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Home My WebLink About4.07 SitingIgnitionFaciltyLivrmrLab . . e . CITY OF DUBLIN AGENDA STATEMENT CITY COUNCIL MEETING DATE: October 3, 1994 SUBJECf: Siting of the National Ignition Facility at the Lawrence Livermore National Laboratory 1!:fJ (Prepared by: Bo Barker, Management Assistant) EXHIBITS ATTACHED: 1. / Resolution supporting the siting of the Ignition Facility at {') I W. ' Lawrence Livermore National Laboratory ~2. / Excerpt from the Conceptual Design Report Executive Summary RECOMMENDATION: Adopt the Resolution and direct staff to forward it the Secretary of Energy. FINANCIAL STATEMENT: None DESCRIPTION: Over the last 10 years the United States Department of Energy has been studying the concept of Internal Confinement Fusion (lCF). In simplistic terms, ICF uses laser beams directed at specific target that, when ignited, creates a strong energy source. An excerpt from the Conceptual Design Report Executive Summary is included as Exhibit 2. The Department of Energy has completed numerous steps in this process and is now considering the construction of a National Ignition Facility. The siting of a facility at the Lawrence Livermore Laboratory would bring a large scale project to the East Bay providing jobs and other economic benefits. In an attempt to persuade the Department of Energy to locate the facility at Lawrence Livermore Laboratory, it has been suggested that East Bay cities send resolutions of support to the Secretary of Energy. It is recommended the City Council adopt a resolution in support of locating the National Ignition Facility at the Lawrence Livermore Laboratory and forward it to the Secretary of Energy. COPIES TO: CITY CLERK FILE ~ ITEMNO.~. 1 .... e e RESOLUTION NO. - 94 A RESOLUTION OF THE CITY COUNCIL OF THE CITY OF DUBLIN **************** IN SUPPORT OF THE NATIONAL IGNITION FACILITY AT THE LAWRENCE LIVERMORE LABORATORY WHEREAS, the proposed u.s. Department of Energy's National Ignition Facility will play essential roles in safeguarding the nation's security and in the development of a clean, limitless energy supply; and WHEREAS, the State of California, and the Bay Area have been economically impacted by defense reductions including significant base closures and are lagging significantly behind the rest of the nation in economic recovery; and WHEREAS, the National Ignition Facility project will provide a significant economic incentive to the region and the State with a broad spectrum of jobs and business for California's high technology businesses; and WHEREAS, the U.S. Department of Energy and its Laboratories are integral to the local, Bay Area and California business economy, and that the Lawrence Livermore National Laboratory is a vital and valuable resource for the Tri-Valley area in particular; and WHEREAS, the National Ignition Facility will be important in sustaining the Lawrence Livermore National Laboratory as an outstanding national, state, regional and local scientific, technological and education resource. NOW, THEREFORE, BE IT RESOLVED that the City Council of the City of Dublin urges the U.S. Department of Energy to construct and operate the National Ignition Facility at the Lawrence Livermore National Laboratory. PASSED, APPROVED AND ADOPTED this 3rd day of October, 1994 AYES: NOES: ABSENT: ABSTAIN: Mayor ATTEST: City Clerk EXHIBIT .1. e National Ignition Facility -Conceptual Design Report Executive Summary August 1994 192 Beam NIF ~ Th.1UtJomll Ignition F."lIIty ~ ~~lb(j)( Mi.:) e UCRL-PROP~117093 ES NIF-LLNL-94-113 L-16973-ES e e L-16973-ES Contents 1. Introduction. ... .............. ........................... .............................. ............. ...... .......................... 1 2. Benefits.................................................. .............................................................................. 1 2.1 Science and Technology ........ ............................................... ............... ..................... 1 2.2 Industrial Competitiveness .. ..... .................................... .......................... ................ 2 2.3 Energy Resources ...... ..... ..... ... ...'.......................... ......... ..... ... ... ............... ................... 2 2.4 National Security ....... ........ ..... ..... ................................. ............. ................................ 2 3. Background..................................................... ...................................................... .............. 3 4. NIP Conceptual Design.............. .................................. ...... ............. ............. ................ ..... 4 4.1 Laser System. ................... ............. ........................... .............. ..... .......... ...... ............... 4 4.2 Target Area ..... ..... ........... ............................................ ... ...... ...................................... 9 4.3 Integrated Computer Control................................... ....................... ....................... 13 4.4 Laser and Target Area Building .............................................................................. 14 5. Other Project Activities....... ................ ..................... ...... ................... ..... ............. .............. 15 6. Method of Accomplislunent .. ............ ...................................... ............. ...... ..................... 16 6.1 Management.. ..... ...... ............. ...... .................................. ... ...................................... .... 16 6.2 Criteria............................................ ............................................................................ 16 6.3 Project Participants ... ..... ..... .......................................... ... ........ ....... .............. ............ 18 6.4 Work Breakdown ........ ............ ................................. .....'.......................... .................. 18 7 . Schedule and Cost ...... ..................... ........... ............. ......................... .......... ....................... 19 8. The NIP Conceptual Design Report ................................................................................ 21 References ................................................................................................................................ 