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Tag: Brookhaven National Laboratory

  • Long Island Association adds seven new board members | Long Island Business News

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    THE BLUEPRINT:

    • LIA elects seven new board members from major Long Island institutions.

    • New members represent , research, defense and accounting.

    • Leaders elected to help bolster economic growth and competitiveness.

    • LIA says new voices will support innovation and small-business success.

    The recently elected seven new members to its . The new board members serve in higher education, accounting services, scientific research and defense manufacturing, bringing expertise in their fields.

    These members, all from organizations that were already represented on the board, were elected to support the LIA’s mission to advance regional economic and business development.

    “We are excited to welcome these accomplished and knowledgeable leaders to the LIA Board of Directors,” Lawrence Waldman, chairman of the LIA, said in a news release about the board members.

    “Their leadership and industry expertise will bring fresh perspectives and help guide our mission to strengthen Long Island’s competitiveness and economic resilience,” he added.

    The board members include Dr. Jerry Balentine, president of New York Institute of Technology, with a campus in Old Westbury; Damon Brady, product line director of , with locations in Greenlawn; Andrea Goldsmith, president of ; John Hill, interim director of ; Craig Savell, managing principal of the New York metro region of , which includes offices in Uniondale and Melville; Christopher Storm, interim president of president of , whose main campus is in Garden City; and Jerry Ward, office managing partner of , with a location in Jericho.

    The LIA’s Board of Directors comprises “a cross-section of our region’s leading industries and institutions, and these new voices will contribute to the LIA’s efforts to ensure a thriving economy,” Matt Cohen, president and chief executive of the LIA, said in the news release.

    “The work of the new board members at their respective companies and organizations is critical to both the growth of our innovation economy and success of small businesses, and we look forward to having their input as we advocate for a prosperous Long Island,” he said.


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    Adina Genn

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  • ‘The Human Element’

    ‘The Human Element’

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    Newswise — Sometimes, the best way to see what you’re made of is facing a challenge. Andrew Broadbent, an accomplished project manager at the at the National Synchrotron Light Source II (NSLS-II), a U.S. Department of Energy (DOE) Office of Science User Facility located at DOE’s Brookhaven National Laboratory, took on such a challenge earlier this year though DOE’s Project Leadership Institute (PLI) and emerged from the yearlong endeavor with his team victorious.

    Cultivating Leadership

    Every year, PLI selects around 25 experienced project leaders endorsed by DOE national laboratories, program offices, and site offices to participate in their intensive, yearlong leadership development program. This program is designed to cultivate the necessary skills to effectively take on and execute high-risk projects. The cohort is split into five teams that work together over the course of the year to conduct a case study analysis of a recent DOE project. Throughout the program, the cohort travels to different national labs across the country to attend events and participates in self-paced learning during the summer. These modules cover important concepts, like leading innovative teams, that often highlight real-life success stories.

    “Everyone on the team has extensive project management experience,” said Broadbent, “so we were all, largely, in the same boat here, and we learned a lot from each other along the way. Each event provided something useful to take away, making it a really valuable program for anyone in the DOE involved with project management.”

    As the program concludes, each team creates a final report and presentation capturing the successes and failures of the project, analyzes the lessons to be learned, and submits them for judging. The judges confer on the analysis they found to be the most impactful and present the winning team with a shared plaque that travels to each teammate’s home institution. Broadbent’s contributions ensured that the plaque would make its final stop at Brookhaven later next year.

    Transforming cUlture Through inclusiOn (TUTO)

    Broadbent’s team, dubbed TUTO, consisted of members from different national laboratories—Jessica Bentley (Sandia National Laboratory), Lisa Ehlers (Lawrence Berkeley National Laboratory), Vincente Guiseppe (Oak Ridge National Laboratory), and Hiro Tanaka (SLAC National Accelerator Laboratory). Each member strengthened the team with their diverse backgrounds, talents, and project experiences. Broadbent drew plenty of inspiration from the projects he has helped manage. For 16 years at NSLS-II, he has been instrumental in the design, installation, and commissioning of several beamlines that are currently serving users who are performing cutting-edge research, as well as future beamlines that will offer the facility new capabilities.

    For their project, the team explored the execution of DOE’s Facility for Rare Isotope Beams (FRIB) project at Michigan State University (MSU). FRIB’s mission is to produce and research rare isotopes for advancing knowledge in nuclear physics, material science, medicine, defense, and industry. The project was completed in June 2022.

    “FRIB is a unique project not only for its one-of-a-kind mission and technological success but also for its leadership. They successfully navigated an unusual funding and regulatory framework to project completion within budget and five months ahead of schedule,” remarked Broadbent.

    While they explored the project through PLI’s core concepts, they also sought out the values employed by the FRIB team that made their project so successful. In their analysis, they narrowed it down to four main concepts: curation, fluidity, character, and engagement.

    “Curation” was reflected in several aspects of project management, from making a team of diverse people with diverse talents to only selecting processes within the project that are predicted to add value.

    “Fluidity” goes hand in hand with curation. As much as one can try to control a project, unexpected changes are bound to happen at any stage. Things that were carefully curated can suddenly take a different shape. Fluidity is about having that expectation and being able to adapt strategically without compromising on core needs, like safety.

    “Character” fueled these concepts, as it described how respectful relationships from effective and empathetic leaders fostered trust, good communication, and conflict solutions that allow work to be performed smoothly and safely.

    Lastly, there was the concept of “engagement,” teams taking pride and ownership in their work, creating a positive safety culture, sparking community and stakeholder involvement, and promoting inclusivity. All of these concepts link together in such a way that each reinforces the others.

     

    While the presentation covered a lot of ground and sparked some productive discussions, the competition was formidable. There was one more Brookhaven employee in 2023’s cohort: Angelika Drees, collider group leader for the Collider-Accelerator Department. While she was working with another team, she enjoyed comparing and contrasting her experiences with Broadbent as the program concluded and brought back a lot of insight to her current role.

    “I have never looked at another DOE project that closely before and I feel like I learned so much just from making comparisons,” recalled Drees. “It made me think about the new Electron-Ion Collider project in a different way. In some sense, there are a lot of similarities; it’s an accelerator and it has complex physics. And though it may not be the same in terms of scale and scope, there were general concepts that translate from one project to the other. Looking at this project so closely taught us a lot.”

    The scoring between teams was reported to be closer than it had ever been in the past. Regardless of the outcome, the exercise was valuable to all involved and provided a lot to think about for future projects.

    “We really enjoyed doing this,” remarked Broadbent. “Even though writing reports like this tends to be a lot of work, we worked together very well as a team and managed to have fun. It was a very different kind of experience and really made us think. The human side is something everyone can understand, and something everyone can improve upon. That thought came to mind very early on in the project and never went away. Each attribute we uncovered was very human-focused.”

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on social media. Find us on Instagram, LinkedIn, X, and Facebook.

     

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  • C2QA, a Year in Review

    C2QA, a Year in Review

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    Newswise — The Co-design Center for Quantum Advantage (C2QA), led by the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory, spans over 27 different partner and affiliate institutions ranging from research and academia to industry. C2QA’s primary focus is building the tools necessary to create scalable, distributed, and fault-tolerant quantum computer systems, and the center has been growing, building, and working hard every year to support that mission. 2023 has gone by quickly, with several memorable milestones to mark the way. Here are some highlights from the last year.

    Science and Technology

    Qubits, basic quantum systems that store information, are fussy things. The smallest fluctuations in their environment can cause them to break down. Heat, ambient radiation, magnetic fields, and even other surrounding qubits can cause the information stored in a qubit to leak into the environment and change its state, making it no longer viable. This is known as “decoherence,” and it’s one of the biggest challenges in making the quantum revolution a reality.

    The materials thrust has made significant progress in extending the lifetime of these finicky bits. Scientists from the Center for Functional Nanomaterials (CFN) and the National Synchrotron Light Source II (NSLS-II) at Brookhaven Lab and C2QA partner Princeton University investigated the fundamental reasons that tantalum qubits perform better by decoding this material’s chemical profile. The results of this work, which were recently published in the journal Advanced Science, will provide key knowledge for designing even better qubits in the future. CFN and NSLS-II are DOE Office of Science User Facilities at Brookhaven Lab.

    The Devoret Research Group at Yale University was also hard at work extending the lifetime and performance of qubits. Led by Michel Devoret, devices subthrust leader at C2QA, the team was able to double the life of a tantalum-based qubit through a process called error correction. Error correction is a special type of coding that will, theoretically, protect the information in a qubit. Researchers employed several methods that have built upon years of research to get to this groundbreaking result, which was published in Nature earlier this year.

    This year, Nathan Wiebe, leader of the Center’s software thrust, and his team worked on a quantum algorithm that simulated classical harmonic oscillators with significant advantage. While other simulations have achieved similar results, they have mostly investigated representations of systems that are already quantum mechanical in nature. This research demonstrated that, in the right conditions, a quantum computer could solve a classical problem in significantly less time.

    Community Outreach

    The quantum information science (QIS) community is growing as research accelerates, and C2QA is leaving no stone unturned to recruit outstanding talent and ensure that opportunities within the field are accessible to all communities and institutions. Some of this starts with reaching out to students as early as high school, introducing them to this budding field, and giving them a chance to connect with experts and learn more about it.

