The fundamental neutron physics beamline at the Spallation Neutron Source.The Spallation Neutron Source The Spallation Neutron Source (SNS) is an accelerator-based neutron source being built in Oak Ridge, Tennessee, USA, by the U.S. Department of Energy (DOE). SNS is being designed and constructed by a unique partnership of six DOE national laboratories: Argonne, Lawrence Berkeley, (SNS SNS sympathetic nervous system. ), currently under construction at Oak Ridge National Laboratory Oak Ridge National Laboratory (ORNL) is a multiprogram science and technology national laboratory managed for the United States Department of Energy by UT-Battelle, LLC. ORNL is located in Oak Ridge, Tennessee, near Knoxville. with an anticipated start-up in early 2006, will provide the most intense pulsed beams of cold neutrons in the world. At a projected power of 1.4 MW, the time averaged fluxes and fluences of the SNS will approach those of high flux reactors. One of the flight paths on the cold, coupled moderator will be devoted to fundamental neutron physics. The fundamental neutron physics beamline is anticipated to include two beam-lines; a broad band cold beam, and a monochromatic monochromatic /mono·chro·mat·ic/ (-kro-mat´ik) 1. existing in or having only one color. 2. pertaining to or affected by monochromatic vision. 3. staining with only one dye at a time. beam of 0.89 nm neutrons for ultracold neutron (UCN UCN Universidad Católica del Norte (Chile) UCN University College of the North (The Pas, Manitoba, Candad) UCN Ultra Cold Neutron UCN Unión del Centro Nacional ) experiments. The fundamental neutron physics beamline will be operated as a user facility with experiment selection based on a peer reviewed proposal process. An initial program of five experiments in neutron decay In nuclear physics, neutron decay may refer to:
n. Mathematics Abbr. T An operation representing a transformation from a given physical system undergoing a given sequence of events to a system in which the exact reverse sequence of events takes place. symmetry violation have been proposed. Keywords: fundamental neutron physics; neutron source; spallation neutron source. 1. Introduction Cold neutrons and ultracold neutrons have been employed in a wide variety of investigations that shed light on important issues in nuclear, particle, and astrophysics astrophysics, application of the theories and methods of physics to the study of stellar structure, stellar evolution, the origin of the solar system, and related problems of cosmology. in the determination of fundamental constants and in the study of fundamental symmetry violation. In many cases, these experiments provide information not available from existing accelerator-based nuclear physics facilities or high-energy accelerators. Until very recently, most of the research in this area has been based at cold sources at reactors. Such sources provide intense continuous beams of cold and ultracold neutrons. The Spallation Neutron Source (SNS) offers an extraordinary opportunity for fundamental neutron physics (FNP FNP Family Nurse Practitioner FNP Frederick News-Post (Frederick, MD newspaper) FNP Fédération Nationale des Podologues FNP Foundation for National Progress (Mother Jones) FNP Fusion Point ). In the past, measurements in this field have been significantly limited by statistical and systematic effects. The SNS offers significant gains in both areas. It will have, by far, the highest peak neutron source intensity in the world. The proposed beam will be the most intense pulsed beam in the world for fundamental neutron physics. The fact that the SNS will be a pulsed source offers profound advantages for the reduction of systematic effects. The time-averaged neutron fluence Flu´ence n. 1. Fluency. from our proposed beamline at the SNS will be greater than that at any continuous neutron source in the United States. When the SNS reaches its final design goal of [approximately equal to]2 MW, the flux and fluence will be within a factor of [approximately equal to]3 to 4 times that at the highest flux beam at the Institut Laue-Langevin (ILL) [1]. Very significantly, the SNS, as a new facility, provides an exceptional opportunity to fully optimize the design of the beamlines. This is especially important in the reduction of backgrounds and the minimization of magnetic interference, which have proven to be serious problems at other neutron facilities. In general, the advantages of the SNS in reducing systematic errors lie in four main areas: 1. Utilizing the time structure of the beam to analyze background and to separate the signal from parasitic effects that have different velocity dependence (important for the experiments that study the weak nucleon-nucleon (NN) interaction via gamma asymmetry measurements and neutron spin rotation). 2. Utilizing the time structure of the beam to make both precise and accurate determinations of neutron beam polarization with polarized A one-way direction of a signal or the molecules within a material pointing in one direction. [.sup.3]He gas cells (important for the beta asymmetry measurements of the A and B correlation coefficients in neutron decay). 3. Utilizing developments in neutron guide technology, particularly curved "benders" to transport the beam far away from other equipment and experiments without significant loss of flux, thereby reducing gamma-ray and neutron backgrounds. The proposed external UCN facility will be far from other instruments. 4. Finally, the design of an independent external experimental facility allows the opportunity to address seismic/vibration noise that is particularly important for some experiments with UCNs. A number of specific experiments have been identified as being particularly well suited to a cold-neutron program at the SNS. These are identified elsewhere in these proceedings and include the precise measurement of the neutron lifetime using magnetically trapped UCNs, the determination of the gamma-ray asymmetry in the capture of polarized neutrons on light nuclei, the precise measurement of a complete set of beta asymmetry parameters in polarized neutron decay, the determination of the parity non-conserving neutron spin rotation in light nuclei (H and [.sup.4]He), and the search for a nonzero non·ze·ro adj. Not equal to zero. nonzero Not equal to zero. neutron electric dipole moment Noun 1. electric dipole moment - the dipole moment in an electric dipole dipole moment - the moment of a dipole (EDM (Engineering Data Management) An information system that maintains the details of all engineering data while the product is in the design and concept phase. This includes geometry and changes to geometry. See PLM. EDM - Electronic Data Management ), using UCNs and superfluid su·per·flu·id n. A fluid, such as a liquid form of helium, exhibiting a frictionless flow at temperatures close to absolute zero. su helium. 