22 A tlachnmen t ....................................................... ..... ................................................... ........... .. A-I i e e L-16973-ES 1. Introduction The mission of the National Ignition Facility (NIP) Project is to provide an aboveground experimental facility capable of achieving fusion ignition for maintaining nuclear competence and weapons effects simulation, furthering the development of inertial fusion energy, and supporting the development of high energy-density physics. The NIP will utilize solid-state lasers as the energy driver. In this facility, a large num- ber of laser beams will be focused onto a small target located at the center of a spherical target chamber; the energy from the laser beams will be deposited in a few billionths of a second. The target will then implode, forcing atomic nuclei to sufficiently high tem- perature and density necessary to achieve a miniature fusion reaction. A conceptual design for the NIP has been prepared and documented by a multilaboratory team within the Department of Energy's National Inertial Confinement Fusion Program. The team included personnel from Lawrence Livermore National Laboratory, Sandia National Laboratories, Los Alamos National Laboratory, and Uni- versity of Rochester Laboratory for Laser Energetics. 2. Benefits Rapid and major progress has been made in the last few years in all areas of inertial confinement fusion (ICF) science and engineering. The NIP will provide the vital capa- bility necessary to accomplish the next ICF scientific plateau-fusion ignition and energy gain. Reaching this plateau earlyin the twenty-first century will maintain U.S. world leadership in ICF and will benefit four of the DOE's businesses: Science and Technology, Industrial Competitiveness, Energy Resources, and National Security. The NIP will integrate civil, commercial, and security research, while being consistent with DOE goals for Environmental Quality. 2.1 Science and Technology The NIP will produce conditions in matter similar to the center of the sun and stars. New, diagnosable, high-energy-density regimes will be accessible in the laboratory for the first time. Thousands of university and laboratory scientists and students all over the world will benefit from international collaborations on leading-edge research in laser-matter interactions; astrophysics; properties of matter at extremely high tempera- tures, pressures, and densities; hydrodynamics; atomic and radiative physics; x-ray lasers for biological imaging; materials sciences; nonlinear optics; x-ray sources for semiconductor materials processing; advanced accelerator concepts; computational physics; and laser and plasma diagnostics. The recent declassification of virtually all of the ICF concepts will foster participation by the general scientific community. 1 e e L-16973-ES 2.2 Industrial Competitiveness The NIP will spur world-class industrial capabilities in low-cost, large-scale preci- sion optics manufacturing; advanced laser technology; laser and plasma materials processing; low-cost, rapid crystal-growth technology; micromachining methods; x-ray lithography technologies; and a variety of advanced instrumentation such as ultrahigh- speed electronics and photonics. Commercial impacts will include large flat-panel displays, advanced computers, new materials, and flexible and cost-effective laser- based manufacturing. The laboratories of the national ICF program have already won 24 cooperative research and development agreements (CRADAs), totaling over $160M, in microelectronics, microphotonics, advanced manufacturing technologies, biotechnol- ogy, environmental, and other fields. The NIF construction project will invest approximately one billion dollars in the u.s. economy over a seven-year period. Seventy-five percent of this investment will be placed in industry, adding 1100 jobs and providing industrial stimulus in critical tech- nologies. Small, minority owned, and/or disadvantaged businesses are uniquely posi- tioned to benefit along with major U.S. companies. As the world's largest optical instru- ment, the NIP can boost the U.S. precision optics industry into a position of world leadership. i' [".. " ....., ." I': 2.3 Energy Resources The NIF will provide critical data on fusion ignition and gain that will enable scien- tific evaluation of inertial fusion energy (IFE) as one of two fusion energy options (the other is magnetic fusion energy) called for in the National Energy Policy Act of 1992.1 Inertial fusion data from the NIF and magnetic fusion data from the Tokamak Physics Experiment and the International Thermonuclear Experimental Reactor will determine the scientific feasibility of the two fusion energy options. Developing fusion energy will help promote u.s. world leadership in providing new energy technologies that reduce the adverse environmental impacts associated with energy production, and will also reduce our nation's dependence on 9i1. 2.4 National Security The NIP will support the National Security vision of reducing the global nuclear danger by becoming a cornerstone of the science-based Stockpile Stewardship Program. In a public address on July 3, 1993, President Clinton said "To assure that our nuclear deterrent remains unquestioned under a test ban, we will explore other means of main- taining our confidence in the safety, the reliability, and the performance of our own weapons." The NIF is a major component of these other means. The same high energy- density capabilities described above will allow the study of many basic physical pro- cesses that occur inside nuclear weapons. The NIP, along with other facilities, will enable weapons scientists to maintain the expertise and computational tools necessary to contribute to the U.s. nonproliferation activities and to ensure that the remaining stockpile remains safe, secure, and reliable-without nuclear testing. Most NIP experi- 2 e e L-16973-ES ments will examine fundamental physics and therefore will be unclassified. An early NIP start is important because the nation's expertise in nuclear weapons science has been declining since 1989. The NIP can help maintain national recognition of the DOE as the pre-eminent research and development organization. Building the NIP for these purposes was recommended by the National Academy of Sciences2 and the Inertial Confinement Fusion Advisory Committee.3 3. Background , ~, The early history of the U.S. ICF Program and its deployment of successively larger and more powerful laser drivers for target irradiation experiments culminated in the Nova system (1984) at LLNL and the Omega system (1985) at the University of Roches- ter Laboratory for Laser Energetics. During the mid-1980s, the ICF community pro- posed a 200-1000 MJ yield laboratory microfusion facility (LMF) to support Defense Programs. Early studies indicated that the LMF would require a 5-10 MJ driver. In 1985, the DOE established a National Academy of Sciences committee chaired by Dr. William Happer, Professor of Physics at Princeton University, to review the national ICF program. The committee concluded that research for several more years was re- quired to support an LMF-scale project. In 1989, Mr. Troy Wade, Assistant Secretary for Defense Programs, testified to Congress that the ICF program had progressed much more rapidly than the Happer Committee or anyone else anticipated in 1985. Conse- quently, Congress (in the FY89 Authorization and Appropriation bills) mandated a review of the ICF program. In response, the DOE established a secorid National Acad- emy of