    This past summer, C2QA hosted QIS 101, a virtual quantum computing summer school. In its third year, QIS 101 built off its successes and learned from its challenges to optimize the course even more. The in-depth coursework, including 50 hands-on projects, was spread out over a six-week period this year. In its short three years, 12 alumni of the class obtained follow-on undergraduate or graduate internships at Brookhaven Lab, other DOE labs, or STEM-focused businesses; seven students were accepted into a master’s program in STEM fields; and two were accepted into Ph.D. programs in STEM fields. These accomplishments are a bright reflection of the talented pool of applicants that are accepted into QIS 101 and what they will bring to this growing field.

    The C2QA-led Quantum Information Science Virtual Career Fair continues to grow in both attendees and offerings. This year, the number of exhibitors more than doubled, reaching 42 booths that represented research, academia, and industry. The event drew in over 1,300 registrants, 39% more than the previous year, and 780 attendees—an encouraging 59% more than the previous year. About three-quarters of the attendees were students (23% undergrads and 44% graduate students) and postdocs (13%). There were 2,100 clicks on the job website, where jobseekers could apply instantly, and over 10,000 booths visited!

    The virtual Quantum Thursdays lecture series is still going strong. C2QA hosted 13 Quantum Thursdays on a variety of topics this year. While undergraduate students are the target audience for these beginner sessions, approximately 40% of attendees identified as undergraduate or graduate students. The series was expanded to include speakers and involvement from all five of the DOE Office of Science National Quantum Information Science Research Centers, setting the stage for a bigger picture of the quantum landscape in the coming year. Previous lectures can be viewed in C2QA’s video archive.

    Another important facet of growing the center is to ensure there is a place for everyone in quantum. The diverse talent brought in through programs that highlight otherwise underrepresented people and institutions benefits the entire QIS landscape.2023 saw the launch of the Faculty Outreach for Quantum-Interested UniversitieS (FOQUS) program. This collective program leveraged the resources and expertise of Brookhaven Lab, including the Office of Diversity, Equity and Inclusion and the Office of Educational Programs, C2QA, the DOE Office of Science’s Office of Workforce Development for Teachers and Scientists, and the IBM-HBCU Quantum Center. This ambitious program encouraged university faculty to combine and expand their networks and leverage programs offered by DOE to engage students and teachers. By breaking down barriers and fostering networking, faculty can prepare and develop underrepresented students from all STEM disciplines to enter the world of QIS.

    Looking to the Future 

    “In 2023, we’ve seen so many promising developments across each thrust in the Center,” remarked C2QA director Andrew Houck. “We’re not just uncovering answers, we’re finding new questions to ask in the year ahead. I think we are at this cusp, and we are about to see—in the next five or 10 years—these machines start to do things that are useful and better than any other technology.”

    Teaming up with other NQISRCs in the future can help remove some of the limitations on rapidly growing programs. QIS 101, for example, received 424 applications when the program can only support up to 40 students due to budget limitations. Joining forces with the other centers could allow a larger number of participants to take advantage of these opportunities in the future.

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on social media. Find us on Instagram, LinkedIn, X, and Facebook.

     

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  • High-performance, Earth-friendly Materials for Geothermal Wells

    High-performance, Earth-friendly Materials for Geothermal Wells

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    Newswise — UPTON, NY—The U.S. Department of Energy (DOE) has announced $19 million in funding over four years for a new research center focused on exploring the chemical and mechanical properties of cement composites and other materials used in enhanced geothermal systems (EGS). The “Center for Coupled Chemo-Mechanics of Cementitious Composites for EGS” (C4M)—one of 11 Energy Earthshot Research Centers (EERCs) just announced by DOE as part of its Energy Earthshots™ Initiative—will be located in the Interdisciplinary Science Department at DOE’s Brookhaven National Laboratory. Research there and at partner institutions will inform the design of Earth-friendly varieties of cement composites, coatings, and other barriers designed to protect geothermal wells. The ultimate goal is to expand the use of this abundant, sustainable form of energy.

    “Our Energy Earthshots are game-changing endeavors to unleash the technologies of the clean energy transition and make them accessible, affordable, and abundant,” said U.S. Secretary of Energy Jennifer M. Granholm. “The Energy Earthshot Research Centers and the related work happening on college campuses around the country will be instrumental in developing the clean energy and decarbonization solutions we need to establish a 100% clean grid and beat climate change.”

    Brookhaven Lab materials scientist Tatiana Pyatina, who leads the geothermal materials research effort at Brookhaven Lab and will direct the new C4M EERC, said, “Geothermal energy has the potential to transform abundant heat trapped deep underground into gigawatts of electricity for powering millions of American homes. It is renewable, has a small geographical footprint, and, unlike other green energies [e.g., wind and solar], is available around-the-clock.”

    But there are a few sticking points: The materials used to construct the wells—including cement composites that support and insulate the pipelike metal casings that carry Earth-heated fluids from subterranean depths to the surface—must withstand extreme temperatures and corrosive conditions and last for many years. Enhanced geothermal systems, which force more fluid than is naturally present through hot underground rocks to increase the extraction of heat, experience even greater thermo-mechanical stresses. Such stringent materials requirements can drive up construction costs.

    In addition, the cement currently used in well-supporting composites is an extreme carbon dioxide (CO2) emitter. Almost a pound of the heat-trapping gas is released for every pound of cement produced—through cement-making chemical reactions and the use of fossil fuels to power the process.

    “To realize geothermal energy’s potential, it is therefore essential to rationally design cost-effective, sustainable well-construction materials with a net-zero CO2 footprint,” Pyatina said.

    To achieve that goal, the C4M team will conduct extensive studies of the chemical and mechanical properties of new forms of cementitious composite materials. Their goals are to understand the chemical changes that take place in these materials under high temperature and pressure so they can design reliable and durable composites for use in the extremely challenging underground environments. By quantifying the effects of these chemical changes on materials’ performance, they will learn to control the solidification and transformations of these materials so they can be deployed successfully and economically in well construction and operation.

    “This work will build on a long history of award-winning research at Brookhaven Lab on materials for sustainable energy applications, including geothermal energy,” Pyatina said. “Our hope is that this research will achieve our goal of developing net-zero CO2 materials that will cut the cost of enhanced geothermal systems by 90% by 2035.” 

    Amy Marschilok, the energy systems and energy storage division manager of the Interdisciplinary Science Department, noted, “To meet our Nation’s energy goals we need new approaches to harness green energy and release it on demand. The new C4M EERC epitomizes the Interdisciplinary Science Department mission, leveraging Brookhaven Lab’s expertise across the innovation cycle from fundamental materials science to functional energy systems. I look forward to significant advances under Tatiana’s leadership.”

    New material needs

    In the process of cement production, limestone (calcium carbonate) and other materials are heated to very high temperatures in cement kilns. The high heat triggers a chemical reaction that decomposes the limestone, transforming the calcium carbonate and other ingredients into the compounds that ultimately make up cement powder. The limestone decomposition reaction and the heating that drives it (if powered by fossil fuels) release CO2. To avoid these CO2 emissions, the C4M team will be exploring the use of alternate minerals, possibly even the mud used to drill the wells, which would form its own cement in place.

    To ensure well durability, they’ll be seeking to identify materials with geologically stable mineral phases. They will also investigate the use of inorganic coatings that make the pipe-like well casings more resistant to high temperatures and aggressive environments. Some coatings may protect the metal casings so well that cement would no longer be needed.

    The team will use both laboratory experiments and computational modeling to elucidate and predict the performance of these new cements and composite materials from the atomic to the macroscopic scale, and for a time span ranging from seconds to years. They expect to use information identified through these studies and the use of artificial intelligence and high-performance computing to design advanced materials with long durability for geothermal applications.

    “We have assembled a multi-disciplinary team of leading researchers with complementary expertise,” Pyatina said, noting that the team will leverage expertise and DOE Office of Science user facilities at Brookhaven—including the National Synchrotron Light Source II (NSLS-II) and Center for Functional Nanomaterials (CFN)—as well as at partner institutions, including the Advanced Light Source at DOE’s Lawrence Berkley National Laboratory. Additional partners include DOE’s Sandia National Laboratory, DOE’s Lawrence Livermore National Laboratory, DOE’s Los Alamos National Laboratory, and four universities: University of Texas at Austin (a minority-serving institution), Cornell University, University of Illinois Urbana-Champaign, and Princeton University.

    “Through this Center, an incredibly talented team has been assembled to develop the fundamental understanding of the materials needed to push back the pressure and temperature boundaries of geothermal power production,” said Thomas Butcher, a research engineer who leads the energy conversion group in Brookhaven Lab’s Interdisciplinary Science Department. “Each member has been leading research in this area for a long time, but this project will allow them to focus on this important challenge in a truly collaborative way.”

