National laboratory facilities associated with department of energy

GET {{nrel_developer_url}}/lps/v1/facilities

RESPONSES

status: OK

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An exponential increase in sensitivity means researchers can take data 10,000 times faster, shortening collection times from weeks down to under an hour.","user_facility":false,"labs":[{"uuid":"facca896-d97c-4a47-8260-7e75539f4010","name":"Ames Laboratory","tto_url":"https://www.ameslab.gov/techtransfer","contact_us_email":"ameslps@ameslab.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/facca896-d97c-4a47-8260-7e75539f4010"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/bc3d13da-f2d3-4f3a-b8a4-d059fa66aa25"}},{"uuid":"2aadf320-93c5-4a20-a04c-45768596a663","name":"Materials Preparation Center","alias":"mpc","description":"\u003cp\u003eThe Materials Preparation Center is a one-of-a-kind specialized research center. The MPC prepares, purifies, fabricates, and characterizes research-sized quantities of rare-earth, alkaline-earth, and refractory materials. \u003c/p\u003e\u003cp\u003eEstablished in 1981, the MPC gives scientists at university, industry, and government laboratories access to novel materials and new technologies as they are developed. Each year, the MPC satisfies hundreds of requests for customized materials and services not available from commercial suppliers and that are unmatched in quality anywhere else in the world. The MPC prepares research-quantity, pure metals and alloys in single and polycrystalline forms. The center also develops processing techniques required for special preparations of these metals and alloys and transfers new knowledge about materials-processing equipment.\u003c/p\u003e","user_facility":false,"labs":[{"uuid":"facca896-d97c-4a47-8260-7e75539f4010","name":"Ames Laboratory","tto_url":"https://www.ameslab.gov/techtransfer","contact_us_email":"ameslps@ameslab.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/facca896-d97c-4a47-8260-7e75539f4010"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/2aadf320-93c5-4a20-a04c-45768596a663"}},{"uuid":"1a0bf30e-d02a-4470-b47e-0d724289b52d","name":"Powder Synthesis and Development Facility","alias":"psdf","description":"The Powder Synthesis and Development Facility (PSDF) is dedicated to expanding the use and application of metallic powders through understanding the fundamental characteristics of the powder synthesis process and scientific/metallurgical alloy development.  Primarily powder is produced via close-coupled gas atomization, in our experimental scale (2-5kg) and pilot scale (10-25kg) atomization systems.  \u003cbr\u003eAmes Laboratory PSDF produces custom powder metals which cannot be purchased from commercial suppliers in small and pilot-scale powder batches for external parties through DOE‘s Strategic Partnership Projects.  PSDF also can conduct assessments of powder submitted to the facility.  ","user_facility":false,"labs":[{"uuid":"facca896-d97c-4a47-8260-7e75539f4010","name":"Ames Laboratory","tto_url":"https://www.ameslab.gov/techtransfer","contact_us_email":"ameslps@ameslab.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/facca896-d97c-4a47-8260-7e75539f4010"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/1a0bf30e-d02a-4470-b47e-0d724289b52d"}},{"uuid":"c3642cef-18fb-4725-9272-a94c74ccf215","name":"Sensitive Instrument Facility","alias":"sif","description":"Ames Laboratory's Sensitive Instrument Facility houses state-of-the-art and next-generation materials characterization instruments. This uniquely constructed space enables the study of structure and chemistry at the atomic scale by isolating instruments from thermal, vibration, and electromagnetic interference. Unique details include two-feet thick concrete floors with built-in vibration dampening layers, aluminum-plate lined bays, and fiberglass reinforced concrete for electro-magnetic isolation, and vibration-free heating and ventilation. These features help ensure the instrumentation achieves the highest possible resolution.\n\nThe SIF provides a suite of four electron microscopes, three specialty optical scanning systems, sample preparation spaces, control rooms, and staff support space. Sample preparation facilities include dry and wet laboratories equipped for sample preparation for scanning and transmission electron microscopy.","user_facility":false,"labs":[{"uuid":"facca896-d97c-4a47-8260-7e75539f4010","name":"Ames Laboratory","tto_url":"https://www.ameslab.gov/techtransfer","contact_us_email":"ameslps@ameslab.