Francis Alexander Named Deputy Director of Brookhaven Lab's Computational Science Initiative
Brookhaven National LaboratoryAlexander brings extensive management and leadership experience in computational science research to the position.
Alexander brings extensive management and leadership experience in computational science research to the position.
A collaborative study involving Brookhaven, MIT, the Harvard-Smithsonian Center for Astrophysics, and the National Museum in Rio de Janeiro suggests the gas cloud from which our solar system formed lasted about 4 million years.
Theorists and scientists conducting experiments that recreate matter as it existed in the very early universe are gathered in Chicago this week to present and discuss their latest results.
Information scientist Line Pouchard just joined Brookhaven Lab’s Center for Data-Driven Discovery, where she will help scientists discover, integrate, and re-use data.
From advances in accelerators and experiments exploring the building blocks of matter and making medical isotopes to new revelations about superconductors, nanomaterials, and biofuels, 2016 was a year of accomplishment at the U.S. Department of Energy’s Brookhaven National Laboratory. Here are our Top-10 highlights.
Thanks to a new development in nuclear physics theory, scientists exploring expanding fireballs that mimic the early universe have new signs to look for as they map out the transition from primordial plasma to matter as we know it. The theory work, described in a paper recently published as an Editor's Suggestion in Physical Review Letters (PRL), identifies key patterns that would be proof of the existence of a so-called “critical point” in the transition among different phases of nuclear matter.
Scientists have developed a way to efficiently create scalable, multilayer, multi-patterned nanoscale structures with unprecedented complexity. The method introduces a significant leap in material intelligence, because each self-assembled layer guides the configuration of additional layers.
Using a new laser-driven "stop-action" technique for studying complex electron interactions under dynamic conditions, scientists have identified an unusual form of energy loss in a material related to superconductors.
Brookhaven senior physicist and group leader Yimei Zhu uses electron microscopy to understand the structure and properties of functional materials. His work has led to major contributions in condensed matter physics, materials science, and chemistry.
New catalysts containing platinum and lead could improve the efficiency of fuel cells—a promising technology for producing clean energy.
Peter Takacs, a physicist in the Instrumentation Division at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory, has been named a Fellow of the Optical Society (OSA).
To help tackle the challenge of finding effective, inexpensive catalysts for fuel cells, scientists at Brookhaven Lab have produced dynamic, 3D images that reveal how catalytic nanoparticles evolve as they are processed.
Raju Venugopalan, a senior physicist at the U.S. Department of Energy's Brookhaven National Laboratory and an adjunct professor at Stony Brook University, has been awarded a Humboldt Research Award for his remarkable achievements in theoretical nuclear physics.
UPTON, NY—Many people picture electrical conductivity as the flow of charged particles (mainly electrons) without really thinking about the atomic structure of the material through which those charges are moving. But scientists who study "strongly correlated electron" materials such as high-temperature superconductors and those with strong responses to magnetism know that picture is far too simplistic.
Brookhaven Lab purchased a new institutional cluster, is building a new computing architecture test bed, and joined/is in the process of joining computing standardization groups. These efforts, part of Brookhaven's Computational Science Initiative, will support data-driven scientific discoveries.
Brookhaven Lab is leading one of the 35 software development projects (SOLLVE) and partnering on one of the four co-design centers (CODAR) recently funded by DOE’s Exascale Computing Project. SOLLVE will focus on OpenMP functionality for exascale computing; CODAR will concentrate on online data analysis and reduction at the exascale.
The award recognizes the novel method he developed nearly 20 years ago to mathematically characterize how the distribution of tiny atmospheric particles called aerosols evolves over time.
Innovations in microscopy, catalysis, and nanomaterials are among the 100 technologies and services of the past year selected by R&D Magazine to receive awards.
Alice Cialella leads a department whose research is focused on aerosol chemistry and microphysics, aerosol-related infrastructure, climate and process modeling, cloud processes, data management and software engineering, terrestrial ecosystems, meteorological services, and tracer technologies.