    Another group of Brookhaven Lab scientists will participate as partners in one of the other Energy Earthshot Research Centers. That center—“Degradation Reactions in Electrothermal Energy Storage (DEGREES)”—will be led by DOE’s National Renewable Energy Laboratory (NREL). James Wishart, Simerjeet Gill, and Yu-chen (Karen) Chen-Wiegart, staff scientists at Brookhaven, will be partners in this center. They will explore the interactions of molten salts (used here as heat transfer fluids) with thermal energy storage materials and investigate how contact with molten salt affects the thermal materials’ stability and performance over time. This research will make use of multimodal x-ray synchrotron techniques at NSLS-II and will include studies on samples brought to NSLS-II from other partner institutions.

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on social media. Find us on Instagram, LinkedIn, Twitter, and Facebook.

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  • Making Big Leaps in Understanding Nanoscale Gaps

    Making Big Leaps in Understanding Nanoscale Gaps

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    Newswise — Creating novel materials by combining layers with unique, beneficial properties seems like a fairly intuitive process—stack up the materials and stack up the benefits. This isn’t always the case, however. Not every material will allow energy to travel through it the same way, making the benefits of one material come at the cost of another.

    Using cutting-edge tools, scientists at the Center for Functional Nanomaterials (CFN), a U.S. Department of Energy (DOE) User Facility at Brookhaven National Laboratory, and the Institute of Experimental Physics at the University of Warsaw have created a new layered structure with 2D material that exhibits a unique transfer of energy and charge. Understanding its material properties may lead to advancements in technologies like solar cells and other optoelectronic devices. The results were published in the American Chemical Society’s Nano Letters.

    2D Materials – Tiny, but Mighty

    Transition metal dichalcogenides (TMDs) are a class of materials structured like sandwiches with atomically thin layers. The meat of a TMD is a transition metal, which can form chemical bonds with electrons on their outermost orbit or shell, like most elements, as well as the next shell. That metal is sandwiched between two layers of chalcogens, a category of elements that contains oxygen, sulfur, and selenium. Chalcogens all have six electrons in their outermost shell, which makes their chemical behavior similar. Each of these material layers is only one atom thick—one-millionth the thickness of a strand of human hair—leading them to be referred to as two-dimensional (2D) materials.

    “At the atomic level, you get to see these unique and tunable electronic properties,” said Abdullah Al-Mahboob, a Brookhaven staff scientist in the CFN Interface Science and Catalysis group. “TMDs are like a playground of physics. We’re moving energy around from one material to the other at an atomic level.”

    Some new properties start to emerge from materials at this scale. Graphene, for example, is the 2D version of graphite, the material that most pencils are made of. In a Nobel Prize-winning experiment, scientists used a piece of adhesive tape to pull flakes off of graphite to study a layer of graphene. The researchers found the graphene to be incredibly strong at the atomic level—200 times stronger than steel relative to its weight! In addition, graphene is a great thermal and electrical conductor and has a unique light absorption spectrum. This unlocked the door to studying the 2D forms of other materials and their properties.

    2D materials are interesting on their own, but when combined, surprising things start to happen. Each material has its own superpower—protecting materials from the environment, controlling the transfer of energy, absorbing light in different frequencies—and when scientists start to stack them together, they create what is known as a heterostructure. These heterostructures are capable of some extraordinary things and could one day be integrated into future technologies, like smaller electronic components and more advanced light detectors.

    QPress—A First-of-its-Kind Experimental Tool

    While the exploration of these materials may have started with something as simple as a piece of adhesive tape, the tools used to extract, isolate, catalog, and build 2D materials have become quite advanced. At CFN, an entire system has been dedicated to the study of these heterostructures and the techniques used to create them—the Quantum Material Press (QPress).

    “It’s hard to compare the QPress to anything,” said Suji Park, a Brookhaven staff scientist specializing in electronic materials. “It builds a structure layer by layer, like a 3D printer, but 2D heterostructures are built by an entirely different approach. The QPress creates material layers that are an atom or two thick, analyzes them, catalogs them, and finally assembles them. Robotics is used to systematically fabricate these ultrathin layers to create novel heterostructures.”

    The QPress has three custom built modules—the exfoliator, cataloger, and stacker. To create 2D layers, scientists use the exfoliator. Similar to the manual adhesive tape technique, the exfoliator has a mechanized roller assembly that exfoliates thin layers from larger source crystals with controls that provide the kind of precision that can’t be achieved by hand. Once collected and distributed, the source crystals are pressed onto a silicone oxide wafer and peeled off. They are then passed along to the cataloger, an automated microscope combing several optical characterization techniques. The cataloger uses machine learning (ML) to identify flakes of interest that are then cataloged into a database. Currently, ML is trained with only graphene data, but researchers will keep adding different kinds of 2D materials. Scientists can use this database to find the material flakes they need for their research.

    When the necessary materials are available, scientists can use the stacker to fabricate heterostructures from them. Using high-precision robotics, they take the sample flakes and arrange them in the order needed, at any necessary angle, and transfer substrates to create the final heterostructure, which can be stored long-term in a sample library for later use. The climate is controlled to ensure the quality of the samples and the fabrication process from exfoliation to building heterostructures is conducted in an inert gas environment in a glovebox. The exfoliated flakes and the stacked samples are stored in vacuum, in the sample libraries of the QPress cluster. Additionally, electron beam evaporation, annealing, and oxygen plasma tools are available in the vacuum side of the cluster. Robotics are used to pass samples from one area of the QPress to the next. Once these novel heterostructures are fabricated though, what do they actually do and how do they do it?

    After the team at CFN fabricated these fascinating new materials with the QPress, they integrated the materials with a suite of advanced microscopy and spectroscopy tools that enabled them to explore optoelectronic properties without exposing the samples to air, which would degrade material structures. Some of the delicate, exotic quantum properties on 2D materials need ultra-low cryo-temperatures to be detected, down to just a few kelvins. Otherwise, they get perturbed by the slightest amount of heat or any chemicals present in the air.

    Al-Mahboob’s work is funded by the DOE Quantum Materials: Integrated Multimodal Characterization and Processing (QM-IMCP) project that CFN has started to build. This platform will include advanced microscopes, x-ray spectrometers, and ultrafast lasers that are able to investigate the quantum world at cryo-temperatures.

    Building Better Structures

    Using the advanced capabilities of these resources, the team was able to get a more detailed picture of how long-distance energy transfer works in TMDs.

    Energy wants to move across materials, the way a person wants to climb a ladder, but it needs a place to hold on to. Bandgaps can be thought of as the space between the rungs of a ladder. The larger the gap, the harder and slower it is to climb. If the gap is too large, it might not even be possible to finish moving up. Using materials that already have great conducting properties, this specialized team of scientists was able to stack them in a way that leveraged their structure to create pathways that transfer the charge more efficiently.

    One of the TMDs the team created was molybdenum disulfide (MoS2), which was shown in previous studies to have strong photoluminescence. Photoluminescence is the phenomenon that makes certain materials glow in the dark after they are exposed to light. When a material absorbs light with more energy than that energy bandgap, it can emit light with photon energy equal to the bandgap energy. If a second material with an equal or lower energy bandgap gets closer to the first, as close as a sub-nanometer to few nanometers, energy can transfer nonradiatively from the first material to the second. The second material can then emit light with photon energy equal to its energy bandgap.

    With an insulating interlayer made of hexagonal boron nitride (hBN), which prevents electronic conductivity, scientists observed an unusual kind of long-distance energy transfer between this TMD and one made of tungsten diselenide (WSe2), which conducts electricity very efficiently. The energy transfer process occurred from the lower-to-higher bandgap materials, which is not typical in TMD heterostructures, where the transfer usually occurs from the higher-to-lower bandgap 2D materials. The thickness of the interlayer played a big role, but also appeared to defy expectations. “We were surprised by the behavior of this material,” said Al-Mahboob. “The interaction between the two layers increases along with the increase in distance up to a certain degree, and then it begins to decrease. Variables like spacing, temperature, and angle played an important role.”

    By gaining a better understanding of how these materials absorb and emit energy at this scale, scientists can apply these properties to new types of technologies and improve current ones. These could include solar cells that absorb light more effectively and hold a better charge, photosensors with higher accuracy, and electronic components that can be scaled down to even smaller sizes for more compact devices.

    This study was supported by the DOE Office of Science.

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on social media. Find us on Instagram, LinkedIn, Twitter, and Facebook.

     

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  • Four Brookhaven Scientists Receive Early Career Research Awards

    Four Brookhaven Scientists Receive Early Career Research Awards

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    Newswise — UPTON, NY—Four scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory have been selected by DOE’s Office of Science to receive significant funding through its Early Career Research Program. The program, which began in 2010, bolsters the nation’s scientific workforce by supporting exceptional researchers at the outset of their careers, when many scientists do their most formative work.

    The awards are a part of the DOE’s long-standing efforts to develop the next generation of STEM leaders to solidify America’s role as the driver of science and innovation around the world.

    “Supporting America’s scientists and researchers early in their careers will ensure the United States remains at the forefront of scientific discovery,” said U.S. Secretary of Energy Jennifer M. Granholm. “The funding announced today gives the recipients the resources to find the answers to some of the most complex questions as they establish themselves as experts in their fields.”

    DOE is recognizing a total of 93 awardees representing 47 universities and 12 DOE National Laboratories in 27 states. Awardees were selected based on peer review by outside scientific experts.

