Lawrence Livermore National Laboratory

Lawrence Livermore National Laboratory

Motto	"Science and Technology in the National Interest"
Established	1952 by the University of California
Research type	Nuclear and basic science
Budget	US$1.5 billion
Director	Penrose (Parney) Albright
Staff	6,800
Location	Livermore, California
Campus	320 hectares (1.2 sq mi)
Operating agency	Lawrence Livermore National Security, LLC
Website	www.llnl.gov www.lllnsllc.com

Lawrence Livermore National Laboratory (LLNL) is a Federally Funded Research and Development Center (FFRDC) founded by the University of California in 1952. It is primarily funded by the United States Department of Energy (DOE) and managed and operated by Lawrence Livermore National Security, LLC (LLNS), a partnership of the University of California, Bechtel, Babcock & Wilcox, URS, and Battelle Memorial Institute in affiliation with the Texas A&M University System. On October 1, 2007 LLNS assumed management of LLNL from the University of California, which had exclusively managed and operated the Laboratory since its inception 55 years before. The laboratory was honored in 2012 by having the synthetic chemical element livermorium named after it.

Background

Aerial view of Lawrence Livermore National Laboratory

LLNL is self-described as "a premier research and development institution for science and technology applied to national security."^[1] Its principal responsibility is ensuring the safety, security and reliability of the nation’s nuclear weapons through the application of advanced science, engineering and technology. The Laboratory also applies its special expertise and multidisciplinary capabilities to preventing the proliferation and use of weapons of mass destruction, bolstering homeland security and solving other nationally important problems, including energy and environmental security, basic science and economic competitiveness.

LLNL is home to many unique facilities and a number of the most powerful computer systems in the world, according to the TOP500 list, including Blue Gene/L, the world's fastest computer from 2004 until Los Alamos National Laboratory's IBM Roadrunner supercomputer surpassed it in 2008. On 6/18/2012, LLNL re-took the lead on the latest edition of the list of the world’s Top 500 supercomputers with Sequoia, a 16.32 petaflops system packing more than 1.5 million custom Power cores. It is based on the same IBM BlueGene/Q architecture used in three other top ten systems which also were the most power efficient on the list. Since 1978, LLNL has received a total of 118 R&D 100 Awards, including five in 2007.^[2] The awards are given annually by the editors of R&D Magazine to the most innovative ideas of the year.

The Laboratory is located on a one-square-mile (2.6 km2) site at the eastern edge of Livermore, California. It also operates a 7,000 acres (2,800 ha) remote experimental test site, called Site 300, situated about 15 miles (24 km) southeast of the main Lab site. LLNL has an annual budget of about US$1.5 billion and a staff of roughly 7,000 employees.

Origins

LLNL was established in 1952 as the Lawrence Radiation Laboratory at Livermore as an offshoot of the existing University of California Radiation Laboratory at Berkeley. It was intended to spur innovation and provide competition to the nuclear weapon design laboratory at Los Alamos, New Mexico, home of the Manhattan Project that developed the first atomic weapons. Edward Teller and Ernest O. Lawrence,^[3] director of the Radiation Laboratory at Berkeley, are regarded as the co-founders of the Livermore Laboratory.

The new laboratory was sited at a former Naval Air Base and training station in Livermore, California. The site was already home to several University of California Radiation Laboratory projects that were too large for its location in the hills above the Berkeley campus, including one of the first experiments in the magnetic approach to confined thermonuclear reactions (i.e. fusion).

E.O. Lawrence tapped 32-year-old Herbert York, a former graduate student of his, to run the Livermore Laboratory. Under York, the Lab had four main programs: Project Sherwood (the Magnetic Fusion Program), Project Whitney (the weapons design program), diagnostic weapon experiments (both for the Los Alamos and Livermore laboratories) and a basic physics program. York also saw to it that the new lab embraced the E.O. Lawrence “big science” approach, tackling challenging projects with physicists, chemists, engineers, and computational scientists working together in multidisciplinary teams.