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/facca896-d97c-4a47-8260-7e75539f4010"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/c3642cef-18fb-4725-9272-a94c74ccf215"}},{"uuid":"448582ae-cbb7-4c79-8e74-f727e5516841","name":"4 Tesla Magnet Facility","alias":"4-tmf","description":"Argonne researchers recently acquired two decommissioned magnets from magnetic resonance imaging (MRI) scanners from hospitals in Minnesota and California that will be used as proving grounds for instruments used in high-energy and nuclear physics experiments.\u003cbr\u003eThe two new magnets have a strength of 4 Tesla, which makes them ideal for benchmarking experiments that test instruments for the g minus 2 (“g-2”) muon experiment currently being assembled at the DOE’s Fermi National Accelerator Laboratory. The Muon g-2 experiment will use Fermilab’s powerful accelerators to explore the interactions of muons, which are short-lived particles, with a strong magnetic field in ​“empty” space.\u003cbr\u003eThe experiment relies on highly precise measurements of the strong magnetic field; the magnets will greatly aid these measurements. The magnet allows for the measurement and calibration of the experiment’s custom-built probes, as it provides not only a strong field but one that is uniform and stable.\u003cbr\u003eIn addition to their strength, these repurposed magnets offer another notable advantage: Originally used as a human patient MRI magnet, they have a wide bore so that large detector components can easily fit inside.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/448582ae-cbb7-4c79-8e74-f727e5516841"}},{"uuid":"d98920cf-8468-4cdc-a290-6dd567405012","name":"Analytical Chemistry Laboratory","alias":"acl","description":"The Analytical Chemistry Laboratory (ACL) provides a broad range of analytical chemistry support services to the scientific and engineering programs at Argonne National Laboratory and specialized analysis for government, academic and industrial organizations, including other national laboratories and QA/QC programs and audits.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/d98920cf-8468-4cdc-a290-6dd567405012"}},{"uuid":"1ab20032-c96d-4651-be0d-9dcefc250c87","name":"Accelerator Development \u0026 Test Facility","alias":"adtf","description":"The accelerator development group operates and maintains a facility for testing accelerator devices. This versatile facility has been used to assemble and perform preliminary acceptance testing on the new ATLAS Radio-Frequency Quadrupole (RFQ) and Electron Beam Ion Source (EBIS).\u003cbr\u003eRecently, the ADTF has been enhanced with a 1630 Koch Systems helium refrigerator, enabling the testing of superconducting devices. The ADTF is now being used for preliminary component testing for a new half-wave resonator cryomodule which will be installed and operated at Fermilab as part of their Proton Improvement Project-II Injector Test and a 1.4 GHz superconducting bunch lengthening system for Argonne’s Advanced Photon Source Upgrade (APS-U) project.\u003cbr\u003eThe ADTF contains: 1630 Koch Systems Refrigerator, 24″ Helium Bath Dewar, 24″ Cryostat, 60″ Cryostat, and a wide range of RF amplifiers.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/1ab20032-c96d-4651-be0d-9dcefc250c87"}},{"uuid":"a6a1b537-6148-4880-88b2-fb73bce79b45","name":"Argonne Leadership Computing Facility","alias":"alcf","description":"The Argonne Leadership Computing Facility (ALCF) is a national scientific user facility that provides supercomputing resources and expertise to the scientific and engineering community to accelerate the pace of discovery and innovation in a broad range of disciplines. ALCF computing resources are 10 to 100 times more powerful than systems typically used for scientific research and are available to researchers from universities, industry, and government agencies. The facility has 25,000 square feet of raised computer floor space and a pair of redundant 20 megavolt amperes electrical feeds from a 90 megawatt substation. The building also features 3,950 tons of cooling capacity (two 1,300-ton chillers for Mira and