    The projects announced today are selections for negotiation of a financial award, and cover projects lasting up to five years in duration. The final details for each are subject to final grant and contract negotiations between DOE and the awardees. The Early Career Research Program is funded by DOE’s Office of Science.

    Information about the 93 awardees and their research projects is available on the Early Career Research Program webpage.

    This year’s Brookhaven Lab awardees are:

    Elizabeth (Liza) Brost, “Shining Light on the Higgs Self-Interaction”

    Elizabeth Brost, an associate scientist in Brookhaven Lab’s Physics Department, will receive funding through the DOE’s Office of High Energy Physics to study properties of the Higgs boson, including its self-interaction.

    Discovered in 2012 at the Large Hadron Collider (LHC) at CERN in Switzerland, the Higgs boson is the fundamental particle associated with the Higgs field, which imparts mass to other fundamental particles. The Standard Model of particle physics, scientists’ best understanding of the particles and forces that make up our world, predicts that the Higgs field can interact with itself. This self-interaction should contribute to the production of pairs of Higgs bosons at the LHC. Brost’s studies of Higgs pair production will provide a path towards measuring the Higgs self-interaction—and ultimately a deeper understanding of the Higgs boson’s role in the Standard Model.

    One major challenge is that pair production of Higgs bosons is extraordinarily rare in proton-proton collisions at the LHC—more than 1000 times rarer than collisions producing single Higgs bosons! In this project, Brost will lead the development of novel techniques to select fruitful collision data in real time using machine learning algorithms. Using data from the LHC’s ATLAS detector, she and her collaborators will search for the direct and indirect effects of “new physics” beyond the Standard Model on Higgs pair production. These measurements may confirm that the Higgs behaves as expected in the Standard Model. Or they may point to the influences of new physics, which must then be incorporated into explanations of the Higgs mechanism and other areas of physics.

    “I am honored to receive this Early Career Award, which will enable me to pursue some of the most interesting open questions in high energy physics,” Brost said. “The analysis and data-collection techniques developed through this project will advance our understanding of the Higgs boson at unprecedented scales, not only at the LHC but also at proposed future colliders.”

    Brost earned her undergraduate degree in physics and French from Grinnell College in 2010 and her Ph.D. in physics from the University of Oregon in 2016. After serving as a postdoctoral research associate at Northern Illinois University from 2016 to 2019, she joined Brookhaven National Laboratory as an assistant physicist. She was promoted to associate physicist in 2021. Stationed at Europe’s CERN laboratory, home to the LHC, Brost has led groups of hundreds of ATLAS physicists on a range of analyses and detector upgrades, many associated with “di-Higgs” searches. She also has extensive experience mentoring students and postdocs, who will play important roles in executing the goals of this Early Career Award project.

    Esther Tsai, “Virtual Scientific Companion for Synchrotron Beamlines” 

    Esther Tsai, a scientist in the Electronic Nanomaterials Group of the Center for Functional Nanomaterials (CFN), aims to strengthen the interactions between human scientists and the artificial intelligence/machine learning (AI/ML) tools that can accelerate their research. With funding from the DOE Office of Basic Energy Sciences, she is developing a revolutionary system that will allow scientists to launch experiments and analyze data using a conversational interface.

    She’s particularly interested in alleviating bottlenecks at the National Synchrotron Light Source II (NSLS-II)—a source of extremely intense x-rays used by more than 1,700 researchers from universities, industry, and other national laboratories each year to study the properties of a wide range of materials. Currently, CFN and NSLS-II staff collaborate with these facility “users,” assisting in the setup, scientific planning/discussion, and analysis of data from experiments at several beamlines run in partnership by these two DOE Office of Science user facilities. Their research on complex materials has the potential to improve the performance of electronics, solar cells, batteries, and other applications. But the beamlines are often understaffed and oversubscribed.

    “Beamline scientists have the daunting mission of supporting various aspects of beamline operation and user science through tireless and sleepless efforts,” Tsai said.

    Her goal is to develop a virtual scientific companion, known as VISION, that will synergistically connect researchers with computational tools to speed up the experimentation so everyone can make more discoveries—and possibly get more sleep.

    The virtual assistant will leverage modern developments in natural language (NL) processing and language models—the technology underpinning the revolutionary capabilities of chatbots and AI assistants. Tsai will tailor these methods to scientific experiments, allowing researchers to input queries in ordinary language without the need for complex coding. VISION will transcribe NL voice to text, acquire and analyze data, visualize results, and provide advanced learning algorithms and physics modeling to suggest optimal experiment design or hypotheses for further exploration. This powerful, general approach can be extended to a host of scientific instruments to accelerate the pace of discovery across the DOE complex.

    “We’re not taking humans out of the picture; we’re actually making it easier for humans to use their natural form of expression, whether speaking or texting, to leverage the strengths of powerful AI/ML programming. We envision a new era where human NL-based communication will be the only needed interface for scientific experimentation and design,” said Tsai.

    “It is a great honor and responsibility to receive this Early Career Award. I am so very grateful for the support I’ve received from colleagues at Brookhaven and especially my group leader, Kevin Yager,” Tsai said. “I will continue to need their support to introduce this new paradigm of NL-controlled scientific expedition.”

    Tsai earned a bachelor’s degree in electrical engineering in 2009 and a Ph.D. in electrical and computer engineering in 2014, both from Purdue University. Before joining Brookhaven Lab’s CFN as an assistant scientist in 2018, she conducted postdoctoral research and provided user support at the Swiss Light Source at the Paul Scherrer Institute from 2015 to 2018. She was promoted to associate scientist at Brookhaven in 2021, and to scientist in 2023.

    Derong Xu, “Luminosity Maximization with Flat Hadron Beams”

    Derong Xu, an assistant physicist working on the future Electron-Ion Collider (EIC) at Brookhaven Lab, is striving to maximize the collider’s most important figure of merit by maintaining the flatness of a beam of ions travelling at nearly the speed of light.

    The EIC will collide two beams—one containing electrons and the other containing protons or other atomic nuclei. The collisions between individual electrons and other ions will produce data that scientists will use to study the internal structure of protons and nuclei, including the arrangement of those particles’ quarks and gluons. If more particle collisions occur, scientists can produce and analyze more data that contribute to our understanding of how visible matter evolved from the quark-gluon plasma studied over the past two decades at the Relativistic Heavy Ion Collider (RHIC), an Office of Science user facility at Brookhaven.

    Physicists can increase the likelihood of these collisions occurring by reducing beam size—packing the same number of particles into a smaller space. This methodology, known as maximizing “luminosity,” is exactly what Xu will work on for the EIC with funding from DOE’s Office of Nuclear Physics. According to calculations by Xu and his colleagues, flattening the ion beam of the EIC will help attain the maximum luminosity. This approach has never been used in a hadron collider—a machine that collides composite particles made of quarks and gluons.

    Though scientists can generate flat ion beams, maintaining this flatness as trillions of charged particles whirl around a collider is a challenge. There are numerous potential interactions, such as those between beams and the superconducting accelerator magnets, that could compromise the quality of the beam and make it harder to focus it to a small, flat spot size at the collision point. Xu’s work will dissect the interactions that could alter beam flatness and investigate methods to reduce or eliminate these effects to maintain high luminosity.

    “Our efforts to improve the luminosity for the EIC will also benefit other future colliders,” said Xu. “I am excited to contribute to this important research endeavor.”

    “I am deeply honored to receive this award and express my heartfelt gratitude for this exceptional opportunity,” Xu added. “The challenge of using a flat beam in future colliders captivates me, and I am eager to explore this topic further.”

    Xu studied accelerator physics at the University of Science and Technology of China (USTC), receiving a bachelor’s degree in 2011 and a Ph.D. in 2016. Xu was a postdoctoral fellow from 2017 to 2018 and then a research fellow from 2018 to 2019 at the National Synchrotron Radiation Laboratory at USTC. Xu’s work on the EIC began at Michigan State University in 2019 and continued at Brookhaven when he joined the Lab in 2021 as an assistant physicist.

    Joanna M Zajac, “Interactions of QDs’ Fast Light in Rb Vapors for Hybrid Quantum Information Science and Technology” 

    Joanna M Zajac, a quantum scientist in the Instrumentation Division, is tackling one of the biggest challenges in quantum networking—developing a fundamental understanding of fast light-matter interconnects that could one day facilitate long distance quantum networks.

    With funding from the DOE Office of Basic Energy Sciences, she will design and build systems that use quantum dots (QD) to generate identical single photons (the simplest fundamental portions of light) in the wavelengths used for optical telecommunication. Quantum dots are light-emitting semiconductor nanostructures whose emission can be tuned to different wavelengths. They could potentially generate photons suitable to work at telecommunication and atomic wavelengths. That would help to reduce the high losses currently experienced when quantum information travels through the telecommunication optical fibers network. 

    The goal is then to couple QD single photons with alkali vapors, such as rubidium (Rb), which can reliably store quantum information. These light-matter interconnects may one day operate as a basis for quantum repeaters that receive and then re-emit quantum information making up nodes of quantum network connected by optical links over long distances. This research could be applied to a range of areas in quantum information science and technology such as quantum computing, quantum communications, and quantum sensing.