Historically, the Berkeley and Livermore laboratories have had very close relationships on research projects, business operations and staff. The Livermore Lab was established initially as a branch of the Berkeley Laboratory. Both labs are named after E.O. Lawrence, and the Livermore Lab was not officially severed administratively from the Berkeley Lab until the early 1970s. To this day, in official planning documents and records, Lawrence Berkeley National Laboratory is designated as Site 100, Lawrence Livermore National Lab as Site 200, and LLNL's remote test location as Site 300.^[4]

The laboratory became known as the Lawrence Livermore Laboratory in 1971.

On March 14, 2011, the City of Livermore officially expanded the city's boundaries to annex LLNL and move it within the city limits. The unanimous vote by the Livermore City Council expanded Livermore’s southeastern boundaries to cover 15 land parcels covering 1,057 acres (4.28 km²) that comprise the LLNL site. Prior to this, the site was in an unincorporated area of Alameda County. The LLNL campus continues to be owned by the federal government.

Nuclear weapons projects

From its inception, Livermore focused on innovative weapon design concepts; as a result, its first three nuclear tests were unsuccessful. However, the Lab persevered and its subsequent designs proved increasingly successful. In 1957, the Livermore Lab was selected to develop the warhead for the Navy's Polaris missile. This warhead required numerous innovations to fit a nuclear warhead into the relatively small confines of the missile nosecone.^[5]

During the decades of the Cold War, scores of Livermore-designed warheads entered the nation's nuclear stockpile. These were used in missiles ranging in size from the Lance surface-to-surface tactical missile to the megaton-class Spartan antiballistic missile. Over the years, LLNL designed the following warheads: W27 (Regulus cruise missile; 1955; joint with Los Alamos), W38 (Atlas/Titan ICBM; 1959), B41 (B52 bomb; 1957), W45 (Little John/Terrier missiles; 1956), W47 (Polaris SLBM; 1957), W48 (155-mm howitzer; 1957), W55 (submarine rocket; 1959), W56 (Minuteman ICBM; 1960), W58 (Polaris SLBM; 1960), W62 (Minuteman ICBM; 1964), W68 (Poseidon SLBM; 1966), W70 (Lance missile; 1969), W71 (Spartan missile; 1968), W79 (8-in. artillery gun; 1975), W82 (155-mm howitzer; 1978), B83 (modern strategic bomb; 1979), W87 (Peacekeeper/MX ICBM; 1982), and W80 (Tomahawk GLCM; 1978). The W80, W87, and the B83 are the only LLNL designs still in the U.S. nuclear stockpile.^[6][7][8]

With the collapse of the Soviet Union and the end of the Cold War, the United States began a moratorium on nuclear testing and development of new nuclear weapon designs. To sustain existing warheads for the indefinite future, a science-based Stockpile Stewardship Program (SSP) was defined that emphasized the development and application of greatly improved technical capabilities to assess the safety, security, and reliability of existing nuclear warheads without the use of nuclear testing. Confidence in the performance of weapons, without nuclear testing, is maintained through an ongoing process of stockpile surveillance, assessment and certification, and refurbishment or weapon replacement.

With no new designs of nuclear weapons, the warheads in the U.S. stockpile must continue to function far past their original expected lifetimes. As components and materials age, problems can arise. Stockpile Life Extension Programs can extend system lifetimes, but they also can introduce performance uncertainties and require maintenance of outdated technologies and materials. Because there is concern that it will become increasingly difficult to maintain high confidence in the current warheads for the long term, the Department of Energy/National Nuclear Security Administration initiated the Reliable Replacement Warhead (RRW) Program. RRW designs could reduce uncertainties, ease maintenance demands, and enhance safety and security. In March 2007, the LLNL design was chosen for the Reliable Replacement Warhead.^[9] Since that time, however, Congress has not allocated funding for any further development of the RRW.