two 675-ton chillers for air cooling at TCS). The facility welcomes investigators from universities, government agencies, and industry who are prepared to perform breakthrough research in climate, materials, alternative energy sources and energy storage, chemistry, nuclear physics, astrophysics, quantum mechanics, and the gamut of scientific inquiry. There are three pathways to apply for time at the ALCF:\n\u003cul\u003e\u003cli\u003eDirector’s Discretionary Allocation: for high impact science and engineering problems that exceed a company’s internal computing capabilities;\n\u003c/li\u003e\u003cli\u003eASCR Leadership Computing Challenge (ALCC): for larger high-risk, high-payoff simulations that are directly related to the DOE mission (such as advancing energy efficiency);\n\u003c/li\u003e\u003cli\u003eINCITE: Computationally intensive, large-scale research projects pursuing transformational advances in science and engineering through the use of a substantial allocation of computer time and data storage or that require the unique leadership-class architectural infrastructure.\u003c/li\u003e\u003c/ul\u003e","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/a6a1b537-6148-4880-88b2-fb73bce79b45"}},{"uuid":"fa5b14dc-c8e4-4049-9f09-55e9b1ed7396","name":"Argonne Liquid Metal Experiment Facility","alias":"alex","description":"The ALEX facility is designed for research using liquid metal systems and reaches areas as varied as nuclear physics, material science, and nuclear engineering.\u003cbr\u003eThe ALEX facility safely houses alkali metal systems in its two large metal (C-1 and C-2) and one small containment (SC-1). The containment systems connect to a scrubber that can handle potentially large amounts of caustic smoke that might be generated in an alkali metal leak or fire, while confining the smoke inside the containments, and minimizing the effects of such an event to external environments.\u003cbr\u003eThe ALEX staff have expertise in liquid metal technologies based on their long experience with liquid metals. The Argonne National Laboratory Fire Department staff are specially trained to deal with alkali metal fires—a unique, on-site, asset.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/fa5b14dc-c8e4-4049-9f09-55e9b1ed7396"}},{"uuid":"62d74ef4-6a23-49a6-9ab1-5018b3069a24","name":"Advanced Mobility Technology Laboratory","alias":"amtl","description":"Argonne’s Advanced Mobility Technology Laboratory enables researchers to conduct vehicle technology assessment and testing activities that provide data critical to the development and commercialization of next-generation vehicles.\u003cbr\u003eEngineers at Argonne’s Advanced Mobility Technology Laboratory (AMTL, formerly known as the Advanced Powertrain Research Facility) use the facility’s two-wheel drive (2WD) and four-wheel drive (4WD) dynamometers and state-of-the-art instrumentation to reveal important information on performance, fuel economy, energy consumption and emissions output.\u003cbr\u003eThe AMTL is capable of testing conventional, hybrid and advanced electrical propulsion systems using a variety of standard and renewable fuels in a precise laboratory environment.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/62d74ef4-6a23-49a6-9ab1-5018b3069a24"}},{"uuid":"043521c8-0e82-4fcb-9ea0-e39ec0b42d85","name":"Argonne Tandem Linac Accelerator System (ATLAS)","alias":"anl-atlas","description":"ATLAS is a national user facility at Argonne National Laboratory in Argonne, Illinois. The ATLAS facility is a leading facility for nuclear structure research in the United States. It provides a wide range of beams for nuclear reaction and structure research to a large community of users from the US and abroad. The full range of all stable ions can be produced in ECR ion sources, accelerated in the world's first superconducting linear accelerator for ions to energies of 7-17 MeV per nucleon and delivered to one of several target stations. About 20% of the beam-time is used to generate secondary radioactive beams. These beams are used mostly to study nuclear reactions of astrophysical interest and for nuclear structure investigations. Users of ATLAS take advantage of the existing experimental equipment such as, for example, the Canadian Penning Trap (CPT), the Fragment Mass Analyzer (FMA), the magnetic spectrograph and