Sciences Inertial Confinement Fusion review committee chaired by Dr. Steven Koonin, Professor of Physics at the California Institute of Technology. That committee met over a two-year period and in 1990 recommended that an intermediate-size, less costly fusion ignition facility be considered as the next step, and that it be built as part of a national, interlaboratory program. The committee also recommended that the ignition facility utilize a solid-state laser driver, since it was the only near-term technol- ogy available that could achieve igI1ition. Concurrently, the DOE Fusion Policy Advisory Committee recommended (in 1990) that an Inertial Fusion Energy Program be started within the Office of Fusion Energy and an intermediate-size (1-2 MJ) facility be constructed to demonstrate ignition and modest gain prior to authorizing a full-scale LMF. In February 1991, Secretary of Energy Admiral James D. Watkins sent a letter to the House Committee on Science, Space, and Technology concurring with the major recommendations of the National Academy of Sciences review. Heeding the recommendations of the National Academy of Sciences report, the DOE established a standing Inertial Confinement Fusion Advisory Committee in 1992. The committee met in December 1992 to consider the status of Novatechnical progress and recommended to the Assistant Secretary for Defense Programs that DOE proceed with Key Decision 0 (KDO). In January 1993, Secretary Watkins, as chair of the DOE Energy Systems Acquisition Advisory Board, affirmed that a positive KDO was warranted and authorized the preparation of aI) NIP Conceptual Design Report for submission in 1994. 3 t...- e e L-16973-ES That report, which was completed in May 1994, is a key element in the decision-making process for proceeding with the NIP Project. 4. NIF Conceptual Design The conceptual design siting basis for the NIF is a generic DOE Defense Program site, defined as open space that is within or immediately adjacent to an existing Defense Programs site. The conceptual design effort was concentrated on the NIF core element, the Laser and Target Area Building, which is locatable at any of the currently proposed sites. In addition, through the development of operational flow charts and other analy- sis, a document was prepared that contains a complete list, description, and cost of support and auxiliary facilities necessary for NIF operation. Many of these facilities or their equivalent are likely to exist and be usable for NIP purposes at current candidate sites. Thus, this list provides a methodology for examining site-specific cases and deter- mining which new facilities and/or facility upgrades will be required in addition to the Laser and Target Area Building. The NIF conceptual design was not only guided by operations planning and an operational flow analysis of people and materials, but, to a large extent, by an ICF experimental plan prepared to chart the path to fusion ignition in this facility. The NIP core facility conceptual design is shown in Figure 1. The Laser and Target Area are designed to satisfy and be in compliance with a comprehensive set of primary and functional criteria. Key performance criteria are summarized'in Table 1. 4.1 Laser System , f. The NIP laser is designed to meet the primary criteria and functional requirements for achieving indirectly driven ignition by providing: . A 500-J1m laser spot size with optimum intensity distribution at the laser entrance hole. The beam will be spatially smoothed by phase plates and temp-orally smoothed using four wavelengths at 0.35 J.UIl (300) separated by 3.3 A. . Symmetrical implosion of the capsule using two-sided target irradiation geom- etry, with two cones of beams per side, and eightfold rotational symmetry. The beams will be pointed on target to within 50 J.U11 rms. . A carefully shaped laser temporal pulse with a peak-b:,-foot contrast ratio of 50:1. . Sufficient energy in the pulse to provide a high probability of ignition. The laser will routinely deliver 500 TW /1.8 MJ at 300 to the laser entrance hole of the target hohlraum. The 1.053-J1m (100) laser is designed to deliver at least 632 TW or 3.3 MJ in a 5.1-ns pulse, accounting for peak power-conversion efficiency for the 100/300 frequency con- verter and other beam-transport losses. The baseline beamline will produce a peak power of -3.9 TW at 100. Therefore, the minimum number of beams required is 162. 4 I' , r~. .. C'II :gc; E.... ::len -lD 8:: G;~ :E~ Q.o. EC'II <;::. e e CO) c; .... en en ~lD ~:: iiiUi' -u 'iiio. ~.e en ECO) ll.l""': iij'1 >.... enen "enlD i~> -.... - en - 00;:- =C::l C C) 0 OCll.t: U - C) "::l E ... 0 CIl ll.l ... ll.len.t: lDCIl- -- C) C cen ...- ::l C -::l t: 0 ~ II'? o E 0''1 o....u.... :g e o.en Ill.!::: olD ~ E~:: EiijE~O CIl!::;ll.l~:: GJ .... ... _ 'II'" .c ti ~ o.~ ,,2enC'llen fa iij t: ;::. lD ...t:&' :: ll.loo. en o.::l :Jenen C CIl = ... ~EC'II ..ll.l.... 0- . o.~'1 ...en.... ll.l en .- t>> lD ::C> Q.'i: .... E.Q~ CIl - en .- u c"C_ .- c a. 1ll0'<t ::Eu_ ..... - c; C .... ::l en o m E ~> ... >.... l!l:iS ~ -Een ... 1Il U .!!!!eno. Oen'<t 0. CIS_ a. E CIl !""': ll.l 0.'1 en...... -Een [~m iii ~:: u en ~ ;:lcUi' o.oU O;:lo. l!!~ 1Il C 1Il C) - ~ C..- ::l en oE EO. ...C1C 0- ... en "'ll.l..,. Eiic; >E.... =ll.len >enm ~::l:: E CIC CIS M 1lE~ ,,~en cenm CIl i:':: &t: ....:: CIl 0 en in a. E ...eno. ll.lCUl 'El!!CO) --- > :is EUl 1Il . en '1 en.... ClSen =ID 8:: en~ -en ~.2 uo. O'<t 0._ 5 Eel! ll.lCO) - . en.... >en enID ~;: - - 0."- o ~ iijo. ClIO ii:~ E o e ... c 0 0- _CIl GiS ... U 1Il en co.... 1Il...C'i C) ll.l . 1Il-.... en en en _CIlID [~:: - E ~ 511lu aiiio. 0>.... en_ L~16973-ES u5 - = Q.l = 0 S- o u e Q.l - ~ ~ rJ:J "" Q.l ~ lU ,..J ~ = 0 .... "" lU > Q.l :: ~ 0 ..c ~ "" Q.l ~ lU - ~ ~ lU - l:lO E = .... e ~ "'C 0 Q.l = e lU Q.l --9 N 0\ ,.... u) ~ lU r:w .... - -= e ~ - Z Q.l ..c ~ E-t :J: ~ ! i ~ = l:lO '" .... ... ~ e L-16973-ES e Table 1. NIF primary and functional criteria highlights. Laser A laser capable of: · Energy (measured incident on entrance hole of the 1.8 MJ hohlraum) · Peak Power · Power Balance (over any 2-ns interval) · Wavelength · Pointing (beam centering deviation) Experimental Area An experimental area and target chamber capable of: · Accommodating and supporting experimenter-supplied cryostats for cryogenic targets · Annual number of shots with fusion yield · Maximum credible DT fusion yield limit · Classified and unclassified experiments 500 TW <8% O.35J..lrn <50 J.I1I1. IIIIS Yes 100 shots of yield <100 KJ 35 shots of yield <5 MJ 10 shots of yield <.20 MJ 45 MJ (1.6 x 1019 neutrons) Yes ,., i L, . . ! The NIF conceptual design includes 192 beamlines, providing a design margin greater than 15%. A schematic of one beamline of the high-power neodymium-glass NIP laser is shown in Figure 2. The 192 laser beamlines require over 9000 discrete, large-format (greater than 40 cm x 40 cm) optics as well as several thousand small-format (greater than 15-cm diameter) optics. The