The Livermore Action Group organized many mass protests, from 1981 to 1984, against nuclear weapons which were being produced by the Lawrence Livermore National Laboratory. Peace activists Ken Nightingale and Eldred Schneider were involved.^[10] On June 22, 1982, more than 1,300 anti-nuclear protesters were arrested in a nonviolent demonstration.^[11] More recently, there has been an annual protest against nuclear weapons research at Lawrence Livermore. In August 2003, 1,000 people protested at Livermore Labs against "new-generation nuclear warheads".^[12] In the 2007 protest, 64 people were arrested.^[13] More than 80 people were arrested in March 2008 while protesting at the gates.^[14]

Plutonium research

LLNL conducts research into the properties and behavior of plutonium to learn how plutonium performs as it ages and how it behaves under high pressure (e.g., with the impact of high explosives). Plutonium has seven temperature-dependent solid allotropes. Each possesses a different density and crystal structure. Alloys of plutonium are even more complex; multiple phases can be present in a sample at any given time. Experiments are being conducted at LLNL and elsewhere to measure the structural, electrical and chemical properties of plutonium and its alloys and to determine how these materials change over time. Such measurements will enable scientists to better model and predict plutonium's long-term behavior in the aging stockpile.^[15]

The Lab’s plutonium research is conducted in a specially designed, ultra-safe, and highly secure facility called the SuperBlock. Work with highly enriched uranium is also conducted here. In March 2008, the National Nuclear Security Administration (NNSA) presented its preferred alternative for the transformation of the nation’s nuclear weapons complex. Under this plan, LLNL would be a center of excellence for nuclear design and engineering, a center of excellence for high explosive research and development, and a science magnet in high-energy-density (i.e., laser) physics. In addition, most of its special nuclear material would be removed and consolidated at a more central, yet-to-be-named site.^[16]

On September 30, 2009, the NNSA announced that about two thirds of the special nuclear material (e.g., plutonium) at LLNL requiring the highest level of security protection had been removed from LLNL. The move was part of NNSA's efforts initiated in October 2006 to consolidate special nuclear material at five sites by 2012, with significantly reduced square footage at those sites by 2017. The federally mandated project intends to improve security and reduce security costs, and is part of NNSA's overall effort to transform the Cold War era "nuclear weapons" enterprise into a 21st century "nuclear security" enterprise. The original date to remove all high-security nuclear material from LLNL, based on equipment capability and capacity, was 2014. NNSA and LLNL developed a timeline to remove this material as early as possible, accelerating the target completion date to 2012.^[17]

Global security program

The Lab’s work in global security aims to reduce and mitigate the dangers posed by the spread or use of weapons of mass destruction and by threats to energy and environmental security. Livermore has been working on global security and homeland security for decades, predating both the collapse of the Soviet Union in 1991 and the September 11, 2001, terrorist attacks. LLNL staff have been heavily involved in the cooperative nonproliferation programs with Russia to secure at-risk weapons materials and assist former weapons workers in developing peaceful applications and self-sustaining job opportunities for their expertise and technologies.^[18][19] In the mid-1990s, Lab scientists began efforts to devise improved biodetection capabilities, leading to miniaturized and autonomous instruments that can detect biothreat agents in a few minutes instead of the days to weeks previously required for DNA analysis.^[20][21]

Today, Livermore researchers address the full spectrum of threats – radiological/nuclear, chemical, biological, explosives, and cyber. They combine physical and life sciences, engineering, computations, and analysis to develop technologies that solve real-world problems. Activities are grouped into five programs:

• Nonproliferation. Preventing the spread of materials, technology and expertise related to weapons of mass destruction (WMD) and detecting WMD proliferation activities worldwide.^[22]
• Domestic security: Anticipating, innovating and delivering technological solutions to prevent and mitigate devastating high-leverage attacks on U.S. soil.^{[23][24][25][26]}
• Defense: Developing and demonstrating new concepts and capabilities to help the Department of Defense prevent and deter harm to the nation, its citizens and its military forces.^[27][28]
• Intelligence: Working at the intersection of science, technology and analysis to provide insight into the threats to national security posed by foreign entities.^[29]
• Energy and environmental security: Furnishing scientific understanding and technological expertise to devise energy and environmental solutions at global, regional and local scales.^[30][31]

Other programs

LLNL supports capabilities in a broad range of scientific and technical disciplines, applying current capabilities to existing programs and developing new science and technologies to meet future national needs.