Gammasphere. Beam lines are also available for experiments where Users bring their own equipment. The Physics support group is available to assist the Users in all preparations for their measurements.","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/043521c8-0e82-4fcb-9ea0-e39ec0b42d85"}},{"uuid":"8d531000-0e9e-477a-9eed-dcd2155184e1","name":"US ATLAS Analysis Support Center","alias":"anl-atlas-sc","description":"The High Enegy Physics (HEP) division at Argonne National Laboratory hosts one of the three Analysis Support Centers for the US ATLAS physicists. The center hosts meetings and workshops both specifically for US ATLAS as well as those for the larger ATLAS community. The center also provides Tier3 computing capability for visitors. There are, on the average, 10-12 long term visitors to the center, including University Staff and graduate students.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/8d531000-0e9e-477a-9eed-dcd2155184e1"}},{"uuid":"4e60264d-809f-4d82-9782-e0437c02ec14","name":"Advanced Protein Characterization Facility","alias":"apcf","description":"The Advanced Protein Characterization Facility (APCF) utilizes high-throughput automated methods for bioinformatics, proteomics, molecular and structural biology.\u003cbr\u003eProteins are the molecular machines of all cells, and as with any machine, it is impossible to understand how a protein works without knowing what it looks like — that is, imaging its three-dimensional structure. The Advanced Protein Characterization Facility (APCF) will help us to ​“see” proteins more quickly and with higher proficiency than before. The increase in space emboldens plans to pursue additional programmatic support and new equipment. The APCF also supports Argonne’s ongoing experimental and computational systems work in biology, funded by both the U.S. Department of Energy and the National Institutes of Health.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/4e60264d-809f-4d82-9782-e0437c02ec14"}},{"uuid":"566e4d97-1de5-4172-8781-85a04502a3a0","name":"Advanced Photon Source","alias":"aps","description":"\u003cp\u003eThe Advanced Photon Source (APS) at the U.S. Department of Energy’s Argonne National Laboratory provides ultra-bright, high-energy storage ring-generated x-ray beams for research in almost all scientific disciplines. Today researches have been using the APS to develop the next generation of batteries, improve the durability of 3-D printed alloys, and maximizing the efficiency of chemical processes like electroysis. The knowledge gained from this research is impacting the evolution of combustion engines and microcircuits, aiding in the development of new pharmaceuticals, and pioneering nanotechnologies. The goals of the APS are to:\u003c/p\u003e\u003cul\u003e\u003cli\u003eOperate a highly reliable third-generation synchrotron x-ray radiation source; ​​​​​\n\u003c/li\u003e\u003cli\u003eFoster a productive environment for conducting research;\n\u003c/li\u003e\u003cli\u003eEnhance the capabilities available to users of the APS facility;\n\u003c/li\u003e\u003cli\u003eAssure the safety of the facility users and staff and the environment;\n\u003c/li\u003e\u003cli\u003eMaintain an organization that provides a rewarding environment that fosters professional growth, and;\n\u003c/li\u003e\u003cli\u003eOptimize the scientific and technological contribution to the Department of Energy and society from research carried out at the APS.\u003c/li\u003e\u003c/ul\u003e\u003cp\u003eThe APS welcomes industrial users conducting both proprietary and nonproprietary research and considers requests for work ranging from short-term feasibility studies to long-term research projects, either on a stand-alone basis or in collaboration with facility or academic colleagues.