THE SPALLATION NEUTRON SOURCE (SNS) PROJECT Jose Alonso

THE SPALLATION NEUTRON SOURCE (SNS) PROJECT Jose Alonso

THE SPALLATION NEUTRON SOURCE (SNS) PROJECT Jose Alonso The SNS is currently the US Department of Energy's activation and residual-radiation levels in the tunnels are largest accelerator construction project, and is being low enough to allow quick access and hands-on carried out by a partnership of five DOE National maintenance, and is driven by the very high reliability and Laboratories for building the world's most powerful availability specifications associated with the strong user- accelerator-based pulse spallation source. At its planned orientation of the SNS facility. Areas where unusable 2 MW operating level, it will produce neutron fluxes at beam is diverted (so-called "controlled" beam-loss least a factor of ten greater than Rutherford Appleton points), such as collimators, scrapers and dumps, must be Laboratory’s ISIS, currently the world’s leading spallation designed to collect these particles in a way that contribute source. The current design of the SNS, shown in Figure only minimally to background levels in the tunnels where 1, calls for a full-energy (1 GeV) linac delivering 1 ms access is required. Normal loss mechanisms must receive pulses to an Accumulator Ring which compresses these particular attention to meet this specification. This into 600 ns proton pulses that strike a liquid mercury implies very tight control over beam emittance, and target at a 60 Hz rate. Room-temperature and cryogenic emittance growth; designing for the largest-possible stay- moderators produce beams of slow neutrons suitable for clear apertures in linac, transport and ring structures; materials research with an initial suite of at least 10 understanding of space-charge and halo effects in linac and ring; ensuring highest-possible vacuum in areas neutron-scattering instruments. Table 1 summarizes the - basic parameters for the baseline design. where H beam is transported to avoid stripping losses; extremely careful design of ring injection system and painting to ensure cleanest injection and capture, and the minimum number of foil traversals of the circulating proton beam; understanding potential ring instabilities associated with the very high stored number of protons. In addition, operational issues of stability in power supplies, efficient tuning and feedback algorithms, quick turn-on and rapid tune-up procedures, high-quality diagnostics, and extremely high reliability of all components all add to the challenge of the SNS design. Rising to these challenges, substantial progress has been made by all the partner laboratories; this progress is highlighted below. Lawrence Berkeley National Laboratory (LBNL) is responsible for the beam formation, and the first part of the accelerating system. Their design calls for producing FIGURE 1: Schematic layout of SNS the 70-mA, 1 ms H- beam pulses in a volume-type rf- discharge source, bunching and accelerating the beam in Table 1. SNS Baseline Design Parameters an RFQ to an energy of 2.5 MeV, and chopping the beam Beam Species on Target Protons into 600 ns “mini-pulses” (with 250 ns gaps between Proton Beam Energy 1 GeV them) suitable for lossless injection into the ring. While Average Beam Power 2 MW all relatively mature technologies, the design requirements Pulse Repetition Rate 60 Hz do stretch the levels of performance for several of the Linac Pulse Length 1 ms needed systems. R&D efforts are close to demonstrating Turns Injected in Ring 1200 required beam-current levels, and have solved several Particles Stored in Ring/pulse 2 x 1014 thorny problems, including the separation of electrons Pulse Width on Target 600 ns extracted from the source along with the H- ions. The Instantaneous Current on Target »60 A first production units are currently being assembled, a fully-operating test-bed will be running in about a year’s Instantaneous Power on Target »60 GW time. Target Material Flowing Mercury Los Alamos National Laboratory (LANL) is Moderators, Ambient Temp 2 (water) responsible for the linac systems required to accelerate the Moderators, Cryogenic 2 (Supercritical H ) 2 beam to the full energy of 1 GeV. The current baseline Neutron Beamlines ³ 18 design consists of a DTL (Alvarez-type Drift-Tube Linac) Uncontrolled Beam Loss < 1 watt/meter between 2.5 MeV and around 85 MeV, followed by a conventional CCL (Coupled-Cavity Linac) to take the Note, the last line in Table 1 represents one of the beam the rest of the way to 1 GeV. The configuration of biggest challenges in the design of the SNS. It represents this linac system is based on the very successful LAMPF -4 a fractional uncontrolled beam loss of less than 1 x 10 (now LANSCE) design, with a few enhancements based over the whole length of the accelerator and transport on lessons learned over the long experience base with this lines. This very low loss is required to ensure that accelerator. For instance, the frequency jump between the DTL and the coupled-cavity structures is only a factor