• The LLNL chemistry, materials, and life science research focuses on chemical engineering, nuclear chemistry, materials science, and biology and bio-nanotechnology.
• Physics thrust areas include condensed matter and high-pressure physics, optical science and high energy density physics, medical physics and biophysics, and nuclear particle and accelerator physics.
• In the area of energy and environmental science, Livermore’s emphasis is on carbon and climate, energy, water and the environment, and the national nuclear waste repository.
• The LLNL engineering activities include micro- and nanotechnology, lasers and optics, biotechnology, precision engineering, nondestructive characterization, modeling and simulation, systems and decision science, and sensors, imaging and communications.
• The LLNL is very strong in computer science, with thrust areas in computing applications and research, integrated computing and communications systems, and cyber security.

Lawrence Livermore National Laboratory has worked out several energy technologies in the field of coal gasification, shale oil extraction, geothermal energy, advanced battery research, solar energy, and fusion energy. Main oil shale processing technologies worked out by the Lawrence Livermore National Laboratory are LLNL HRS (hot-recycled-solid), LLNL RISE (in situ extraction technology) and LLNL radiofrequency technologies.^[32]

Key accomplishments

Over its 60-year history, Lawrence Livermore has made many scientific and technological achievements, including:^[33]

• Critical contributions to the U.S. nuclear deterrence through the design of nuclear weapons to meet military requirements and, since the mid-1990s, through the Stockpile Stewardship Program, by which the safety and reliability of the enduring stockpile is ensured without underground nuclear testing.
• Design, construction, and operation of a series of ever larger, more powerful, and more capable laser systems, culminating in the 192-beam National Ignition Facility (NIF), completed in 2009.
• Advances in particle accelerator and fusion technology, including magnetic fusion, Free-electron lasers, accelerator mass spectrometry, and inertial confinement fusion.
• Breakthroughs in high-performance computing, including the development of novel concepts for massively parallel computing and the design and application of computers that can carry out hundreds of trillions of operations per second.
• Development of technologies and systems for detecting nuclear, radiological, chemical, biological, and explosive threats to prevent and mitigate WMD proliferation and terrorism.
• Development of extreme ultraviolet lithography (EUVL) for fabricating next-generation computer chips.
• First-ever detection of massive compact halo objects (MACHOs), a suspected but previously undetected component of dark matter.
• Advances in genomics, biotechnology, and biodetection, including major contributions to the complete sequencing of the human genome though the Joint Genome Institute and the development of rapid PCR (polymerase chain reaction) technology that lies at the heart of today’s most advanced DNA detection instruments.
• Development and operation of the National Atmospheric Release Advisory Center (NARAC), which provides real-time, multi-scale (global, regional, local, urban) modeling of hazardous materials released into the atmosphere.
• Development of highest resolution global climate models and contributions to the International Panel on Climate Change which, together with former vice president Al Gore, was awarded the 2007 Nobel Peace Prize.
• Co-discoverers of new superheavy elements 113, 114, 115, 116, 117, and 118.
• Invention of new healthcare technologies, including a microelectrode array for construction of an artificial retina, a miniature glucose sensor for the treatment of diabetes, and a compact proton therapy system for radiation therapy.

On July 17, 2009 LLNL announced that the Laboratory had captured eight R&D 100 Awards – more than it had ever received in the annual competition. The previous LLNL record of seven awards was reached five times – in 1987, 1988, 1997, 1998 and 2006.

Also known as the “Oscars of invention”, the awards are given each year for the development of cutting-edge scientific and engineering technologies with commercial potential.