NIP laser subsystems are indicated Figure 1. The laser consists of four 4 high x 12 wide arrays or bundles of beamlines with a nominal hard aperture of 40 cm each. Each beamline is optically independent. This design is very compact compared to previous fusion laser systems, facilitating a compact system and building design. A typical amplifier assembly is shown in Figure 3. An Optical Pulse Generation (OPG) system provides the input pulse to the laser and is located below the transport spatial filter (TSF). The OPG system consists of compact, stand-alone optical packages that inject the input beam into the far field of the TSF. The beam passes through the boost amplifier columns, the Pockels cell assembly, and is captured in a multipass scheme using cavity mirrors, amplifiers (AI and A2), and spatial filters. Flashlamps, located in the amplifier, uniformly pump the laser slabs and are driven with ....260 MJ electrical energy. The Pulsed Power System provides this energy, which is stored in dielectric capacitors. The amplifier column hardware includes laser slabs, reflectors, flashlamps, blast shields, electrical connections, and support frames. A column consists of an amplifier module that is four-bearns-high and is grouped 12-beams-wide to form an amplifier 6 \." I' e e L-16973~ES Cavity ampllfle 1 Cavity Lena mirror BOO8ter amplifier i C.vlty mirror Injection pulee from p....mplifl.r Fl1IqU8ney converter 40-00-Q394-0789pbOl Figure 2. A schematic of one beamline of the NIF laser from pulse injection to final focus on target. 227.667 (5.78) 262.905 (6.68) To target Amplifier column (108 in A 1 assembly) 4o-CIO-039H1888.pub Figure 3. View of a NIF main cavity amplifier assembly (typical of all NIF amplifiers). 7 e e L~16973-ES t..... .~ assembly. Each laser bundle has three separate amplifiers: a 9-slab-Iong main cavity amplifier (A1), a 5-slab-Iong switch amplifier (A2), and a 5-slab-Iong boost amplifier (A3). The frame assembly unit is the principal frame on which the other amplifier com- ponents are mounted. The frame assembly unit is a one-slab-wide by four-slabs-high by one-slab-deep aluminum framework, with blast shields mounted to two of the long sides. A 4-high slab cassette subassembly and an 8-wide flashlamp cassette slide into the frame assembly unit to form a complete amplifier column. To facilitate assembly and maintenance, the slab and flashlamp cassettes are changed from underneath an amplifier column using a special processing cart. This allows the critical amplifier components to be protected from the laser bay environment at all times. The amplifiers will operate under a positive pressure, inert gas atmosphere to prevent particle flow into the amplifier cavity. The spatial filters are large, evacuated multibeam chambers that provide beam image relaying and beam modulation control during beam amplification and transport. This is performed with an array of confocal lens pairs at opposite ends of each chamber and with pinhole apertures at their common focal planes. The cavity spatial filter is located within the multipass cavity and is bonnded by amplifiers on either end. The transport spatial filter is located after the A3 amplifier and accommodates the seed pulse injection from the optical pulse generation system. The vessels will be constructed of stainless steel and operate at <10-2 torr vacuum. The size of the spatial filters will allow pinhole and lens replacement from inside the chamber, out of the laser bay envi- ronment. Two cavity mirror mount assemblies (LM1 and LM2) per laser bay are located at each end of the laser cavity, as shown in Figure 2. These assemblies provide support and remote alignment of the cavity mirrors that reflect the beam back and forth during multipass amplification. Each assembly consists of a large array frame, adjustment platforms for initial alignment, and individual cavity mirror mounts. The cavity mirror farthest from the target area (LM1) is also a deformable mirror for performing wavefront correction of the beam. The other cavity mirror (LM2) has full-aperture transmission capability for use with beam diagnostics. The cavity mirror assemblies have remotely operated pitch and r<?ll adjustments for use in preshot system alignment. The Pockels cell is an electro-optic device that rotates the polarization of each laser beam, and is used with the polarizer to switch the laser beam out of the main amplifier cavity. To accomplish this switching, the Pockels cell rotates the beam polarization in less than the cavity round-trip transit time (.....200 ns). It uses plasma-electrode technol- ogy to create regions of ionized helium on both sides of a potassium dihydrogen phos- phate (KDP) crystal to induce birefringence, which causes polarization rotation in the beam passing through. The Pockels cell consists of a housing, KDP crystal, windows" discharge electrodes, electrical connections, controls, and vacuum system. The windows contain the plasma near the crystal, and the vacuum system maintains the helium atmosphere at 35 rotorr. The Pockels cells are grouped in arrays to match the laser beam layout, which consists of a series of 1-wide x 4-high Basic Switch Units. There are nOrrUnally six individual transport turning mirror mounts (LM3 to LM8) per beam, which are also shown in Figure 2. These provide support and remote alignment of the mirrors that tral)Sport the beam from the laser cavity to the target. S i': , " , , I ~ ~i ~ . !- . I,',', . "., L' [""" t}; i.:'i 1',:j~ \ '''~: ('..'; \\;: ii e e L-16973~ES i ~ J' i Each mirror mount array consists of an array frame, adjustment platforms for initial alignment, and individual transport turning mirror mounts. In order to accommodate the pointing requirements on the target, both the elbow mirror (LM3) and the ultimate target mirror (LM8) have remotely actuated pitch and roll adjustments, and the two switchyard mirrors (LM4 and LM5) have remotely actuated pitch adjustments. The roll adjustments on LM4 and LM5 and the pitch and roll adjustments on LM6 and LM7 are one-time manual adjustments that occur during installation. The ultimate target mirrors . (LM8) have full-aperture transmission capability for use with target backscatter beam diagnostics. The Final Optics System is a single integrated structure that is mechanically sup- ported by and directly fastened to a flange on the Target Chamber. It will convert four 10) beams to the third harmonic, focus these 30) beams onto the target, and provide beam smoothing and color separation. Frequency conversion will be accomplished using a Type I KDP second harmonic convertor and a Type II KD*P third harmonic convertor. The beams will be focused onto the target using off-axis, aspheric, fused- silica lenses. The wedged component of the lenses will disperse the unconverted and undesirable 10) and 20) beams from the target. The focus lenses will be the vacuum barrier for the target chamber. Beam smoothing will be accomplished using phase plates