby of Brookhaven, leader of the DUNE Core Software and Computing Consortium. "By bringing together experts from around the world, we are not only advancing the tools and technologies needed for DUNE but also fostering collaboration that will drive innovation and discovery for years to come." DUNE experiment goals: matter-antimatter asymmetry & neutrino studies. The prevalence of matter over antimatter remains one of physics' most enduring mysteries, and the Deep Underground Neutrino Experiment (DUNE) is uniquely positioned to address it. These elusive particles, notoriously difficult to detect, hold clues to why matter dominates the cosmos, despite theoretical predictions of equal creation of both matter and antimatter during the Big Bang. DUNE aims to begin collecting data without a neutrino beam in 2029, and with a beam in 2031, processing data sets far exceeding those of current collider experiments. Fermilab's Kyle Knoepfel described this as handling "data-rich movie files that consist of gigabytes of data instead of megabyte-resolution photographs." This necessitates a new software framework, Phlex, designed to manage the scale and complexity of the incoming data. Argonne's expertise in high energy physics and computing is central to this effort; Peter van Gemmeren, a principal computational scientist at Argonne and event organizer, stated, "With deep expertise in high energy physics and some of the most powerful facilities and tools, Argonne is uniquely positioned to support DUNE's mission." Phlex software & FORM infrastructure for DUNE data handling. Existing data handling systems, designed for experiments generating megabyte-resolution data, are insufficient for DUNE's expected gigabyte-scale records. This is similar to processing data-rich movie files rather than still photographs. To address this, the collaboration has developed Phlex, a new software framework intended to optimize data processing for the experiment. Complementing Phlex is FORM, a data input/output and storage infrastructure currently under development at Argonne, designed to support the framework's processing demands. Scientists are also exploring the integration of compute accelerators, leveraging Argonne's expertise in this area to further enhance processing speeds. 2031 DUNE data collection & computing resource management. Andrew Olivier, Barnali Chowdhury, Peter van Gemmeren, Esteban "Steve" Rangel, and Xiaoyong Jin represented Argonne's contributions to both the physics and the substantial computing challenges inherent in the experiment. Kyle Knoepfel from Fermilab presented Phlex, a new software framework designed to handle the massive data records, gigabyte-sized files, that DUNE will generate, a significant increase over the megabyte-resolution data typical of collider experiments. Participants also explored strategies for efficient computing resource allocation, including quotas and prioritization, led by Steven Timm from Fermilab and Andrew McNab from the University of Manchester. The Aurora supercomputer at the Argonne Leadership Computing Facility will be instrumental in processing the incoming data, offering the necessary scale for this ambitious undertaking. ProtoDUNE validation at CERN & Aurora supercomputer integration. The success of the Deep Underground Neutrino Experiment (DUNE) increasingly relies on meticulous validation of its core technologies, as evidenced by recent activity at CERN and Argonne National Laboratory. Scientists are leveraging the 770-ton ProtoDUNE prototype, operated at the European Center for Nuclear Research, to refine detector responses before the full-scale experiment begins construction in South Dakota. This prototype is not simply a scaled-down version; it's a crucial testing ground for understanding how the detector will interact with particles like pions and protons, essential for calibrating its sensitivity to elusive neutrinos. Researchers are specifically studying particle behavior in liquid argon, a key component of the DUNE detectors, to ensure accurate data capture. Complementing the ProtoDUNE validation is the integration of the Aurora supercomputer, housed at Argonne's Leadership Computing Facility, into the DUNE data processing pipeline. This powerful machine will be instrumental in handling the massive data streams anticipated from the experiment, which will deal with gigabyte-sized data records, a significant leap beyond the megabyte-resolution data typical of current collider experiments. The collaborative effort, bringing together over 50 scientists from more than 200 institutions, underscores the complexity of modern physics research.