Basic Energy Sciences

The Basic Energy Sciences (BES) program supports basic scientific research to lay the foundations for new energy technologies and to advance DOE missions in energy, environment, and national security. BES research emphasizes discovery, design, and understanding of new materials and new chemical, biochemical, and geological processes. The ultimate goal is to better understand the physical world and harness nature to benefit people and society.

Major technological innovations don’t just happen. They typically have their roots in basic research breakthroughs over a period of decades. The BES program supports basic research behind a broad range of energy technologies, spanning energy generation, conversion, transmission, storage, and use. Many major innovations can be traced back to basic research supported by BES over the past 40 years. These include, for example, LED lighting; efficient solar cells; better batteries; stronger, lighter materials for transportation, nuclear power plants, and national defense; and improved production processes for high-value chemicals.

The BES program is one of the nation’s largest sponsors of research in the physical sciences. The program funds basic science at nearly 170 universities, national laboratories, and other research institutions in the U.S.  BES has also built and supports a national network of major shared research facilities based at DOE national laboratories and open to all scientists. These user facilities help form the backbone of the nation’s research infrastructure. Over 16,000 scientists and engineers make use of these facilities each year.

Learn more about the Basic Energy Sciences mission and operations here.

BES By the Numbers, FY 2018

BES Subprograms

Courtesy Shawn M. Kathmann, Pacific Northwest National Laboratory.

Chemical Sciences, Geosciences, and Biosciences (CSGB)

The Chemical Sciences, Geosciences, and Biosciences Division supports basic research on chemical transformations and energy flow. This research provides the groundwork for the development of new and improved processes for the generation, storage, conversion, and use of energy as well as for other applications.

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Materials Sciences and Engineering (MSE)

Materials Sciences and Engineering (MSE)

The Materials Sciences and Engineering Division supports basic research for the discovery and design of new materials with novel properties and functions. This research creates a foundation for the development of new and improved materials for the generation, storage, conversion, and use of energy as well as for other applications.

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Scientific User Facilities (SUF)

Scientific User Facilities (SUF)

The Scientific User Facilities Division supports R&D, planning, construction, and operation of a nationwide suite of major scientific facilities. These user facilities include large x-ray light sources, neutron scattering centers, and research centers for nanoscale science. They provide state-of-the-art instrumentation to create and measure materials and chemical systems. Tens of thousands of scientists from universities, industry, and government laboratories use them each year.

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Reprinted with permission from Baginska, M., et al. 2012. “Autonomic Shutdown of Lithium-Ion Batteries Using Thermoresponsive Microspheres,” Advanced Energy Materials 2(5), 583–90. Copyright 2012 John Wiley and Sons.

Energy Frontier Research Centers (EFRCs)

The Energy Frontier Research Centers bring together teams of scientists to perform basic research with a scope and complexity beyond what is possible for individuals or small groups. These centers foster transformative scientific advances to uncover innovative solutions to difficult problems in the energy sciences..

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Courtesy Kalia, Nakano, Vashishta, and Shimojo, University of Southern California, at the ANL IBM Blue Gene Q supercomputer with 786,432 processors.

Computational Materials and Chemical Sciences (CMS,CCS)

Computational Materials and Chemical Sciences supports teams of researchers performing basic research to develop software and databases for design of new materials and chemical processes. This research takes advantage of DOE’s current supercomputers and develops software for next-generation exascale computing systems.

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Energy Innovation Hubs

Energy Innovation Hubs

The Energy Innovation Hubs mobilize large research teams to overcome major scientific barriers to development of transformative new energy technologies. The two Hubs supported by BES focus on grand challenges in energy: (1) Fuels from Sunlight and (2) Next Generation Batteries and Energy Storage.