The awards raises LLNL’s total to 129 since 1978. The winning technologies were:

• GeMini Spectrometer
• Artificial Retina — Restoring Sight to the Blind
• The ROSE compiler framework
• The Babel Middleware
• The FemtoScope: A Time Microscope
• ROSE: Making Compiler Technology Accessible to all Programmers
• Land Mine Locator: Eradicating the Aftermath of War
• Laser Beam Centering and Pointing System
• Spectral Sentry — Protecting High-Intensity Lasers from Bandwidth-Related Damage
• Precision Robotic Assembly Machine — for Building Nuclear Fusion Ignition Targets

Unique facilities

• Biosecurity and Nanoscience Laboratory. Researchers apply advances in nanoscience to develop novel technologies for the detection, identification, and characterization of harmful biological pathogens (viruses, spores, and bacteria) and chemical toxins.
• Center for Accelerator Mass Spectrometry: LLNL’s Center for Accelerator Mass Spectrometry (CAMS) develops and applies a wide range of isotopic and ion-beam analytical tools used in basic research and technology development, addressing a spectrum of scientific needs important to the Laboratory, the university community, and the nation. CAMS is the world’s most versatile and productive accelerator mass spectrometry facility, performing more than 25,000 AMS measurement operations per year.
• High Explosives Applications Facility and Energetic Materials Center: At HEAF, teams of scientists, engineers, and technicians address nearly all aspects of high explosives: research, development and testing, material characterization, and performance and safety tests. HEAF activities support the Laboratory’s Energetic Materials Center, a national resource for research and development of explosives, pyrotechnics, and propellants.

• National Atmospheric Release Advisory Center: NARAC is a national support and resource center for planning, real-time assessment, emergency response, and detailed studies of incidents involving a wide variety of hazards, including nuclear, radiological, chemical, biological, and natural atmospheric emissions.

• National Ignition Facility: This 192-beam, stadium-size laser system will be used to compress fusion targets to conditions required for thermonuclear burn. Experiments at NIF will study physical processes at conditions that exist only in the interior of stars and in exploding nuclear weapons (see National Ignition Facility and photon science).

• Superblock: This unique high-security facility houses modern equipment for research and engineering testing of nuclear materials and is the place where plutonium expertise is developed, nurtured, and applied. Research on highly enriched uranium also is performed here.
• Terascale Simulation Facility: LLNL’s Terascale Simulation Facility houses one of the world’s most powerful computers, Blue Gene/L. Blue Gene/L occupied the No. 1 position on the Top500 list in June 2007;^[34] the current system achieves a Linpack benchmark performance of 478.2 TFlop/s (teraflops, or trillions of calculations per second). A 20 PFlop/s (petaflops, or quadrillions of calculations per second) system named Sequoia is scheduled to be sited in the TSF machine room in late 2011 and be fully operational in 2012. Another Blue Gene class machine, Dawn, has already been installed to act as a developmental testbed for multi-petaflop computing.^[35]

• Titan Laser: Titan is a combined nanosecond-long pulse and ultrashort-pulse (subpicosecond) laser, with hundreds of joules of energy in each beam. This petawatt-class laser is used for a range of high-energy density physics experiments, including the science of fast ignition for inertial confinement fusion energy.

Largest computers

Throughout its history, LLNL has been a leader in computers and scientific computing. Even before the Livermore Lab opened its doors, E.O. Lawrence and Edward Teller recognized the importance of computing and the potential of computational simulation. Their purchase of one of the first UNIVAC computers, set the precedent for LLNL’s history of acquiring and exploiting the fastest and most capable supercomputers in the world. A succession of increasingly powerful and fast computers have been used at the Lab over the years:

• 1953 Remington-Rand UNIVAC 1 (Universal Automatic Computer)
• 1954 IBM 701
• 1956 IBM 704
• 1958 IBM 709
• 1960 IBM 7090
• 1960 Remington-Rand LARC (Livermore Advanced Research Computer)
• 1961 IBM 7030 (Stretch)
• 1963 IBM 7094
• 1963 CDC 1604
• 1963 CDC 3600
• 1964 CDC 6600
• 1969 CDC 7600
• 1974 CDC STAR 100
• 1978 Cray-1
• 1984 Cray X-MP
• 1985 Cray-2
• 1989 Cray Y-MP
• 1992 BBN Butterfly
• 1994 Meiko CS-2
• 1995 Cray C90
• 1995 Cray T3D
• 1998 IBM ASCI Blue Pacific
• 2000 IBM ASCI White
• 2004 Thunder
• 2005 IBM Blue Gene/L
• 2005 ASC Purple
• 2006 Zeus
• 2006 Rhea
• 2006 Atlas
• 2007 Minos
• 2012 IBM Sequoia