    “Fast light-matter interconnects made of alkali atomic ensembles and photons from quantum dots (QDs) create a heterogenous system that combines the advantages of its homogenous components’, Zajac said. “Within this project we are going to develop fundamental understanding of interactions therein allowing us to develop components of long-distance quantum networks in the future. This DOE award gives me a fantastic opportunity to explore this important topic among the vibrant scientific community in Brookhaven Lab’s Instrumentation Division and beyond.”

    Zajac pursued her education in the United Kingdom, earning her master’s degree in physics from Southampton University in 2008 and her Ph.D. in physics from Cardiff University in 2013. She was a postdoctoral research associate at Heriot-Watt University from 2013 to 2016 and a research fellow at St. Andrews University in 2016. Before joining Brookhaven Lab’s Instrumentation Division as a quantum scientist in 2021, she was a senior researcher at Oxford University (2020-21), United Kingdom.

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on social media. Find us on Instagram, LinkedIn, Twitter, and Facebook.

    Denise Yazak and Danielle Roedel contributed to the writing of this news release.

     

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  • JoAnne Hewett Named Director of Brookhaven National Laboratory

    JoAnne Hewett Named Director of Brookhaven National Laboratory

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    Newswise — UPTON, NY—The Board of Directors of Brookhaven Science Associates (BSA) has named theoretical physicist JoAnne Hewett as the next director of the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory and BSA president. BSA, a partnership between Stony Brook University (SBU) and Battelle, manages and operates Brookhaven Lab for DOE’s Office of Science. Hewett will also hold the title of professor in SBU’s Department of Physics and Astronomy and professor at SBU’s C.N. Yang Institute for Theoretical Physics.

    “JoAnne has a strong research background and extensive experience as a scientist and leader,” said DOE Office of Science Director Asmeret Asefaw Berhe. “She is a great choice to advance the Department of Energy’s priorities at Brookhaven—from fundamental breakthroughs to applications that improve people’s lives each and every day.”

    Hewett’s appointment comes after an international search that began in summer 2022. Current Brookhaven Lab Director Doon Gibbs announced in March 2022 his plans to step down after leading the Laboratory for nearly a decade.

    Hewett comes to Brookhaven from SLAC National Accelerator Laboratory in Menlo Park, CA, where she most recently served as associate lab director (ALD) for fundamental physics and chief research officer. She also is a professor of particle physics and astrophysics at SLAC/Stanford University.

    “JoAnne brings vital experience and proven leadership skills to further Brookhaven Lab’s game-changing discoveries and innovative breakthroughs that benefit science and society,” said Maurie McInnis, president, Stony Brook University, and co-chair, BSA Board of Directors. “As Brookhaven advances major projects, expands its mission, and further modernizes its campus where scientists are solving the most urgent challenges of our time, we are pleased to welcome her as the Lab’s next director.”

    “We are so excited to welcome JoAnne Hewett as the next director of Brookhaven National Laboratory,” said BSA Board co-chair Mark Peters, executive vice president for national laboratory management and operations at Battelle. “Her outstanding scientific credentials and management and leadership skills will lead the Lab to new heights of scientific discovery and impactful science and technology in service of our nation.”

    Brookhaven Lab celebrated its 75th anniversary in 2022 and is home to seven Nobel Prize-winning discoveries and countless advances. Its 5,322-acre site on eastern Long Island attracts scientists from across the country and around the world, offering them expertise and access to large user facilities with unique capabilities. As DOE’s only multi-program lab in the northeastern U.S., Brookhaven hosts thousands of guest researchers and facility users each year—in-person and virtually—from universities, private industry, and government agencies. The Lab’s annual budget is approximately $700 million, much of which is funded by the DOE and its Office of Science.

    As Lab director, Hewett will oversee a team of more than 2,800 scientists, engineers, technicians, and professionals working to address challenges in nuclear and high energy physics, clean energy and climate science, quantum computing, artificial intelligence, photon sciences, isotope production, accelerator science and technology, and national security.

    “I am honored to take on the role of laboratory director at Brookhaven, a truly exceptional national laboratory with a rich history and a talented and dedicated staff,” said Hewett. “The Lab has an extremely bright future, one that will help solve some of the greatest scientific challenges facing the world today.” 

    Hewett is expected to join Brookhaven Lab this summer. Gibbs will retire on April 17, and Brookhaven’s long-time Deputy Director for Operations Jack Anderson will serve as interim laboratory director until Hewett is on board. The Lab’s current ALD for Facilities and Operations Tom Daniels will serve as interim deputy director for operations while Anderson is in the interim director role.

    “I am grateful to Doon for his outstanding leadership of Brookhaven and his long legacy of building and strengthening the Lab for advancing scientific discovery,” said Hewett. “I am excited to realize the truly ambitious array of projects here, launch innovative, world-leading science programs, expand the diversity of the Brookhaven community, and continue to strengthen our ties to New York State and our partner universities.”

    Governor Kathy Hochul added, “Brookhaven National Laboratory plays an important role for advancing science and engineering both nationally and here in New York, and I’m confident that JoAnne Hewett will be a great addition as the newest director. JoAnne is not only incredibly qualified and talented, but will also make history as the first woman to serve in this critical role. The Lab has developed innovative ways to deliver on New York’s top priorities, from battling disease to acting on climate, that are making a difference today and for the future of New York. I look forward to working with JoAnne Hewett in her new role as Brookhaven continues to advance cutting-edge technologies to improve the lives of New Yorkers.”

    Hewett will also participate in the final hiring decision for the deputy director for science and technology position currently held by Robert Tribble. The search for Tribble’s replacement is nearing completion following his announcement last year that he would also step down after eight years in his current role.

    Longtime Scientist, Leader

    Hewett is a theoretical physicist. Her research probes the fundamental nature of space, matter, and energy. She is best known for her work on physics beyond the Standard Model of particle physics and how that might relate to experiments.

    Since joining SLAC faculty in 1994 as its first woman member, Hewett has served in key leadership roles, including head of the Theoretical Physics Group, deputy director of the Science Directorate and director of SLAC’s Elementary Particle Physics (EPP) Division, as well as her current roles as ALD and CRO.

    During her tenure as ALD, Hewett aligned the program with the particle physics community’s highest priorities by establishing a neutrino theory and experimental program, initiated the Dark Matter New Initiatives program for small experiments, launched the Detector Microfabrication Facility, and oversaw the transition of Rubin Observatory and Super Cryogenic Dark Matter Search to commissioning and operations. As deputy director of the Q-NEXT national quantum center, she helped shepherd a key partnership between SLAC and other institutions to further the field of quantum science.

    Hewett has twice been a member of the High Energy Physics Advisory Panel—which advises the federal government on the national program in experimental and theoretical high energy physics (HEP) research—and is the panel’s current chair. She made major contribution to the recent Particle Physics Project Prioritization Panel (“P5”) plan that defines priorities for U.S. high-energy physics research over the next 10 years. She also has served on the program advisory committees for SLAC, Fermi National Accelerator Laboratory, the Kavli Institute for Theoretical Physics, and the Cornell Electron Storage Ring.

    Hewett is a fellow of the American Association for the Advancement of Science and the American Physical Society. She also served as chair of the American Physical Society’s Division of Particles & Fields in 2016.

    Hewett earned her bachelor’s degree in physics and mathematics and Ph.D. in physics from Iowa State University.

    Looking to the Future

    Hewett is taking on this role at an exciting time, as Brookhaven prepares to begin construction of the Electron-Ion Collider (EIC). This one-of-a-kind nuclear physics research facility will be built at Brookhaven through a partnership among DOE, Thomas Jefferson National Accelerator Facility, and Brookhaven. The EIC is being funded by the federal government, primarily through the DOE Office of Science. It will draw on expertise throughout the DOE national laboratory complex and from universities and research institutions worldwide. The total project cost is expected to range from $1.7-2.8 billion. About $100 million in New York State funding will support EIC construction of new infrastructure at Brookhaven Lab that is essential for the EIC project.

    The Laboratory is also building a new welcome center, the Science and User Support Center. This is the first building planned for Discovery Park, a new vision for Brookhaven Lab’s gateway to increase opportunities for the community to engage with the Laboratory and the DOE.

    “I can’t think of a better time to join such a vibrant Laboratory, given all of the exciting projects ahead—including the EIC, Discovery Park, and an expanded medical isotopes program—that will help define the Lab’s future,” said DOE Brookhaven Site Office Manager Robert Gordon.

    “I am head-over-heels excited to build the EIC in partnership with Jefferson Lab to unlock the mysteries of the force that binds Nature’s building blocks, to strengthen connections to industry and the community with Discovery Park, and to advance the multi-program missions of the Lab,” said Hewett. “And I’m very much looking forward to working with everyone at Brookhaven, Stony Brook, and the DOE to usher the Lab into its next successful chapter.”

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on Twitter or find us on Facebook.