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BES Science Highlights

Surrounded by Water
December 14, 2016
Scientists understand the macroscopic behavior of the interaction between water and acid, yet the microscopic behavior and the specific structures
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New Properties Discovered in Atom-Wide Troughs
December 14, 2016
In the world of semiconductors, impurities and defects can be a good thing. They modify the properties of materials such as silicon, and scientists
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Spinning the (X-ray) Light Fantastic
December 14, 2016
At the LCLS, researchers have demonstrated the generation of X-ray pulses with polarization control at photon energies from 280 eV to 1200 eV, by
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Translating Basic Biological Research to Cancer Drug Discovery
December 14, 2016
First-generation BRAF inhibitors vemurafenib (PLX4032) and dabrafenib have demonstrated clinical efficacy in treating metastatic melanoma harboring
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Not Your Typical “Cut Glass Crystal”
December 14, 2016
Using a focused laser beam, researchers demonstrated for the first time that single crystals could be written into a solid glass matrix as dots,
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How to Convince Molecules to Self-Assemble into Precise Hollow Nanotubes
December 14, 2016
The self-assembly of complex molecules containing water-attracting (hydrophilic) and water-repelling (hydrophobic) segments in water is important
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Giving Friction the Slip with New Carbon Films
November 30, 2016
Tribology—the study of friction, wear, and lubrication—is critical to the efficiency and durability of engines and other moving metal
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How to 3D Print on the Nanoscale
November 30, 2016
Precision control of nanometer scale 3D fabrication has been a longstanding research goal. Now, researchers have developed a 3D simulation that
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Lining up for New High-Density Memory Devices
November 30, 2016
Scientists grew a vertically aligned nanocomposites lattice matched on a SrTiO3 (STO) substrate using laser deposition. These micrometer-thick
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DNA + Nanoparticles = Self-Assembled “Diamond”
November 30, 2016
For the first time, scientists devised ordered arrays (superlattices) of nanoparticles, which organize in the same way that carbon atoms do within
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BES Program News

Energy Department to Invest $32 Million in Computer Design of Materials
Researchers to take advantage of DOE’s advanced supercomputers.
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Neutrons Investigate Tomatoes for Insights Into Interplant Chatter
Professors Kathryn and Jonathan Morris from Xavier University are using neutron scattering at the Department of Energy’s (DOE’s) Oak Ridge National Laboratory (ORNL) to observe firsthand how these info-chemicals travel along tiny, pipe-like networks called fungal hyphae. Whether the messages move passively along the outside of those fungal networks or the fungi deliberately locate and absorb info-chemicals for transportation remains unclear.
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New Research Facility Will Serve ORNL's Growing Mission in Computing, Materials R&D
Energy Secretary Rick Perry, Congressman Chuck Fleischmann and lab officials today broke ground on a multipurpose research facility that will provide state-of-the-art laboratory space for expanding scientific activities at the Department of Energy’s Oak Ridge National Laboratory. The new Translational Research Capability, or TRC, will be purpose-built for world-leading research in computing and materials science and will serve to advance the science and engineering of quantum information.
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Simpler & Smaller: A New Synthetic Nanofactory Inspired by Nature
In a new study, researchers at MSU report a new genetically engineered shell, based on natural structures and the principles of protein evolution.
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Using DNA Templates to Harness the Sun's Energy
A team of researchers led by Hao Yan, Yan Liu and Neal Woodbury of the School of Molecular Sciences and Biodesign Center for Molecular Design and Biom
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New Approach for Solving Protein Structures from Tiny Crystals
Using x-rays to reveal the atomic-scale 3-D structures of proteins has led to countless advances in understanding how these molecules work in bacteria, viruses, plants, and humans—and has guided the development of precision drugs to combat diseases such as cancer and AIDS. But many proteins can’t be grown into crystals large enough for their atomic arrangements to be deciphered. To tackle this challenge, scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory and colleagues at Columbia University have developed a new approach for solving protein structures from tiny crystals.
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Contact Information

Basic Energy Sciences
U.S. Department of Energy
SC-22/Germantown Building
1000 Independence Avenue., SW
Washington, DC 20585
P: (301) 903 - 3081
F: (301) 903 - 6594
E: Email Us