\u003c/p\u003e","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/566e4d97-1de5-4172-8781-85a04502a3a0"}},{"uuid":"9b8882ec-dd2c-4647-ad0e-f431c0791124","name":"Argonne Wakefield Accelerator Facility","alias":"awa","description":"\u003cp\u003eThe Argonne Wakefield particle Accelerator (AWA) Facility is a resource unique to the U.S. Department of Energy. The AWA relies on dielectric two-beam acceleration, a concept that was first demonstrated at Argonne National Laboratory and is now being developed into a practical compact accelerator technology. Industry has historically tapped into these resources to study new materials at the molecular level, and improve efficiency of chemical processes. \u003c/p\u003e\u003cp\u003ePlans to test the main acceleration structures at 200-500 MV/m at the AWA facility are underway. Work at the AWA facility includes the generation of a flexible, gigawatt-scale drive bunch train and the associated diagnostics in the space-charge dominated regime; temporal electron bunch shaping and ring-beam generation both required for high transformer ratio; and emittance preservation issues such as beam break-up control of the drive beam in wakefield structures.\n  \u003c/p\u003e","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/9b8882ec-dd2c-4647-ad0e-f431c0791124"}},{"uuid":"5df29a53-a720-4ad3-aff1-d419859f35fc","name":"Cell Analysis Modeling and Prototyping  Facility","alias":"camp","description":"\u003cp\u003eArgonne's Cell Analysis, Modeling, and Prototyping Facility (CAMP) Facility is a DOE-supported facility that allows battery researchers to manufacture full-size prototype battery electrodes and cells (pouch and 18650 format cells) using pilot-scale semi-automated equipment in a dry room environment. The CAMP Facility designs, fabricates, and characterizes high-quality prototype electrodes and cells based on the latest discoveries involving advanced battery materials. The overall mission of the CAMP Facility is to enable the transition of these new advanced battery materials from research laboratories to industrial production through independent validation and analysis in commercially-relevant cell formats. \u003c/p\u003e\u003cp\u003eThe CAMP Facility is outfitted with semi-automated pilot scale battery production equipment in a dry room capable of maintaining below 100 ppm moisture (with up to six people). This production equipment can produce pouch cells of several different sizes as well as hard can cells (18650s), which are common formats in the battery industry. The CAMP Facility team is an integrated group of researchers that apply their skills in the following areas:\n\u003c/p\u003e\u003cul\u003e\u003cli\u003eMaterials validation;\n\u003c/li\u003e\u003cli\u003eElectrode and cell fabrication;\n\u003c/li\u003e\u003cli\u003eDiagnostic;\n\u003c/li\u003e\u003cli\u003eModeling.\u003c/li\u003e\u003c/ul\u003e\u003cp\u003e\u003c/p\u003e","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/5df29a53-a720-4ad3-aff1-d419859f35fc"}},{"uuid":"f23831d3-cb91-4ae9-ae6e-d8bea9acf923","name":"Center for Nanoscale Materials","alias":"cnm","description":"\u003cp\u003eThe Center for Nanoscale Materials (CNM) at Argonne National Laboratory is a premier user facility providing expertise, instrumentation, and infrastructure for interdisciplinary nanoscience and nanotechnology research. Academic, industrial, and international researchers can access the center through its user program for both nonproprietary and proprietary research. \u003c/p\u003e\u003cp\u003eThe scientific strategy of the CNM is consolidated under the following three cross-cutting and interdependent scientific themes. Collectively, they aim at the discovery and hierarchical integration of materials across different length scales, at the extremes of temporal, spatial, and energy resolutions:\n\n\u003cul\u003e\u003cli\u003eQuantum materials and phenomena;\n\u003c/li\u003e\u003cli\u003eManipulating nanoscale interactions;\n\u003c/li\u003e\u003cli\u003eSynthesis of nano-architectures for energy, information and functionality.\n\u003c/li\u003e\u003c/ul\u003eCNM solicits brief proposals for user-initiated nanoscience and nanotechnology research projects three times per year. Applications are due in March, July, and October.\n\n\u003cbr\u003e\u003c/p\u003e","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/f23831d3-cb91-4ae9-ae6e-d8bea9acf923"}},{"uuid":"3490ca57-9cbf-4911-bb94-bf4d057d951e","name":"Distributed Energy Research Center","alias":"derc","description":"Argonne’s Distributed Energy Research Center (DERC) allows researchers to develop and demonstrate novel technologies to reduce emissions and improve efficiency of prime movers used in Distributed Energy applications, primarily stationary reciprocating engines and small gas turbines. Since the prime movers are stationary, the emphasis is in efficient conversion of energy from gaseous fuels and renewables such as wind to electricity. The breadth of the work ranges from bench-scale testing through demonstrations on commercial units. The emphasis is on applied technology demonstration that often includes design and operation of large-scale facilities based on strategic partnerships with industrial consortia.