manufactured on the target side surface of the debris shields. The removable debris shields will be sacrificial optical elements used to protect the focus lenses from target debris, shrapnel, and soft x-rays. The Final Optics Assembly will also provide support for a full-aperture, incident-beam energy diagnostic (30) calorimeter). A diffrac- tion grating on the laser side of the focus lens will be used to diffract nominally 0.1 % of the 30) beam to a mirror, which will image the beam onto a thermo-electric calorimeter. Beam control and laser diagnostic systems are provided to align and diagnose all NIP laser beams from pulse generation in the Maser Oscillator to the final focus on target. r 4.2 Target Area The NIF target area is designed 1:0 satisfy primary and functional requirements by providing: . A 10-m-diameter, 10-cm-thick wall, externally shielded aluminum vacuum cham- ber, upon which is mounted final optics, laser diagnostics, and target diagnostics. . A vacuum of <5 x 10-5 torr within two hours before a laser shot. . A vibration-resistant target positioner that will place a cryogenic or a noncryogenic target within 3 em of the vacuum chamber center. . A system to align a target and the laser centroid to within 50 J.lm. . Laser and target diagnostics for system performance control and verification and provisions for future ignition diagnostics. . Shielding and confinement systems to protect workers, the public, and the envirorunent. \.,'~ ' 9 e e L-16973-ES The NIP target area provides the experimental facility for performing target experiments and consists of the following major subsystems: target chamber, target emplacement, target diagnostics, target diagnostics control room, support structures, environmental protection, and auxiliary systems. A cutaway view of the target area is shown in Figure 4. The laser beams are transported in 2 x 2 arrays from the switchyards to the target chamber room. The laser beams focus energy onto a target located at the center of the target chamber, while target diagnostics mounted on the chamber collect experimental data. The laser beams enter the target chamber through final optics assemblies located in two circular configurations defined by the intersection of cones with -270 and -530 polar angles. The final optics assemblies are offset :1:40 from the nominal cone angles. The target chamber is housed in a reinforced-concrete building with three separate operational areas. The upper and lower pole regions of the target chamber house the final optics and turning mirrors in a Class 1000 clean room. Personnel access to these areas will be limited to preserve cleanliness levels. The third area of the target building i. l":." ~ 'r,! , .:J r--".,. )" I" 1- Switchyard mirror Target area building L_: \'" L) ;/,':{i r ' jU_~ '-, :."., >~~; ('., I ' L I.'.' I ' i '.':"":"'J Target chamber Final optics assembly 40.00-0394-' 030.pub Figure 4. A cutaway view of the NIF target area showing major subsystems. 10 e e L-16973-ES ) . encloses the equatorial portion of the target chamber and contains the majority of the target diagnostics. This area is not intended to be a clean room as the majority of the operational diagnostic configuration activity takes place in this region. The cantilevered floor sections of the building provide separation of the clean room enclosures at the polar regions from the equatorial target diagnostic area. The horizontal orientation of the equatorial access plane provides convenient opera- tional access to the majority of the target diagnostics mounted to the target chamber. This orientatioI:' also provides convenient horizontal access to the laser optical assem- blies housed in the target area. This orientation simplifies the design of the access struc- tures required to service the laser optical components and diagnostics. There are also structures to provide personnel access to the laser turning mirrors, final optics assem- blies, and diagnostics. The NIP baseline target chamber design is a 10-em-thick by 10-m internal-diameter spherical aluminum shell. The aluminum wall provides the vacuum barrier and mounting surface for the first wall panels, which protect the aluminum from soft x-rays and shrapnel. Unconverted laser light that hits the opposite wall is absorbed by other panels located adjacent to and slightly smaller than the opposing beam port. The exterior of the chamber will be encased in 40 cm of concrete to provide neutron shielding. The chamber is supported vertically by a hollow concrete pedestal and horizontally by radial joints connected to the cantilevered floors. The chamber vacuum system will provide a 10--6 torr vacuum level for target experiments. The target chamber is illustrated in Figure 5 with the target emplacement and positioning/alignment systems and planned diagnostics. The target emplacement and positioning/ alignment systems are two multi-degree- of-freedom manipulators designed to provide a system for repeatable and stable align- ment of the laser beam target sensor system and the target within the target chamber. The manipulators will be inserted through opposing ports on the target chamber and will pass through vacuum-isolation valves outside the chamber. This will permit mounting the target onto the end of the manipulator and subsequent repositioning inside the evacuated chamber at the beam's focal point. The target emplacement system is designed for noncryogenic targets; however, the design concept is consistent with cryogenic targets. Both manipulators are supported by external mounts that are isolated from the structure and chamber vibration. Thetarget area will accommodate the required x-ray and neutron diagnostics to execute the experimental plan for ignition in the NIP. The majority of the target diag- nostics are positioned around the horizontal equator of the target chamber. To accom- modate the "equatorial" diagnostics, the Target Area Building arid structural space frame are designed to provide space around the chamber equator. This configuration provides a room 30.5 m in diameter by -3-m high, with the chamber approximately at . the center and a floor common to the equatorial diagnostics, providing easy access and serviceability of these experiments. In addition, the structure is designed to accommo- date the diagnostics located up to :1:200 off the equator, as well as diagnostics at the poles. The diagnostics ports will accommodate many standard diagnostics and will have a clear aperture 46 cm in diameter so that experiments can use universal twelve- J , 11 - e f~-~' , I L-16973-ES I'" Static X-ray Imaging (SXI) Chamber center reference system (CCRS) Target Positioner-(TARPOS) Neutron Imaging (NI) I ) , Time Resolved X~ray Imaging (GXI) Shock Break Out (SOP) r ! .