The November 2007 release of the 30th TOP500 list of the 500 most powerful computer systems in the world, has LLNL’s Blue Gene/L computer in first place for the seventh consecutive time. Five other LLNL computers are in the top 100. However, the November 2008 release of the TOP500 list places the Blue Gene/L supercomputer behind the Pleiades supercomputer in NASA/Ames Research Center, the Jaguar supercomputer in Oak Ridge National Laboratory, and the IBM Roadrunner supercomputer in Los Alamos National Laboratory. Currently, the Blue Gene/L computer can sustain 478.2 trillion operations per second, with a peak of 596.4 trillion operations per second.

On June 22, 2006, researchers at LLNL announced that they had devised a scientific software application that sustained 207.3 trillion operations per second. The record performance was made at LLNL on Blue Gene/L, the world's fastest supercomputer with 131,072 processors. The record was a milestone in the evolution of predictive science, a field in which researchers use supercomputers to answer questions about such subjects as: materials science simulations, global warming, and reactions to natural disasters.

LLNL has a long history of developing computing software and systems. Initially, there was no commercially available software, and computer manufacturers considered it the customer’s responsibility to develop their own. Users of the early computers had to write not only the codes to solve their technical problems, but also the routines to run the machines themselves. Today, LLNL computer scientists focus on creating the highly complex physics models, visualization codes, and other unique applications tailored to specific research requirements. A great deal of software also has been written by LLNL personnel to optimize the operation and management of the computer systems, including operating system extensions such as CHAOS (Linux Clustering) and resource management packages such as SLURM.^[36] The Peloton procurements in late 2006 (Atlas and other computers) were the first in which a commercial resource management package, Moab, was used to manage the clusters.^[37]

Livermore Valley Open Campus (LVOC)

In August 2009 it was announced that a joint venture known as the Livermore Valley Open Campus (LVOC) would be created between Sandia National Laboratories/California campus and LLNL to promote collaboration between the scientists at these labs and their counterparts in industry and academia. It was intended that open access to the campus would directly support the advancement of innovation and research, increase the profile of the labs in the region, expand the high-tech “footprint” of the San Francisco Bay Area and establish the Livermore Valley as the high-tech anchor of the East Bay of San Francisco.

Sponsors

LLNL's principal sponsor is the Department of Energy/National Nuclear Security Administration (DOE/NNSA) Office of Defense Programs, which supports its stockpile stewardship and advanced scientific computing programs. Funding to support LLNL's global security and homeland security work comes from the DOE/NNSA Office of Defense Nuclear Nonproliferation as well as the Department of Homeland Security. LLNL also receives funding from DOE’s Office of Science, Office of Civilian Radioactive Waste Management, and Office of Nuclear Energy. In addition, LLNL conducts work-for-others research and development for various Defense Department sponsors, other federal agencies, including NASA, Nuclear Regulatory Commission (NRC), National Institutes of Health, and Environmental Protection Agency, a number of California State agencies, and private industry.

Budget

For Fiscal Year 2009 LLNL spent $1.497 billion^[38] on research and laboratory operations activities:

Research/Science Budget:

• National Ignition Facility - $301.1 million
• Nuclear Weapon Deterrent (Safety/Security/Reliability) - $227.2 million
• Advance Simulation and Computing - $221.9 million
• Nonproliferation - $152.2 million
• Department of Defense - $125.9 million
• Basic and Applied Science - $86.6 million
• Homeland Security - $83.9 million
• Energy - $22.4 million

Site Management/Operations Budget:

• Safeguards/Security - $126.5 million
• Facility Operations - $118.2 million
• Environmental Restoration - $27.3 million

Directors

The LLNL Director is appointed by the Board of Governors of Lawrence Livermore National Security, LLC (LLNS) and reports to the board. The Laboratory Director also serves as the President of LLNS. Over the course of its 55 year history, eleven eminent scientists have served as LLNL Director:

• 1952-1958 Herbert York
• 1958-1960 Edward Teller
• 1960-1961 Harold Brown
• 1961-1965 John S. Foster, Jr.
• 1965-1971 Michael M. May
• 1971-1988 Roger E. Batzel
• 1988-1994 John H. Nuckolls
• 1994-2002 C. Bruce Tarter
• 2002-2006 Michael R. Anastasio
• 2006-2011 George H. Miller^[39]
• 2011–Present Penrose C. Albright^[40]

Organization

The LLNL Director is supported by a senior executive team consisting of the Deputy Director, the Deputy Director for Science and Technology, Principal Associate Directors, and other senior executives who manage areas/functions directly reporting to the Laboratory Director.

The Directors Office is organized into these functional areas/offices:

• Chief Information Office
• Contractor Assurance and Continuous Improvement
• Environment, Safety and Health
• Government and External Relations
• Independent Audit and Oversight
• Office of General Counsel
• Prime Contract Management Office
• Quality Assurance Office
• Security Organization
• LLNS, LLC Parent Oversight Office

The Laboratory is organized into four principal directorates, each headed by a Principal Associate Director:

• Global Security
• Weapons and Complex Integration
• National Ignition Facility and Photon Science
• Operations and Business
  • Business
  • Facilities & Infrastructure
  • Institutional Facilities Management
  • Integrated Safety Management System Project Office
  • Nuclear Operations
  • Planning and Financial Management
  • Staff Relations
  • Strategic Human Resources Management

Three other directorates are each headed by an Associate Director who reports to the LLNL Director:

• Computation
• Engineering
• Physical & Life Sciences

Corporate management

The LLNL Director reports to the Lawrence Livermore National Security, LLC (LLNS) Board of Governors, a group of key scientific, academic, national security and business leaders from the LLNS partner companies that jointly own and control LLNS. The LLNS Board of Governors has a total of 16 positions, with six of these Governors constituting an Executive Committee. All decisions of the Board are made by the Governors on the Executive Committee. The other Governors are advisory to the Executive Committee and do not have voting rights.

The University of California is entitled to appoint three Governors to the Executive Committee, including the Chair. Bechtel is also entitled to appoint three Governors to the Executive Committee, including the Vice Chair. However, one of the Bechtel Governors must be a representative of Babcock and Wilcox (B&W) or the Washington Division of URS Corporation (URS), who is nominated jointly by B&W and URS each year, and who must be approved and appointed by Bechtel. The Executive Committee actually has a seventh Governor who is appointed by Battelle, however they are non-voting and merely advisory to the Executive Committee. The remaining Board positions are known as Independent Governors (also referred to as Outside Governors), and are selected from among individuals, preferably of national stature, and can not be employees or officers of the partner companies.

The University of California-appointed Chair has tie-breaking authority over most decisions of the Executive Committee. The Board of Governors is the ultimate governing body of LLNS and is charged with overseeing the affairs of LLNS in its operations and management of LLNL.

LLNS managers and employees who work at LLNL, up to and including the President/Laboratory Director, are generally referred to as Laboratory Employees. All Laboratory Employees report directly or indirectly to the LLNS President. While most of the work performed by LLNL is funded by the federal government, Laboratory employees are paid by LLNS which is responsible for all aspects of their employment including providing health care benefits and retirement programs.

Within the Board of Governors, authority resides in the Executive Committee to exercise all rights, powers, and authorities of LLNS, excepting only certain decisions that are reserved to the parent companies. The LLNS Executive Committee is free to appoint officers or other managers of LLNS and LLNL, and may delegate its authorities as it deems appropriate to such officers, employees, or other representatives of LLNS/LLNL. The Executive Committee may also retain auditors, attorneys, or other professionals as necessary. For the most part the Executive Committee has appointed senior managers at LLNL as the primary officers of LLNS. As a practical matter most operational decisions are delegated to the President of LLNS, who is also the Laboratory Director. The positions of President/Laboratory Director and Deputy Laboratory Director are filled by joint action of the Chair and Vice Chair of the Executive Committee, with the University of California nominating the President/Laboratory Director and Bechtel nominating the Deputy Laboratory Director.^[41]