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/3490ca57-9cbf-4911-bb94-bf4d057d951e"}},{"uuid":"7d586830-001b-4968-80ce-4f8043381e2b","name":"Environmentally Assisted Cracking Laboratory","alias":"eac","description":"The Environmentally Assisted Cracking (EAC) Laboratory uses four autoclave systems to evaluate the resistance of nuclear reactor structural materials environmentally assisted cracking in simulated LWR coolant environments. he system allows for fatigue and stress corrosion cracking testing in aqueous environments at temperatures of up to 350°C and consists of a test frame with a 2-liter autoclave, a hydraulic actuator, load train, and a load cell. The water – representative of a LWR coolant environment – is circulated through the autoclave at pre-set flow rates. The state-of-the-art data acquisition system is based on LabView software.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/7d586830-001b-4968-80ce-4f8043381e2b"}},{"uuid":"855a718b-e404-407a-87ff-15d51ad02ad0","name":"Electrochemical Analysis and Diagnostics Laboratory","alias":"eadl","description":"Argonne’s Electrochemical Analysis and Diagnostics Laboratory’s (EADL) objective is to provide reliable, independent, and unbiased evaluations of battery performance and life. These evaluations serve as progress measures for U.S. Department of Energy (DOE) and U.S. Advanced Battery Consortium (USABC) projects. Argonne has a long history of conducting independent battery performance and life studies for DOE, dating back to the early 1970s. The facility can test everything from small cells for consumer electronics to full-size electrical vehicle batteries. The EADL can test cells and batteries to any profile using custom design hardware and software. Also, it possesses the ability to test over a wide range of temperatures, from well below ambient to well above ambient temperature, using environmental chambers to house the test items (from cells to full-size batteries). Additionally, the facility can conduct \u003e240 concurrent advanced battery studies under operating conditions that simulate electric-vehicle (EV), electric-hybrid vehicle (HEV), utility load-leveling, and standby/uninterruptible power source applications. Each battery is independently defined, controlled and monitored to impose charging regimes and discharge load profiles that simulate the types of dynamic operating conditions found during actual use.","user_facility":true,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/855a718b-e404-407a-87ff-15d51ad02ad0"}},{"uuid":"db27858f-dc19-48fb-853d-8dee4981be66","name":"Electrochemical Discovery Laboratory (EDL)","alias":"ecdl","description":"The Electrochemical Discovery Laboratory (EDL) is managed by the Joint Center for Energy Storage Research (JCESR), an Argonne led Department of Energy Innovation Hub focused on next-generation batteries. At the EDL, scientists synthesize high-quality materials for testing in beyond-lithium-ion batteries and characterize their properties with state-of-the-art analytical techniques.\u003cbr\u003eThese techniques include structural, compositional, and trace analysis probes with the goal of understanding, at atomic and molecular levels, the chemical transformations that occur during battery charging and discharging.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/db27858f-dc19-48fb-853d-8dee4981be66"}},{"uuid":"0c89b324-699b-44ff-9e98-c896a75c5b63","name":"Advanced Electron Paramagnetic Resonance (EPR) Facility","alias":"epr","description":"The Solar Energy Conversion Group has developed and maintains unique, advanced electron paramagnetic resonance (EPR) facilities at Argonne for the analysis of the structure and function of artificial and natural photosynthetic assemblies, catalytically active transition metal complexes, biohybrid complexes, organic photovoltaic materials, and metallo-organic frameworks.