~~ ! ': Filter Fluorescer (FFLEX) Neutron Flight Path (NFP) I" r r . I I, Static X~ray Imaging (SXI) Chamber Center Reference System-(CCRS) I",' i L, 40-00.c394-1096,pub ,:' Figure 5. NIF target chamber with target diagnostics. inch manipulators for insertion of diagnostics in the chamber. This will provide flexibil- ity for the rapid rebuilding and relocation of instruments between shots. Environmental Protection Systems are designed to meet key performance specifica- tions, such as limiting NIP tritium inventory to 300 Ci and total tritium release from NIP facilities to less than 10 Ci/y. The tritium processing system will convert tritium (which will be present in the NIP target chamber, diagnostic lines-of-sight, vacuum systems, and glove boxes) to tritiated water, which will be stored on dryer beds for disposal at a later date. The tritium pro- cessing system will interface with other systems that could be exposed to tritium, such as vacuum pumping systems for the target chamber. The cleaning/decontamination of the debris shields will be done in an off-line clean- ing station to protect personnel and the environment from exposure to tritium-contami- nated surfaces and external radiation produced by activation. The automated cleaning I 12 e e L-16973-ES r .. , process concept utilizes pelletized C02 blasting equipment for removal of surface contaminants. The interior of the NIP chamber will be cleaned and decontaminated using a similar pelletized C02 blasting system with a remotely controlled robotic arm. The use of the robotic system for cleaning minimizes the need for personnel entry into the NIP chamber. A general decontamination workstation will provide an off-line cleaning/ decontamination capability for other target-related components. For all of the C02 cleaning systems, the aggregate of collected gases will be exhausted to the ahno- sphere through the facility elevated-release-point after being filtered by a HEPA-filtered debris recovery system and monitored by a dedicated tritium monitor. Radiation and tritium monitoring systems will be installed to continuously measure levels of gamma and neutron radiation within the target room/chamber to assure that personnel do not enter the target room or chamber before radiation has declined to pre-established levels. Monitors will be located at experiment areas outside the target room to ensure that personnel are not exposed to radiation above prescribed levels. 4.3 Integrated Computer Control System The Integrated Computer Control System (ICCS) combines the elements of the laser and target area distributed control subsystems to form an overall control system that provides for safe and efficient installation, operation, and maintenance of the NIP. The ICCS consists of six major elements as shown in Table 2. The computer system and network architecture provide control functions and operator stations needed in the facility to meet the dual requirements of centralized controls for experiments and remote controls for construction and maintenance. The ICCS distributes its processing in a layered architecture, with each additional layer exhibiting more functional complexity and a higher degree of integration. These layers are grouped into an upper-level and a lower-level computer system. Table 2. Major elements of the Integrated Computer Control System. Ices Element Contents Supervisory Control Software Workstations, networks, file servers, software tools, and graphics displays Control and monitoring of power conditioning beam control, laser diagnostics, and target diagnostics Fast and precision timing signal generation and distribution Access controls and subsystem permissives Pointing, centering and focusing of beam transport components Computer System Integrated Timing System Integrated Safety System Automatic Alignment System Ancillary Systems Video, voice, surveillance and ,environmental monitoring services 13 e e L-16973-ES 4.4 Laser and Target Area Building The Laser and Target Area Building, shown in Figure 1, is designed as an environ- mentally controlled facility for housing the laser and target area systems. It consists of two lasers bays, two optical switchyards, a target room, target diagnostic facilities, capacitor areas, control rooms, and operations support areas. The floor plan is based on a U-shaped layout, with the laser bays forming the legs of the "U" and the switchyards .with target room forming the connection. This configuration allows a second target chamber to be added in the future without major disruption to NIP operation. The Laser and Target Area Building is designed in accordance with DOE Order 6430.1A4 and is classified as a low-hazard, non-nuclear facility. The Laser and Target Area Building will conform to other codes such as the Uniform Building Code and the Life Safety Code. The laser bays and switchyards consist of isolated 0.91-m-thick concrete slabs, with walls and roofs supported by isolated piers. The central core area between the laser bays has system support rooms located on the ground level and mechanical equipment on the second level. The core area is also supported by piers. This concept of an isolated mat foundation for the laser bays and a pier support for the main vibration-isolation sources will satisfy the system vibration-isolation requirements. The target chamber is housed in a cylindrical, reinforced-concrete building, which is 30.5 m in diameter and is 29.3-m tall, with a: 1.82-m-thick wall and a 1.21-m-thick roof. The target room has 'canti- levered floors that extend from the cylindrical wall to create the three separate opera- tional areas (see Figure 4). Two of the areas enclose the upper and lower pole regions of the target chamber where the turning mirrors and final optics packages are located. The third area of the target building encloses the equatorial portion of the target chamber and contains the majority of the target diagnostics. All wall openings will have concrete doors, except where the laser beams enter the target room. As a result of the beam path openings, the switchyard walls require a minimum concrete thickness of 0.6 m for radiation shielding; however, they will be thicker than this for structural reasons. The heating, ventilating, and air conditioning (HV AC) system is designed to provide filtered, temperature-controlled air to all parts of the Laser and Target Area Building. The entire experimental area will be maintained with :to.280C in order to satisfy laser stability requirements. The degree of cleanliness varies with location in the building. The size of this building would make a totally high-cleanliness facility prohibitively expensive. Therefore, the approach taken has been to provide graded cleanliness levels with only localized high-cleanliness areas. The laser bays and switchyards incorporate 90% bag filters to provide a cleanliness level between Class 10,000 and Class 100,000. Localized clean modules will be utilized around the laser components during assembly and maintenance to produce a Class 100 cleanliness level. Also, the entire laser system will be slightly pressurized with a clean gas to prevent particle intrusion onto the criti- cal optical components inside. The target room will have Class 1000 HEPA-filtered airflow to the pole regions above and below the target chamber. The target room HV AC system will be capable of providing a slight negative pressure in the room at shot time with exhaust release at an elevated point to accommodate the possibility of air activa- tion during high-yield shots. 