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  • Brookhaven HSRP and SPARK Program Alumni Selected in 2023 Regeneron Science Talent Search

    Brookhaven HSRP and SPARK Program Alumni Selected in 2023 Regeneron Science Talent Search

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    Newswise — Last month, Society for Science (the Society) announced the 300 scholars in the Regeneron Science Talent Search 2023. The scholars were each awarded $2,000 and also awarded $2,000 for their school. Scholars were chosen based on their research, leadership skills, community involvement, commitment to academics, creativity in asking scientific questions, and promise as STEM leaders, demonstrated through the submission of their original, independent research projects, essays and recommendations (See the full list of this year’s scholars).

    Two of this year’s scholars were not only students from high schools on Long Island, but also young researchers who participated in two of the intensive educational programs offered at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory. Having the hands-on experience of working in a busy laboratory environment, seeing their research being carried out, and collaborating with experts in their fields of interest was a big asset in applying to a competition of this caliber.

    “These programs provide students with an authentic research experience,” said Aleida Perez, Interim Manager of University Relations and Workforce Development for Teachers and Scientists (WDTS) and DOE Programs at Brookhaven Lab. “They are able to develop their scientific skills and build a collaborative network for their future educational, and perhaps professional, paths.”

    Jack Shultz, a student at Westhampton Beach high school, was part of the Student Partnerships for Advanced Research and Knowledge (SPARK) Program at Brookhaven Lab last year. In this program, high school students and their science educators become visiting researchers with access to Brookhaven National Laboratory’s scientific facilities. Shultz has a core interest in biology and chemistry, which has led to several research projects and more specific areas of interest.

    “Living on Long Island, it’s easy to take for granted what a unique and incredible environment we have,” said Shultz. “In a short amount of time, you can actually see climate change effects firsthand in things like marine ecosystems or the change in local weather patterns.”

    Shultz has been researching kelp ecosystems on Long Island using the SRX and XPD beamlines at the Lab’s National Synchrotron Light Source II—a U.S. Department of Energy (DOE) Office of Science user facility—under the mentorship of Juergen Thieme, science coordinator for the imaging & microscopy program at NSLS-II and Eric Dooryhee, program manager for the Hard X-ray Scattering and Spectroscopy (HXSS) program at NSLS-II.

    “The scientists at the beamlines were so helpful and inclusive,” recalled Schultz. “Their willingness and enthusiasm really pushed the boundaries of my work. Eric and Juergen were so encouraging and informative. There are people here with two doctorates, but they treat high school students like peers. It’s amazing that we have a resource like this locally, and many people may have research ideas that could benefit from it but have no idea it exists or that there are pathways to access it.”

    His experience applying and being selected as a Regeneron scholar and being able to experience what it’s like to do research in a national laboratory setting as part of a team of professional scientists has only reaffirmed Shultz’s enthusiasm for science. He plans to continue his current research and pursue a degree in molecular biology.

    Marc Nichitiu is a high school senior at the Stony Brook School that participated in the lab’s 2022 High School Research Program (HSRP). This competitive six-week program allows high school juniors and seniors to collaborate on a research project with Brookhaven Laboratory staff. Nichitiu was mentored by Igor Zaliznyak, a scientist specializing in Neutron Scattering in Brookhaven Lab’s Condensed Matter Physics and Materials Science Department. Zaliznyak was not only an encouraging mentor, but his advice was also one of the reasons Nichitiu entered the Regeneron competition.

    “At first, I thought that I didn’t really have the time to apply for the scholarship and I simply wanted to focus on my research,” recalled Nichitiu, “but Dr. Zaliznyak really liked the research I was doing and encouraged me to write it up. It’s good practice, in general, to be able to describe what you’ve been doing and explain it to others. Indeed, just the experience of applying was helpful.”

    Nichitiu collaborated with Zaliznyak to characterize the scattering signature of superfluid helium using thermal neutrons. From making balloons float to creating the computer chips in your smartphone, helium is in high demand on earth, but it is not an infinite resource. The need for this element continues to grow, but it is non-renewable noble gas, and the global supply is limited. Nichitiu started his research thinking of how describing neutron scattering signatures could help future space probes seek resources like helium from places beyond the constraints of our own planet. Nichitiu was also fascinated with helium’s behavior at very low temperatures.

    “If you take helium gas and you cool it down below 2.2 Kelvin, you get a special kind of liquid called a super fluid, which has zero viscosity” explained Nichitiu. “Since it has zero friction, it can just creep up the walls or through the tiniest crevices, which makes it really good for leak detection and for powering thermo-mechanical pumps in space. The discovery of the frictionless behavior of superfluid helium marked a cornerstone in modern physics with implications for the study of superconductivity and the universe’s phase transitions following the Big Bang.”

    Both scholars encourage students with a passion for STEM to ignore their doubts and apply. Applications for the 2024 search will be accepted from June of this year into November, leaving plenty of time to start planning out a research project to submit.

    “There’s no harm in applying,” said Nichitiu. “If you’re doing any sort of scientific research that you know you believe has some merit to the scientific community, you should definitely try. Even if it gets rejected, even if it’s not on par with the journals you would want to submit it to, it’s really important to get those basic scientific skills.”

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, please visit science.energy.gov.

    Follow @BrookhavenLab on Twitter or find us on Facebook.

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  • Brookhaven Lab Battery Scientist, Hydrogeologist, and DOE Site Office Manager Among Secretary of Energy’s 2022 Honorees

    Brookhaven Lab Battery Scientist, Hydrogeologist, and DOE Site Office Manager Among Secretary of Energy’s 2022 Honorees

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    Newswise — UPTON, NY—On January 24, 2023, U.S. Secretary of Energy Jennifer Granholm honored 44 teams with the Secretary of Energy Achievement Award and five individuals for their work. Among the recipients are Distinguished Professor Esther Takeuchi, a battery researcher with a joint appointment at the Department of Energy’s (DOE) Brookhaven National Laboratory and Stony Brook University; Douglas Paquette, a hydrogeologist in Brookhaven Lab’s Environmental Protection Division; and Robert Gordon, manager of the DOE-Brookhaven Site Office that oversees operations at Brookhaven Lab.

    “These awards are among the highest forms of internal, non-monetary recognition DOE Federal and contractor employees can receive,” Secretary Granholm said in a statement. “They are bestowed on individuals and teams in recognition of service which goes above and beyond, and for contributions having lasting impacts on both DOE and on our great Nation. Along with the entire DOE leadership team, I am so proud of the accomplishments of our award recipients. Their commitment to achieving DOE’s mission is an inspiration.”

    Takeuchi was honored for her role on an 80-member team of scientists and support staff from across the DOE National Laboratory complex who facilitated eight virtual panel discussions as part of a Congressional briefing series entitled “Driving U.S. Competitiveness & Innovation: A New Era of Science for Transformative Industry.” The team created a platform for American industry leaders and National Laboratory scientists to speak directly with Congressional staffers. Their goal was to discuss the productivity of public-private collaborations to accelerate emergent technologies and American leadership in artificial intelligence, microelectronics, quantum information sciences, the bioeconomy, and materials and chemistry for clean energy.

    This effort highlighted how capabilities at DOE National Laboratories and their User Facilities (including the National Synchrotron Light Source II and Center for Functional Nanomaterials at Brookhaven Lab) have been used to advance cutting-edge industries and American technical leadership. The discussions also emphasized how partnerships between DOE-supported researchers and American companies can accelerate the Nation’s competitiveness and innovation and address workforce development challenges to prepare for these emergent industries in ways that promote diversity, equity, and inclusion.

    “I was delighted to participate in the topic of ‘Materials and Chemistry for Clean Energy,’” Takeuchi said. “This forum provided a venue to discuss the opportunity for impact of federally funded research and the national labs in strengthening U.S. industrial competitiveness. My discussions featured energy storage as critical to the clean energy transformation including electrifying transportation and adoption of clean energy generation.”

    Paquette and Gordon both served on a team honored for helping DOE formulate a strategy for addressing the impacts of per- and polyfluoroalkyl substances (PFAS). PFAS are a class of widely manufactured chemicals that in recent years have been identified as emerging contaminants of concern in many communities across the United States. Historically, they have been widely used in products such as nonstick pans, water-repellent clothing, and firefighting foams. 

    National focus on PFAS has led to a wide array of Federal and state-level regulatory approaches and policy initiatives. The PFAS Policy Development Team, made up of representatives from multiple DOE offices, coordinated efforts within the DOE and with external stakeholders to better understand and manage the regulations, risks, and liabilities associated with these substances.

    This work enabled DOE to gather information about current and past uses of PFAS; develop policies, guidance documents, and educational materials to support more effective efforts to manage PFAS-related liabilities and constructively engage with internal and external stakeholders; and identify research needs and opportunities to support DOE efforts to develop solutions to PFAS challenges. The coordinated efforts of this team have positioned DOE to engage constructively on an issue of high-level national concern in an informed, proactive, and effective manner.

    “I am honored to be part of the team that was recognized by the Secretary of Energy,” Paquette said. “Over the past four years, the DOE has been proactive in trying to understand the extent of PFAS contamination resulting from past operations and to prevent any new impacts to the environment.”

    The PFAS team recently produced three noteworthy documents including the DOE PFAS Roadmap, the DOE Initial site-by-site PFAS survey, and the DOE Initial PFAS Research and Development Plan. These documents can be found on DOE’s PFAS website at Energy.gov/pfas.