2. The Fundamental Neutron Physics Beamline at the SNS The FNP beamline facility will be located on neutron flight path 13 (FP13) at the SNS (Fig 1). The FNP beamline will consist of neutron guides, choppers, secondary shutters, monochromators, and shielding along with the necessary utilities, safety and radiation protection equipment, and appropriate ancillary equipment. One guide will terminate at approximately 15 m from the cold moderator, inside the SNS target building. It will be used for measurements that require a cold-neutron beam with a broad wavelength distribution. A second guide will transmit the neutrons to an external experimental facility adjacent to the SNS target building. This facility will be used for experiments that require ultracold neutrons. The fundamental neutron physics beamline "views" a "partially-coupled" liquid hydrogen moderator. This moderator has the highest cold flux of the SNS moderators. The exit face of the moderator possesses a flat portion of 10 cm X 12 cm area. This moderator is viewed by a 10 cm X 12 cm, m = 3.5 supermirror guide. The guide penetrates the core vessel insert region and extends to within [approximately equal to]0.9 m of the moderator face. At a distance of [approximately equal to]2.2 m from the moderator is the primary beam shutter, which extends 1.8 m along the beam. A section of curved neutron bender extends through this shutter and is designed to precisely align with the static guide elements on both sides when the shutter is open. Between the main shutter and the end of the guide are 4 frame-overlap choppers. A secondary shutter will be placed downstream of the last chopper and will serve as the local experimental shutter. The beamline for the UCN station begins with the double-crystal monochromator A monochromator is an optical device that transmits a mechanically selectable narrow band of wavelengths of light or other radiation chosen from a wider range of wavelengths available at the input. that diffracts a monochromatic neutron beam centered at 0.89 nm out of the primary polychromatic polychromatic /poly·chro·mat·ic/ (-krom-at´ik) many-colored. pol·y·chro·mat·ic or pol·y·chro·mic or pol·y·chro·mous adj. Having or exhibiting many colors. beam. The first crystal will be located between the first and second frame-definition choppers. The first chopper will be configured to have a "notch" such that 0.89 nm neutrons are passed for all operating conditions. This effectively decouples the operation of the polychromatic and 0.89 nm beamlines. The beam is diffracted horizontally using alkali-intercalated graphite crystals. The mosaic spread of this crystal can be made large enough ([approximately equal to]2[degrees] full width at half maximum A full width at half maximum (FWHM) is an expression of the extent of a function, given by the difference between the two extreme values of the independent variable at which the dependent variable is equal to half of its maximum value. ) to match the neutron guide divergence so that all of the neutrons that can efficiently produce UCNs UCNs in [.sup.4]He by one-phonon down scattering are reflec-reflected. The once reflected neutrons are incident on a second alkali monochromator that reflects the neutrons towards the external facility. The phase space distribution of the 0.89 nm neutrons is approximately returned to the distribution before reflection from the first crystal and thus can be efficiently guided to the experimental station with an m = 3.5 guide. The UCN beamline ends at [approximately equal to]40 m from the moderator in a shielded enclosure of dimensions approximately 15 m X 13 m X 10 m. This external building includes a vibrationally isolated floor slab for support of the experiments, cryogenic service, and road access for experimental equipment. [FIGURE 1 OMITTED] 3. Project Status The fundamental Neutron Physics Beamline is currently under construction at Oak Ridge National Laboratory. The cold neutron beamline is planned for completion in early 2008 and the ultracold neutron beamline is scheduled for completion in 2010. Both beamlines will be operated as user facilities with experimental approval and beam allocation based on a proposal driven, peer review system. Acknowledgements This work is supported by the Office of Nuclear Physics of U.S. Department of Energy (DE-FG02-03ER41258 and MIE-04-FNPB) and Oak Ridge National Laboratory. 4. References [1] R. Tribble et al., Report to the Nuclear Sciences Advisory Committee on Fundamental Physics with Neutrons (2003). Geoffrey Greene University of Tennessee The University of Tennessee (UT), sometimes called the University of Tennessee at Knoxville (UT Knoxville or UTK), is the flagship institution of the statewide land-grant University of Tennessee public university system in the American state of Tennessee. , Knoxville, TN Vince Cianciolo, Paul Koehler, and Richard Allen Oak Ridge National Laboratory, Oak Ridge, TN William Michael Snow Indiana University, Bloomington, IN Paul Huffman and Chris Gould North Carolina State University History
David Bowman and Martin Cooper Los Alamos National Laboratory Los Alamos National Laboratory (LANL) (previously known at various times as Site Y, Los Alamos Laboratory, and Los Alamos Scientific Laboratory) is a United States Department of Energy (DOE) national laboratory, managed and operated by Los Alamos National , Los Alamos, NM and John Doyle Harvard University, Cambridge, MA Accepted: August 11, 2004 Available online: http://www.nist.gov/jres |
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