14 ,.".' I I I, (: I" r /, r- r": ,...." 1'" I.',,: f';: i e e L-16973-ES ;m, I The building fire-suppression system will consist of an automatic sprinkler system. Appropriate fire barriers have been designed to limit property damage, fire propagation, and loss of life by separating adjoining structures, isolating hazardous areas, and protecting personnel egress paths. In these rooms, an independent fire hazards analysis, as allowed by DOE Order 5480.7 AS will be prepared in the Title I design stage to document a loss potential of less than $150M. In the present design, materials of building construction (metal, glass, concrete, gypsum), equipment, and cabling are essentially noncombustible or fire resistant and represent an insignificant fire load. The most significant fire load is the banks of oil-filled capacitors, which will be separated from the high-value laser components by housing the capacitors in four, two- hour, fire-rated rooms. 5. Other Project Activities In addition to designing, constructing, and procuring hardware for the facilities and equipment described in the preceding sections, a number of activities are necessary to support the NIP Project. These Other Project Cost activities are funded by Operating Expense allocations, as opposed to Plant And Capital Equipment allocations. The fol- lowing activities are included: ES&H/Supporting R&D: . Assurance functions for the project. . Preliminary Safety Assessment Report development based on the Conceptual De~ign Report. · EP A, state, and local NEP A permits. . Environmental analysis for preparation of an Environmental Impact Statement. · Conceptual design. · Advanced conceptual design. · Technical support. . Other Project Costs administration and integration. Start-up Activities: · Start-up and operations planning. . Technology transfer. . Training material preparation and training of operations staff. . Operations and maintenance procedure preparation. · Staffing. . Performance of operational test procedures during facility system start-up. . Engineering, maintenance, and host site support during facility system start-up. · Operating spares. lmC 15 e e L-16973~ES · Initial stores inventory. · Operational Readiness Reviews. The assurance functions funded under the Other Project Cost includes Quality, Security, Safety, and Environmental reviews needed for the NIF Project. An advanced concepmal design effort will be performed after the NIF concepmal design, and is expected to result in updated design criteria to be utilized in the Title I design. Techni- cal support includes final prototype testing, the facilitization of optics manufacmrers, pilot optics-manufacmring runs, and the Other Project Cost funded set of target diag- nostics. (An initial set of diagnostics is funded by project capital dollars). Final proto- type testing provides data for the reliability, availability, and maintainability smdies. The capacity of U.S. optics companies for producing large optical components is currently inadequate to meet the NIF schedule requirement. In addition, the cost of large optics using present manufachlring technology is inconsistent with the NIF cost goals. For these reasons of schedule and cost, a substantial effort is planned to facilitate the necessary optics suppliers in order to obtain optics for the NIF at a rate and cost consistent with present goals. Facilitation requires a sufficient quantity of state-of-the- art production equipment and a concomitant modification of production facilities to install the equipment. This facilitation program will commence at the beginning of FY97 with pilot production continuing into mid-FY99. i I. , ' r~~ }' ...; I: ( >.: ) '" ,-:<':'"".; 'I: I' 6. Method of Accomplishment I.;"; r. ,'".:1"; l;'~ 6.1 Management j:{~{ The NIF is a national inertial confinement fusion project and a DOE major system acquisition. The major participants are the DOE-Defense Program at Headquarters and the qakland Field Office, Lawrence Livermore National Laboratory, Los Alamos Na- tional Laboratory, Sandia National Laboratories, and the University of Rochester Labo- ratory for Laser Energetics. The line management begins with the DOE Assistant Secre- tary for Defense Programs and proceeds through the DOE-HQ Program Director and DOE-HQ Project Director to the DOE/OAK Project Lead. The DOE/OAK Project Lead provides day-to-day interfaces with the NIF Laboratory Project Office lead by the Labo- ratory Project Manager and the Deputy Project Managers representing each participat- ing organization. In addition, subcontractors such as the Architect/Engineer, Construc- tion Manager, and NEP A document preparer will be involved in the implementation of the project. \ 'J j , 6.2 Criteria The NIF design is guided by a comprehensive set of criteria and requirements docu- ments and, as a DOE project, will conform to applicable DOE orders and guidelines. The NIP criteria hierarchy is shown in Figure 6. I 16 The NIP top-level criteria, which are identified in the Functional Requirements/ Primary Criteria document,6 include: 1. Mission-related requirements. 2. Safety requirements. 3. Environmental protection. 4. Safeguards and security. 5. Building systems. 6. Operational availability. 7. Decontamination and decommissioning. 8. Quality assurance. 9. Applicable DOE orders, codes, and standards. e J:- ~ I I ~ : (0"- , " I ! ' ,.~- e L-16973-ES DOE orders, Federal, State, Justification of NIF users and codes, and local mission need stakeholders standards, etc. regulations (JMN) requirements , NIF primary criteria and Level 1 selected functional requirements + Other functional Level 2 requirements System design Level 3 requirements Interface control Level 4 documents 4CJ.00.0494-1m pub ~_. - Figure 6. Hierarchy of the NIF design criteria. 17 e e L-16973-ES f'.. -, 6.3 Project Participants The project execution staff will consist of personnel from the participating laborato- ries and subcontractors. In addition, the project will be supported by an extensive number of manufacturers and suppliers throughout the United States. Figure 7 indi- cates the types of businesses likely to participate based on prior experience with large glass laser systems (e.g., Nova, Omega, Beamlet, etc.). The NIF Project will utilize a variety of contract formats to assure equitable, cost-effective construction, and procurements. \.,0.: ,~ I.,' , i 6.4 Work Breakdown The NIP Project is planned around the work breakdown structure shown in Figure 8. This work breakdown structure provides the backbone for organizing and integrating cost and schedule information. During design construction and start-up, it will provide the means to track project expenditures. A more detailed version of the work breakdown structure is included in the attachment to this document. 