    “Each of these documents highlights Brookhaven Lab’s contributions to PFAS R&D solutions, novel approaches to PFAS remediation, and transparency with the community and regulators,” said Gordon. “It’s not a coincidence that Brookhaven Lab is prominent in DOE’s key PFAS documents; it is because of Brookhaven’s recognized expertise, experience, and willingness to serve as a resource across the DOE enterprise.”

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on Twitter or find us on Facebook.

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  • Celebrating the Upcoming sPHENIX Detector

    Celebrating the Upcoming sPHENIX Detector

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    Newswise — UPTON, NY— Asmeret Asefaw Berhe, Director of the U.S. Department of Energy’s (DOE) Office of Science, visited DOE’s Brookhaven National Laboratory on Jan. 27 to celebrate the fast-approaching debut of a state-of-the-art particle detector known as sPHENIX. The house-sized, 1000-ton detector is slated to begin collecting data at Brookhaven Lab’s Relativistic Heavy Ion Collider (RHIC), a DOE Office of Science User Facility for nuclear physics research, this spring.

    Like a massive, 3D digital camera, sPHENIX will capture snapshots of 15,000 particle collisions per second to provide scientists with data to better understand the properties of quark-gluon plasma (QGP)—an ultra-hot and ultra-dense soup of subatomic particles that are the building blocks of nearly all visible matter. RHIC collisions briefly recreate the conditions of the universe a fraction of a second after the Big Bang, some 14 billion years ago. Studying QGP can help physicists learn about the origins of matter as we know it and how nature’s strongest force binds quarks and gluons into protons and neutrons, the particles that make up ordinary atomic nuclei.  

    “Brookhaven National Laboratory continues to be a central hub of nuclear physics expertise, making it the world’s premier facility for studying the quark gluon plasma,” said Asmeret Asefaw Berhe, DOE’s Director of the Office of Science. “The sPHENIX detector, and the talented collaboration that will operate it, will strive to give us that answer and the final piece of the quark-gluon puzzle.”

    Brookhaven Lab Director Doon Gibbs said, “sPHENIX marks a key milestone in the RHIC science program. It will allow us to explore many questions raised by incredible discoveries already made at RHIC, especially the surprising liquid nature of the quark-gluon plasma, and lay the foundation for future discoveries at the Electron-Ion Collider. I congratulate and thank all the scientists, engineers, technicians, and support staff at Brookhaven—and sPHENIX collaborators around the world—who have worked together to make this detector possible.”

    At the core of sPHENIX is a 20-ton cylindrical superconducting magnet that will bend the trajectories of charged particles produced in RHIC collisions. The magnet is surrounded and filled with subsystems that include complex silicon detectors, a Time Projection Chamber, and calorimeters that will capture details of particle jets, heavy quarks, and rare, high-momentum particles fast and accurately. These advanced particle tracking systems will allow nuclear physicists to probe properties of the quark-gluon plasma with higher precision than ever before to understand how the interactions between quarks and gluons give rise to the unique, liquid-like behavior of QGP.

    “Our detector employs 100,000 silicon photomultipliers, calorimeter elements built using 3-D printing techniques and a 300 million channel radiation-hard silicon detector that has its sensor and electronics integrated into a monolithic device,” said sPHENIX project director Ed O’Brien.

    Many sPHENIX detector components build on experience gained throughout RHIC operations and draw on expertise throughout the nuclear and particle physics communities, including running experiments at Europe’s Large Hadron Collider.

    “These technologies were barely on the drawing board when RHIC began operations over 20 years ago,” O’Brien said. “Now they are a reality in sPHENIX.”

    “We’ve pulled together the field’s most sophisticated technologies and pushed them to new limits to design a detector unlike any that have come before,” said Brookhaven Lab physicist and sPHENIX co-spokesperson David Morrison. “It’s really a technological marvel.”

    sPHENIX will generate an enormous amount of data to realize its science goals. Developing the capabilities to collect, store, share, and analyze that data will help push the limits of data handling in ways that could benefit other fields including climate modeling, public health, and any fields that require the analysis of huge datasets.

    Learn more about sPHENIX and watch as some of its components came together.

    sPHENIX was built by an international collaboration of physicists, engineers, and technicians from 80 universities and labs from 14 countries—close to 400 collaborators overall, including students. Students, for example, joined efforts to assemble and test complex detector subsystems, studied cost-effective materials for high-speed electronics, and contributed to accelerator improvements that will increase collision rates at RHIC.

    “These hands-on educational experiences are providing valuable training for our nation’s future scientists, technicians, and engineers,” said sPHENIX co-spokesperson Gunther Roland, a physicist at the Massachusetts Institute of Technology. “Their expertise and future work may impact fields well beyond fundamental physics that rely on similar sophisticated electronics and cutting-edge technologies—including medical imaging and national security.”

    sPHENIX and operations at RHIC are funded by the DOE Office of Science (NP). 

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov

    Follow @BrookhavenLab on Twitter or find us on Facebook

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  • sPHENIX Assembly Update: Magnet Mapped, Detectors Prepared

    sPHENIX Assembly Update: Magnet Mapped, Detectors Prepared

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    Newswise — Physicists, engineers, and technicians at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory are rounding out the year with key developments to a house-sized particle detector that will begin capturing collision snapshots for the first time next spring.

    The state-of-the-art, three-story, 1,000-ton detector—known as sPHENIX—will precisely track particles streaming from collisions at the Relativistic Heavy Ion Collider (RHIC), a DOE Office of Science user facility for nuclear physics research. It’s an ongoing makeover of the PHENIX experiment, which took data at RHIC from 2000 until 2016. The upgraded, state-of-the-art sPHENIX will enable scientists to better understand the properties of quark-gluon plasma (QGP) —a soup of subatomic particles that are the inner building blocks of protons and neutrons. Scientists want to measure those particles to learn more about how those building blocks interact to form the visible matter that makes up our world.

    With the recent completion of essential particle-tracking components and a project to map the magnetic field of a superconducting electromagnet at the detector’s core, sPHENIX crews are gearing up for final installations.

    “There’s this whole choreography of a very intricate process of how these remaining pieces go together that’s going to play out in the next months and have us in shape to take data in the spring,” said Brookhaven Lab nuclear physicist and sPHENIX co-spokesperson David Morrison.

    CERN crew maps magnetic field

    A central component of sPHENIX is a 20-ton cylindrical superconducting solenoid magnet. It was once the centerpiece of an experiment called BaBar at SLAC National Accelerator Laboratory in California. Crews transported it across the country in 2015, tested it at low-field in 2016 and high-field in 2018, and carefully installed it at sPHENIX last year.

    The magnet generates a precise and uniform magnetic field—1.4 Tesla, or about as strong as the magnet used for magnetic resonance imaging (MRI) scans. The powerful field will bend the trajectories of charged particles that are among the “debris” produced when nuclei collide at RHIC.

    Remaining detectors soon to be layered inside the magnet’s drum will measure very accurately the position of the particles that stream out of these nuclear smashups, from which other properties can be obtained. Scientists seek to “connect the dots” of those measurements to discern very small differences among three kinds of “parent” particles called upsilons. The upsilon data is only one of numerous studies with sPHENIX at RHIC which will reveal clues about how QGP transitions from a hot soup of quarks and gluons to matter as we know it.

    But before these final tracking components can be installed, the sPHENIX crew sought to map the solenoid’s magnetic field.

    “Once you fill up the middle of the magnet, you can’t place a mapping machine inside,” said Brookhaven physicist Kin Yip.

    A team from CERN, Europe’s particle physics laboratory, came to Brookhaven in November to tackle the precision task.

    “CERN’s detector technologies group are the world experts in magnet mapping,” Yip said.

    The CERN team used the same mapping machine they’d previously used to map the magnet that forms the backbone of the ATLAS experiment at CERN’s Large Hadron Collider.

    The mapping machine, shipped from Geneva, Switzerland, fit into precision rails inside of the magnet’s drum, where some panels of the sPHENIX electromagnetic calorimeter (EMCal)—which will measure different types of charged and uncharged particles in RHIC collisions—had not yet been installed. The cryogenic group from Brookhaven’s Collider-Accelerator Department used liquid helium to cool the solenoid’s superconducting cables to 4.6 degrees Kelvin (-451.4 degrees Fahrenheit)—the temperature needed to generate the magnetic field. Two arms run by air-powered motors rotated like propellers to measure the magnetic field as crews stepped the machine along points from one end of the cylindrical magnet to the other. (Technicians installed the final EMCal segments soon after the mapping project ended.)

    “We thank Brookhaven Lab and in particular the people at sPHENIX for tasking us with the mapping of the sPHENIX solenoid,” said Nicola Pacifico of CERN’s mapping group, which included Francois Garnier, Raphael Dumps, Pritindra Bhowmick. “Every mapping campaign is an R&D exercise on its own, presenting its specific challenges. We enjoyed the support of a very competent team on site, which allowed us to complete the mapping in a timely manner. We wish sPHENIX and its team full success in its physics programme, and au revoir until the next mapping at Brookhaven Lab!”

    sPHENIX scientists had been using a calculated map of the solenoid’s magnetic field to run RHIC collision simulations. The new precision measurements will increase the accuracy of deciphering data from the complex experiment once it’s up and running.