Patches of chain-like molecules placed across nanoscale particles can radically transform the optical, electronic, and magnetic properties of particle-based materials. Now, scientists have used cutting-edge electron tomography techniques—a process of 3D reconstructive imaging—to pinpoint the structure and composition of the polymer nano-patches.
UPTON, NY — Sally Dawson, a theoretical physicist at the U.S. Department of Energy's Brookhaven National Laboratory, has been named a recipient of the 2017 J.J. Sakurai Prize for Theoretical Particle Physics. The award, given by the American Physical Society (APS), recognizes Dawson and her three co-authors of The Higgs Hunter's Guide, a seminal book first published in 1989 on the physics of Higgs bosons—fundamental particles predicted by the accepted theory of particle physics as essential to generating the mass of fundamental particles, and discovered in experiments at the Large Hadron Collider (LHC) in 2012.
Understanding how tiny particles emitted by cars and factories affect Earth's climate requires accurate climate modeling and the ability to quantify the effects of these pollutant particles vs. particles naturally present in the atmosphere. One large uncertainty is what Earth was like before these industrial-era emissions began. In a paper just published in Nature, scientists collaborating on the GoAmazon study describe how they tracked particles in the largely pristine atmosphere over the Amazon rainforest, which has given them a way to effectively turn back the clock a few hundred years.
Understanding the electronic ordering in copper-oxide superconductors could help scientists find the “recipe” for raising the temperature at which current can flow through these materials without energy loss.
Tomoyasu Mani is being recognized for his work at Brookhaven Lab to understand the physical processes occurring in organic materials used to harness solar energy.
Reports of the non-existence of the so-called “sterile” neutrino are premature, say scientists at the U.S. Department of Energy’s Brookhaven National Laboratory—even as they release results from two experiments that further limit the places this elusive particle may be hiding. These results, described in three papers published in Physical Review Letters (PRL) by scientists working on the Daya Bay Neutrino Experiment in China and the Main Injector Neutrino Oscillation Search (MINOS) at Fermi National Accelerator Laboratory—like results recently announced by another neutrino experiment known as IceCube—greatly narrow the “phase space” where scientists must hunt.
By bombarding the material with low-energy protons, scientists doubled the amount of current the material could carry without resistance, while raising the temperature at which this superconducting state emerges.
Scientists will help develop modeling and simulation applications for next-generation supercomputers to enable advances in nuclear and high-energy physics and chemistry research.
A team of scientists has discovered a phenomenon that could have practical applications in solar cells, rechargeable battery electrodes, and water-splitting devices.
SAN DIEGO, CA – The National Synchrotron Light Source II (NSLS-II) project at the U.S. Department of Energy's (DOE) Brookhaven National Laboratory has been awarded the Project Management Institute's (PMI) prestigious Project of the Year Award. This international award, presented to NSLS-II project staff during PMI's annual meeting in San Diego, CA, on Sept.
A team of scientists studying solar cells made from cadmium telluride, a promising alternative to silicon, has discovered that microscopic "fault lines" within and between crystals of the material act as conductive pathways that ease the flow of electric current. This research-conducted at the University of Connecticut and the U.S. Department of Energy's Brookhaven National Laboratory, and described in the journal Nature Energy-may help explain how a common processing technique turns cadmium telluride into an excellent material for transforming sunlight into electricity, and suggests a strategy for engineering more efficient solar devices that surpass the performance of silicon.
Since 1952, the Department of Energy’s (DOE) Brookhaven National Laboratory has been home to a national resource whose existence is not widely known outside of its customer base: the National Nuclear Data Center (NNDC), a user facility with a research mission. Alejandro Sonzogni, the new director of the NNDC, sees his mission as adapting the NNDC group’s activities to meet the changing needs of the nuclear community and spreading the word about the services the group offers.
For young scientists joining a research project for a summer, every minute of the experience is precious. In addition to reading previous publications and learning the scientific vernacular, many of the students coming to the U.S. Department of Energy's (DOE) Brookhaven National Laboratory for summer research internships must scramble to teach themselves how to code so they can work with their data. Brookhaven's Office of Educational Programs (OEP) created the Scientific Computing 102 course to help students meet this challenge.