'I," r-:- \"'".1 i; MT * NO ll':~ \ ., ; . :~: j SO * WY f? co ** KS * '. _~. J Type of business Number * Small business 203 ." iO. ti Woman~owned small business 23 * Small disadvantaged business 23 "* Large business 62 4()'()()'()594-2349pb01 Figure 7. The projected NIF manufacturing base. 18 e e L-16973-ES ,i . 7. Schedule and Cost I, ' The schedule shown in Figure 9 describes the sequence of events leading to the start of operations in October 2002. This assumes that the NIP Project is initiated by line-item funding in FY96 based on a validated Conceptual Design Report. A detailed schedule has been prepared encompassing all NIP Project activities to work breakdown structure Level 3 by Participant Code. The schedule has been updated since the CDR to reflect the decision to prepare an Environmental Impact Statement (EIS) and to accelerate portions of the manufacturing facilitization program. The EIS activities are on the schedule critical path. This schedule reflects the DOE decision constraints and thorough attention to environmental and safety analysis and documentation. The schedule is also tightly integrated with supporting technology efforts and the activities necessary to assure cost-effective, reliable, timely supplies of large optical components. The detailed project schedule reveals the critical path that affects project duration. In some periods (e.g., procurement and construction), dual critical paths exist. The major NIP critical path consists of design, site selection, design and construction of the Laser and Target Area Buildings through beneficial occupancy, installation of the laser and other special equipment, completion of acceptance test procedures, and start-up of the NIP. The processes of completing construction, installing equipment, and system start-up are overlapped to shorten the critical path within the limits of a practical funding profile. The release of construction and procurement funding is constrained by a.DOE key decision, as are design and operations funding. These key decisions (KDl-4) are shown in Figure 9. WBS Level 1 National Ignition Facility Project Office 1.2 Site and Conventional Facilities Laser 1.4 Target Area 1.1 was Level 2 1.5 Integrated Computer Control 1.6 Optical Components c=:=:J PACE funded ~ OPEXfunded 1.4.0693.2859P Figure 8. NIF Project topw1evel work breakdown structure. 19 L-16973-ES e C') ~ u. N o it T"" o it <C 80 ~ --------- o o it en ~ .- '0 - .! i ~ E CI) c.. :5 5 o 0" "0 CI) l: lV m ~ - to en it l;; > u. - - -8<::> - --r:- ~ 'Cij ~ g. - CI) CI)~ 80 "0 -g c.. ~ g ~ ~O N ~. _ - - -0-<)- '7 g- j::. en - - - - - - - - ~ >~ l:::E " CJ <C CI) CI) "0 ~ > u. l: o CI)'-O =u Cl)CI) "iii ---CI)---- CI) ;:; "0 j:: B ---0------ O~ en w < I() en it o z ---<>------------- ~O o W t- o::t en > u. e -0--- -0:: ~o:: ii:O ~ .e "0 l: lV en ! lV en o :::J i: as US l: o := o :::J "0------ e " CI) .c .!! ------:0. :::J 1: c.. C o 0:: o l: en en - - - --8- -- "0 "i 3 .a l: c.. "0 as CI) CI) ~ g 2 .g <C CJ_ -8::- e as 0. <C l: ::J: en 0.. .~ . o o D. o 20 CI) iii ~ CI) C-' i ,-- i "I i (''', , Ii; I:" ~. - ", aj - = "Cl aJ ..t:: v fI'J t' rtl e e = fI'J .... u aJ .- e ~ ~ - i z 0\ ~ ~ ..;. '" = i bO .... ~ 1'- e -- L-16973-ES The NIP Total Project Cost (TPC) is the sum of the Total Estimated Cost (TEC) and the Other Project Cost (OPC). The TEC is funded by Plant and Capital Equipment (PACE) funds, and the OPC is funded by Operating Expense (aPEX) funds. The TEC activities include the Title I and II design and Title ill engineering; building construc- tion; procurement, assembly, and installation of all special equipment; and sufficient spares to reach acceptance of the construction project. Costs associated with the TEC begin at the start of Title I design and are substantively complete when all subsystems and components of the special equipment are installed and have been tested in accor- dance with acceptance test procedures. The OPC activities include all start-up planning and testing activities, Operational Readiness Reviews, spares inventory sufficient to reach the end of TPC and to provide for initial operations, the Preliminary Safety Analysis Report, environmental assessments and NEP A documentation, the conceptual and advanced conceptual designs, technical support, and assurance functions for these activities. OPC activities begin before Title I with the costs for the conceptual design study and end after the Operational Readiness Review. The NIP will then be ready for KD4 and transition to annual operations. After KD4, the operations of the NIP will be funded by ICF Program operating funds. Table 3 is a summary of the TEC and Opc. The last column contains the totals as they appear in the Project Data Sheet. The totals and temporal profiles have been updated since the CDR to incorporate approved cost trends (e.g., adding an EIS). Using the detailed cost database, the Integrated Project Schedule, and the DOE cost escalation guidance, the NIP temporal cost profile was derived. Table 4 shows the yearly Budget Outlay (BO) and Budget Authority (BA) requirements for the NIP Project to cover TEC and OPC. 8. The NIF Conceptual Design Report The NIF conceptual design has been documented in a multiple volume Conceptual Design Report. An extensive series of appendices are included with that report to sup- port the design and cost of the NIP. The Conceptual Design Report includes assess- ments of safety and environmental issues. The NIP Conceptual Design has been re- viewed in-depth by participating Laboratory scientists and engineers, by Laboratory management, by DOE/OAK and DOE-HQ, and by an independent cost estimation contractor. The Conceptual Design Report contents are described in the attachment to this document. Table 3. Summary of NIF costs for the 192-beamlet laser design. Base costs Contingency Total Total ($M FY 1994 ) ($M escalated) TEC OPC TPC 586.5 199.1 785.6 121.0 N/A 121.0 707.5 199.1 906.6 842.6 230.8 1073.4 21 References 1. National Energy Policy Act of 1992, Public Law 102-486. ,..-- \ ' I'" \ " 2. National Research Council, Second Review of the Department of Energy's Inertial Confinement Fusion Program, Final Report, National Academy Press, Waslllngton, D.C. (1990). I I , I , I 3. Inertial Confinement Fusion Advisory Committee for Defense Programs' Letter to Assistant Secretary for Defense Programs (May 20,1994). 4. U.S. Department of Energy, Orc:Ier 6430.1A, General Design Criteria (1989). 5. U.s. Department of Energy, Order 5480.7 A, Fire Protection (1989). 6. National Ignition Facility Primary CriteriafFunctional Requirements, NIF-LLNL-93-058, L-15983-1, Lawrence Livermore National Laboratory, Livermore, CA (February 1994). 7. National Ignition Facility Conceptual Design Report Supplement, NIF-LLNL-94-113, L-16973-1 Vol 5, Lawrence Livermore National Laboratory, Livermore, CA (August 1994). 22