    “In general, in experimental physics, more information is better than less information,” said John Haggerty, a Brookhaven physicist who led the acquisition of the magnet in the early days of sPHENIX. “We can only calculate what we think we built, not what we may have inadvertently built. Now, we have the best possible map.”

    Key sub-detector arrives at Brookhaven

    The massive magnet isn’t the only major detector component that made a cross-country trek to sPHENIX. Pieces of a pixel-based vertex detector known as MVTX, were built at CERN, then shipped to DOE’s Lawrence Berkeley National Laboratory (LBNL) in California for expert assembly, before arriving safely at Brookhaven in October. The detector was shipped in two halves for the 3,000-mile cross-country road trip. Crews used a truck with special suspension and took care to consider a safe route and weather conditions.

    The MVTX is one of three components that will work together to measure the position to determine the momentum of all charged particles emerging from RHIC’s collisions. (The other two are an Intermediate Silicon Strip Tracker (INTT, see below) and a Time Projection Chamber (TPC) being built at Stony Brook University.

    The MVTX, which will sit within the sPHENIX magnet’s central core, offers a very precise answer to the question: did a particle come exactly from the collision or even a fraction of a hair’s width away? It turns out that differences of such tiny distances can make a big difference.

    “Thousands of particles come out of our collisions,” Morrison explained. “Some of those particles decay, turning into other types of particles almost right away—making it maybe 50 microns, about the thickness of a strand of hair. MVTX tells us extremely precisely where particles came from, with a precision of about five microns, so we know if the particle was created in the collision itself or is a product of such as decay.”

    The part of MVTX that actually makes measurements is compact—about a foot long, 3.5 inches in diameter, and weighing in at about 3 ounces. All together, MVTX is made up of three overlapping layers of silicon sensors, which line two halves of a carbon fiber tube. At one end, the tube widens like the bell of a trumpet to fit lots of cables and fibers that power and readout the detector.

     “In this compact package there are 300 million channels, elements that can say ‘I saw something,’” said Edward O’Brien, the sPHENIX project director. “If we think of those channels as pixels, MVTX has a factor of 40 more pixels than your high-definition TV crammed into a space that’s over 20 times smaller.”

    Before installing the pixel-based detector early next year, sPHENIX engineers and technicians will practice placing a mockup of this delicate component around the experiment’s beam pipe., They’ll have only a tiny amount of clearance—about a millimeter—to slide the device into its final position after the other detector components are installed. “It’s like playing the game ‘Operation’ in reverse,” Morrison said. When it comes time to put that final piece in place, he says, the sPHENIX crew will be ready.

    Tracking super-fast, overlapping events

    Meanwhile the team is making progress on those other particle-tracking components.

    With a response time of 60 nanoseconds—60 billionths of second—the INTT will be key in capturing continuous snapshots of 15,000 particle collisions per second, more than three times faster than the former PHENIX detector.

    The INTT takes measurements in the space where MVTX and TPC do not, allowing physicists to reconstruct a complete particle track. It’s super-fast response time enables it to distinguish which tracks come from overlapping events when collisions are piling up.

    The sub-detector was completed in mid-September by an international collaboration that included technicians, engineers, postdocs, and scientists from Japan, Taiwan, and the U.S. The project is funded primarily through the RIKEN BNL Research Center (RBRC) with additional U.S and international contributions.

    The INTT consists of four layers of overlapping silicon strips that form a semiconductor particle detector based on ionizing radiation detection. The layers sit in two halves of a 10-foot-long cylinder. Bringing the two-halves of the detector together for testing, and soon installation, was a tricky task with many moving parts.

    “It’s like flying a 747 airplane,” said Rachid Nouicer, a Brookhaven Lab nuclear physicist, RBRC senior visiting scientist, Stony Brook University adjunct professor, and co-manager of the INTT detector construction.

    To ensure a “safe landing” the INTT assembly team used a machine with two “claws” that picked up each half and pressed them together while technicians tightened screws and knobs around the device. They had to be careful to prevent any cracks in the silicon strips. They also needed to ensure there are no gaps between overlapping silicon layers so the detector can receive all particle signals when its operational.

    “Physics is always moving towards precision and detector technology has to keep up with it—we want detectors to be faster, more precise,” Nouicer said. “It’s a great accomplishment to see all the INTT detector’s channels working. Now, we want to do physics with it.”

    As work progresses on the TPC, a gas tracking detector, at Stony Brook, the time for physics is fast approaching. Stay tuned for another update on that detector component.

    “We’re right at the end of detector component construction. O’Brien said. “We’re done within errors. The challenge ahead is completing installation in the next few months”

    “As you can see, the construction and assembly of these complex detector components is a major international effort,” said sPHENIX co-spokesperson Gunther Roland, a physicist at the Massachusetts Institute of Technology. “This work brings together so many great physicists from all over the world—80 universities and labs from 14 countries and close to 400 collaborators —to make the vision for this detector and the science it will enable a reality.”

    The upgrade and operations at RHIC are funded by the DOE Office of Science (NP).

     Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, please visit science.energy.gov.

    Follow @BrookhavenLab on Twitter or find us on Facebook.

     

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  • A Radical New Approach in Synthetic Chemistry

    A Radical New Approach in Synthetic Chemistry

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    Newswise — UPTON, NY—Scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory helped measure how unpaired electrons in atoms at one end of a molecule can drive chemical reactivity on the molecule’s opposite side. As described in a paper recently published in the Journal of the American Chemical Society, this work, done in collaboration with Princeton University, shows how molecules containing these so-called free radicals could be used in a whole new class of reactions.

    “Most reactions involving free radicals take place at the site of the unpaired electron,” explained Brookhaven Lab chemist Matthew Bird, one of the co-corresponding authors on the paper. The Princeton team had become experts in using free radicals for a range of synthetic applications, such as polymer upcycling. But they’ve wondered whether free radicals might influence reactivity on other parts of the molecule as well, by pulling electrons away from those more distant locations.

    “Our measurements show that these radicals can exert powerful ‘electron-withdrawing’ effects that make other parts of the molecule more reactive,” Bird said.

    The Princeton team demonstrated how that long-distance pull can overcome energy barriers and bring together otherwise unreactive molecules, potentially leading to a new approach to organic molecule synthesis.

    Combining capabilities

    The research relied on the combined resources of a Princeton-led DOE Energy Frontier Research Center (EFRC) focused on Bio-Inspired Light Escalated Chemistry (BioLEC). The collaboration brings together leading synthetic chemists with groups having advanced spectroscopic techniques for studying reactions. Its funding was recently renewed for another four years.

    Robert Knowles, who led Princeton’s role in this research, said, “This project is an example of how BioLEC’s combined expertise enabled the team to quantify an important physical property of these radical species, that in turn allowed us to design the resulting synthetic methodology.”

    The Brookhaven team’s major contribution is a technique called pulse radiolysis—available only at Brookhaven and one other location in the U.S.

    “We use the Laser Electron Accelerator Facility (LEAF)—part of the Accelerator Center for Energy Research (ACER) in Brookhaven’s Chemistry Division—to generate intense high-energy electron pulses,” Bird explained. “These pulses allow us to add or subtract electrons from molecules to make reactive species that might be difficult to make using other techniques, including short-lived reaction intermediates. With this technique, we can step into one part of a reaction and monitor what happens.”

    For the current study, the team used pulse radiolysis to generate molecules with oxygen-centered radicals, and then measured the “electron-withdrawing” effects on the other side of the molecule. They measured the electron pull by tracking how much the oxygen at the opposite side attracts protons, positively charged ions sloshing around in solution. The stronger the pull from the radical, the more acidic the solution has to be for protons to bind to the molecule, Bird explained.

    The Brookhaven scientists found the acidity had to be high to enable proton capture, meaning the oxygen radical was a very strong electron withdrawing group. That was good news for the Princeton team. They then demonstrated that it’s possible to exploit the “electron-withdrawing” effect of oxygen radicals by making parts of molecules that are generally inert more chemically reactive.

    “The oxygen radical induces a transient ‘polarity reversal’ within the molecule—causing electrons that normally want to remain on that distant side to move toward the radical to make the ‘far’ side more reactive,” Bird explained.

    These findings enabled a novel substitution reaction on phenol based starting materials to make more complex phenol products.

    “This is a great example of how our technique of pulse radiolysis can be applied to cutting-edge science problems,” said Bird. “We were delighted to host an excellent graduate student, Nick Shin, from the Knowles group for this collaboration. We look forward to more collaborative projects in this second phase of BioLEC and seeing what new problems we can explore using pulse radiolysis.”

    Brookhaven Lab’s role in this work and the EFRC at Princeton were funded by the DOE Office of Science (BES). Princeton received additional funding for the synthesis work from the National Institutes of Health.

    Brookhaven National Laboratory is supported by the Office of Science of the U.S. Department of Energy. The Office of Science is the single largest supporter of basic research in the physical sciences in the United States and is working to address some of the most pressing challenges of our time. For more information, visit science.energy.gov.

    Follow @BrookhavenLab on Twitter or find us on Facebook.

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