The current LLNS Chairman is Norman J. Pattiz - founder and chairman of Westwood One, America's largest radio network, and he also currently serves on the Board of Regent of the University of California. The Vice Chairman is J. Scott Ogilvie - president of Bechtel Systems & Infrastructure, Inc., he serves on the Board of Directors of Bechtel Group, Inc. (BGI) and on the BGI Audit Committee.^[42]

The Board of Governors uses the following committees to oversee the management and operations of LLNL by LLNS:

• Business and Operations
• Ethics and Audit
• Mission
• Nominations and Compensation
• Nuclear Weapons Complex Integration
• Safeguards and Security
• Science and Technology

See also

San Francisco Bay Area portal

• Dielectric wall accelerator
• Top 100 US Federal Contractors

Footnotes

References

• Nuclear Rites: A Weapons Laboratory at the End of the Cold War, by Hugh Gusterson, University of California Press, Berkeley, 1996 (ISBN 0-520-21373-4)
• The Stockpile Stewardship and Management Program: Maintaining Confidence in the Safety and Reliability of the Enduring U.S. Nuclear Weapon Stockpile U.S. Department of Energy, Office of Defense Programs. May 1995.
• Preparing for the 21st Century: 40 Years of Excellence. Lawrence Livermore National Laboratory. Report UCRL-AR-108618. 1992.

External links and sources

• Lawrence Livermore National Laboratory (official website)
• Lawrence Livermore National Security, a Limited Liability Corporation (official website)
• Laboratory History (official website)
• LLNL Industrial Partnerships and Commercialization (IPAC) (official website)
• University of California Office of Laboratory Management (official website)
• Society of Professionals, Scientists and Engineers (Union representing UC Scientists and Engineers at LLNL)
• University of California LLNL Retiree Group (Legal Defense Fund for UC Retirees from LLNL)
• Annotated bibliography for Livermore from the Alsos Digital Library for Nuclear Issues

Coordinates: 37°41′10″N 121°42′34″W / 37.686°N 121.7095°W / 37.686; -121.7095

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Anti-nuclear movement in the United States   General Anti-nuclear groups in the US California movement Protests in the US Great Peace March Nuclear power in the US Canceled nuclear plants in the US Nuclear weapons and the US   Organizations and groups Abalone Alliance Clamshell Alliance Committee for Nuclear Responsibility Corporate Accountability International Critical Mass Friends of the Earth Greenpeace USA Institute for Energy and Environmental Research Mothers for Peace Musicians United for Safe Energy Nevada Desert Experience Nuclear Control Institute Nuclear Information and Resource Service Physicians for Social Responsibility Plowshares Movement Public Citizen Shad Alliance Sierra Club Three Mile Island Alert Women Strike for Peace   People Daniel Berrigan Larry Bogart Helen Caldicott Barry Commoner Frances Crowe Carrie Barefoot Dickerson Paul M. Doty Jane Fonda John Gofman Paul Gunter John Hall Amory Lovins Arjun Makhijani Gregory Minor Hermann Joseph Muller Ralph Nader Linus Pauling Eugene Rabinowitch Bonnie Raitt Martin Sheen Karen Silkwood Thomas Louie Vitale   Main protest sites Black Fox Bodega Bay Diablo Canyon Indian Point LLNL Montague Naval Base Kitsap Nevada Test Site Rancho Seco Rocky Flats San Onofre Seabrook Shoreham Three Mile Island Trojan Vermont Yankee White House Peace Vigil Y-12 Weapons Plant Yankee Rowe   Books Carbon-Free and Nuclear-Free Conservation Fallout Contesting the Future of Nuclear Power Critical Masses Fallout: An American Nuclear Tragedy Killing Our Own Licensed to Kill? Making a Real Killing Nuclear Implosions Nuclear Politics in America The Cult of the Atom We Almost Lost Detroit   Films Atomic Ed and the Black Hole Countdown to Zero Dark Circle