Rebecca Siddall is a high school student from Oundle, UK, who spent her summer in Brookhaven Lab’s High School Research Program learning about physics from members of the STAR collaboration at the Relativistic Heavy Ion Collider (RHIC).
An ultra-high-vacuum chamber with temperatures approaching absolute zero—the coldest anything can get—may be the last place you would expect to find gold. But a group of researchers from Stony Brook University (SBU) in collaboration with scientists at the Air Force Research Lab (AFRL) and the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory have just demonstrated that such a desolate place is ideal for producing catalytically active gold nanoparticles.
Five projects from the U.S. Department of Energy's (DOE) Brookhaven National Laboratory have been selected as finalists for the 2016 R&D 100 awards, which honor the top 100 proven technological advances of the past year as determined by a panel selected by R&D Magazine.
Brookhaven physicist Ivan Bozovic and his team have an explanation for why certain materials can conduct electricity without resistance at temperatures well above those required by conventional superconductors.
A team of physicists just received $2.1 million in funding for 2016-2017 from DOE’s Advanced Scientific Computing Research (ASCR) program to enhance a “workload management system” for handling the ever-increasing data demands of two experiments at the Large Hadron Collider and expanding its use as a general workload management service for a Department of Energy supercomputer.
Large Hadron Collider (LHC) performance surpasses expectations; results confirm the Higgs particle, show "bump" appears to be a statistical fluctuation, and offer insight into quark-gluon plasma at high energies complementary to those explored at the Relativistic Heavy Ion Collider (RHIC).
Scientists at Brookhaven National Laboratory have developed a way to direct the self-assembly of multiple molecular patterns within a single material, producing new nanoscale architectures. This is a significant conceptual leap in self-assembly that could change the way we design and manufacture electronics.
A new study just published in Physical Review Letters reveals that a high degree of gluon fluctuation--a kind of flickering rearrangement in the distribution of gluon density within individual protons--could help explain some of the remarkable results at the Relativistic Heavy Ion Collider (RHIC) -- a U.S. Department of Energy Office of Science User Facility for nuclear physics research at DOE's Brookhaven National Laboratory -- and also in nuclear physics experiments at the Large Hadron Collider (LHC) in Europe.
As director, Eric Lançon—a physicist who has played major roles in computing efforts for the Large Hadron Collider in Europe—oversees an integrated computing, data storage, and networking infrastructure.
Imagine, on the streets of the United States, electric vehicles as affordable and convenient as gasoline-powered vehicles. Now imagine that scene taking place in just a few years.
Scientists have captured atomic level snapshots showing how one key enzyme modifies a protein involved in turning genes on or off inside cells. Understanding this process helps explain how complex organisms can arise from a finite number of genes. The research also identifies links between defects in this particular enzyme and certain cancers, potentially pointing to new drug targets.
By engineering a novel enzyme involved in lignin synthesis, scientists at the U.S. Department of Energy's Brookhaven National Laboratory and collaborators have altered the lignin in plant cell walls in a way that increases access to biofuel building blocks without inhibiting plant growth.
Researchers discovered an entirely unexpected atomic arrangement of Gold-144, a molecule-sized nanogold cluster whose structure had been theoretically predicted but never confirmed.
Brookhaven scientists, students, and university partners help build and test key components for a possible future RHIC detector upgrade.
Solenoid passes major test before its second lifetime in a particle detector upgrade at RHIC.
A new collaboration takes aim at understanding how the ultra-hot, ultra-dense plasma that formed our early universe gets its intriguing properties.
Scientists developed two DNA-based nanostructure self-assembly approaches: one allows the same nanoparticles to be connected into a variety of 3D structures; the other facilitates the integration of different nanoparticles and DNA frames into interconnecting modules.
Scientists have found magnetic excitations in a metallic compound whose main source of magnetism is the orbital movement of its electrons. Their discovery challenges conventional wisdom that these excitations are only found in materials whose magnetism is dominated by the spin of its electrons.