\u003cbr\u003eElectron paramagnetic resonance (EPR) spectroscopy is only sensitive to systems containing unpaired electron spins. This makes EPR an indispensable technique for research into the chemical, biochemical and catalytical reactions where these radicals play a vital role. Another related field of application is in photochemistry, where chemical reactions are initiated by light.\u003cbr\u003eAfter light absorption, the first step of transformation involves a charge separation process, which create both a negatively charged electron and a positively charged hole. Both of these posses unpaired spins and can be detected, characterized and followed by EPR. Furthermore, open-shell transition metals which are at the center of many catalytic reactions can also be studied in detail by EPR spectroscopy.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/0c89b324-699b-44ff-9e98-c896a75c5b63"}},{"uuid":"0964d2cd-a775-4660-a317-844b3c00210e","name":"Environmental Sample Preparation and Sequencing Facility","alias":"epspsf","description":"The Environmental Sample Preparation and Sequencing Facility (ESPSF) was originally established in 2007 at Argonne National Laboratory and is housed in Argonne’s Computing, Environment and Life Sciences (CELS) directorate, providing world-class computation power, software, and expertise critical to the acquisition, analysis, and interpretation of the unprecedented volume of genetic information being generated on next generation DNA sequencing platforms. The facility provides resources and services to Argonne and University of Chicago users, and to the broader scientific community (both US and abroad). ESPSF is involved in a wide range of scientific research from the sequencing of metagenomic samples to both 16S and 18S rRNA amplicon sequencing for microbial community analysis, and ITS sequencing for fungal community analysis. The ESPSF team helps users determine the most efficient and cost effective approach to meet their research needs.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/0964d2cd-a775-4660-a317-844b3c00210e"}},{"uuid":"b53bbe7d-4a27-40f1-9dc7-69b29eb2bcc3","name":"Engine Research Facility","alias":"erf","description":"Argonne’s Engine Research Facility allows scientists and engineers to study in-cylinder combustion and emissions under realistic operating conditions. The facility’s engines range in size from automobile- to locomotive-sized, as well as stationary electric power production engines. The facility is used to discover and evaluate new technologies to determine their technical feasibility and commercial viability. In addition, Argonne researchers use the facility’s engines to conduct research on sustainable renewable fuels.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/b53bbe7d-4a27-40f1-9dc7-69b29eb2bcc3"}},{"uuid":"9c1d05cc-0bfc-4520-9e2e-eb305a2280a4","name":"EV-Smart Grid Interoperability Center","alias":"evsgic","description":"Argonne is home to the U.S. Department of Energy’s Electric Vehicle (EV) Smart Grid Interoperability Center. The Center plays a key role in supporting global harmonization of standards and technology for the EV-grid interface, as well as charging interoperability to ensure future electric vehicles and charging stations worldwide work together seamlessly.\u003cbr\u003eArgonne researchers provide support to emerging technology development in grid connectivity, bridging the needs of the EV manufacturers and the utilities. The focus of this research and development effort is in providing practical applications that enhance the market acceptance of plug-in vehicles and the charging infrastructure, including:\u003cbr\u003e- Enabling technology development to support EV-Grid integration,\u003cbr\u003e- Enabling communication to manage vehicle charging loads,\u003cbr\u003e- Reducing the cost of electric vehicle charging infrastructure,\u003cbr\u003e- Enhancing the viability of fast/consumer-friendly charging, and\u003cbr\u003e- Harmonization of global connectivity standards.","user_facility":false,"labs":[{"uuid":"2694f894-8072-490e-b9ef-647eb2643b73","name":"Argonne National Laboratory","tto_url":"http://www.anl.gov/technology/technology-development-and-commercialization","contact_us_email":"amitchell@anl.gov","links":{"self":"https://developer.nrel.gov/api/lps/v1/labs/2694f894-8072-490e-b9ef-647eb2643b73"}}],"links":{"self":"https://developer.nrel.gov/api/lps/v1/facilities/9c1d05cc-0bfc-4520-9e2e-eb305a2280a4"}}]}}