of its transition between “off” state and “on” state with no 2 instead of 4 (400 to 800 MHz, versus 200 to 800 MHz), beam present. (Any beam in the magnet during this and the focusing configuration has been adjusted to transition would be lost on the septum, causing substantial ensure better matching between the various accelerating activation and thermal damage.) Note, this gap originates and transport sections. Designs are being finalized now, way back in the low energy end of the linac, where the and hot-model testing is proceeding. Procurements for “mini-pulses” are produced by the beam chopper, the train klystrons and structure components are expected to begin of “mini-pulses” and gaps being synchronized to overlap in 2000. during the stacking process. A recent decision has been to not incorporate the After the full complement of turns is injected into the CCDTL concept into the accelerating chain. This has ring, a fast kicker ejects the entire load (in a single turn) resulted from some engineering difficulties with a test and sends it through the RTBT (Ring-to-Target Beam section, and a re-evaluation of the optimization of Transport) line to the target. structure design, cost and beam dynamics. Oak Ridge National Laboratory is designing the target, As a parallel activity, a serious evaluation is being moderator and neutron transport systems. Situated inside conducted on the potential advantages of replacing the a 6-meter radius block of concrete and steel, these normal-conducting high-energy linac portion of the linac systems convert the beam power via carefully designed (above around 200 MeV) with a superconducting moderator and reflector systems into usable fluxes of structure. Recent advances for TESLA at DESY have thermal and slow neutrons that are conveyed in the 18 addressed some of the technical issues associated with transport lines leading to the scattering instruments. application of this technology for pulsed linacs, but other Liquid mercury is used as the target, flowing at a rate of issues associated with operational reliability and details of 1.5 meters per second through the target vessel. As such rf systems, as well as cost and schedule compatibilities the 2 MW of beam power causes only a 30°C temperature with the overall project , are still being evaluated. A rise. Liquid metal offers numerous advantages for high- decision is expected by mid December 1999. power targets, including mitigation of shock problems, Brookhaven National Laboratory is building the reduction of waste-streams for spent targets (the charge of Accumulator Ring that provides the pulse-compression mercury, about 1.5 cubic meters, is expected to last (current amplification), and the high-energy transport throughout the entire life of the facility), and minimizing lines connecting this ring with the linac and the target. of decay heat in the event of a system shutdown, since the Beam is shaped, collimated and conditioned in the first activation is spread throughout the entire liquid volume transport line (the HEBT, or High Energy Beam Transport instead of concentrated in the actual area where the beam line) for optimum injection into the ring; the aim being to stops. minimize beam loss in the ring, and allow for efficient R&D activities focus on operation of flowing loops, and controlled stacking of the »1200 turns accumulated corrosive effects, beam-shock measurements and during the injection process. A 90° achromatic bending modeling, and radiation effects. In these regards, there section is provided in the HEBT for momentum selection are substantial interactions between the SNS target group and cleaning. Beam is passed through a 300 µg/cm2 and ongoing activities in Japan and Europe. carbon foil, in which the two electrons are stripped from Instruments for neutron scattering are being developed the H - beam, and the resulting protons join beam already by a consortium centered at the IPNS at Argonne National stacked in the ring. The foil is supported by thin carbon Laboratory, with joint ORNL-ANL management. To fibers to eliminate the support frame that would intercept make best use of the very high fluxes that will be beam. Programmed bump magnets in the ring are used to available at the SNS, a strong emphasis has been placed paint the 1200 turns into a suitable pattern to minimize the on innovative designs and new technology for detectors number of times the circulating beam traverses the and instrument concepts. As a result, instrument types stripping foil, and to ultimately tailor the beam density and performance requirements are being specified, but the distribution that strikes the target. detailed designs are being coupled closely with carefully- The ring has four straight sections, connected by four designed R&D activities to ensure that each of the 10 90° achromatic bending arcs. Each straight has a instruments expected to be on-line at the start of operation particular function: injection, cleanup and collimation, rf are truly world-class.

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