13,188 research outputs found

    The DRIFT Directional Dark Matter Detector and First Studies of the Head-Tail Effect

    Full text link
    Measurement of the direction of the elastic nuclear recoil track and ionization charge distribution along it, gives unique possibility for unambiguous detection of the dark matter WIMP particle. Within current radiation detection technologies only Time Projection Chambers filled with low pressure gas are capable of such measurement. Due to the character of the electronic and nuclear stopping powers of low energy nuclear recoils in the gas, an asymmetric ionization charge distribution along their tracks may be expected. Preliminary study of this effect, called Head-Tail, has been carried out here using the SRIM simulation program for Carbon and Sulfur in 40 Torr carbon disulfide, as relevant to the DRIFT detector. Investigations were focused on ion tracks projected onto the axis of the initial direction of motion in the energy range between 10 and 400 keV. Results indicate the likely existence of an asymmetry influenced by two competing effects: the nature of the stopping power and range straggling. The former tends to result in the Tail being greater than the Head and the latter the reverse. It has been found that for projected tracks the mean position of the ionization charge flows from 'head' to 'tail' with the magnitude depending on the ion type and its energy.Comment: To appear in the proceedings of Dark 2007 Sixth International Heidelberg conference on "Dark Matter in Astro & Particle Physics", Sydney, Australia 24th-28th September 200

    Asian-Americans and the Internet

    Get PDF
    Presents findings from a survey conducted between March and December 2001, to document the use of the Internet by English speaking Asian Americans. Looks at differences in online use by age, gender, education, and economic status

    Reduction of Coincident Photomultiplier Noise Relevant to Astroparticle Physics Experiment

    Full text link
    In low background and low threshold particle astrophysics experiments using observation of Cherenkov or scintillation light it is common to use pairs or arrays of photomultipliers operated in coincidence. In such circumstances, for instance in dark matter and neutrino experiments, unexpected PMT noise events have been observed, probably arising from generation of light from one PMT being detected by one or more other PMTs. We describe here experimental investigation of such coincident noise events and development of new techniques to remove them using novel pulse shape discrimination procedures. When applied to data from a low background NaI detector with facing PMTs the new procedures are found to improve noise rejection by a factor of 20 over conventional techniques, with significantly reduced loss of signal events.Comment: Submitted to NIM

    Non-invasive investigations of a wall painting using optical coherence tomography and hyperspectral imaging

    Get PDF
    Multispectral and hyperspectral imaging are efficient methods of measuring spectral reflectance at high spatial resolution. This non-invasive technique has been applied to the imaging of paintings over the last 20 years. PRISMS (Portable Remote Imaging System for Multispectral Scanning) was designed specifically for imaging wall paintings. Optical Coherence Tomography (OCT) is a low coherence interferometric technique capable of fast non-invasive imaging of subsurface microstructure. This paper shows the first application of in situ OCT imaging of a wall painting. The combination of PRISMS and OCT gives information on the varnish and paint layer structure, pigment identification, the state of degradation of the paint and varnish layers and informing curators on the painting schemes and techniques

    A small angle neutron scattering and Mössbauer spectrometry study of magnetic structures in nanocrystalline Ni3Fe

    Get PDF
    Results are reported from small angle neutron scattering and Mössbauer spectrometry measurements on nanocrystalline Ni3Fe. The nanocrystalline materials were prepared by mechanical attrition and studied in the as-milled state, after annealing at 265 °C to relieve internal stress, and after annealing 600 °C to prepare a control sample comprising large crystals. The small angle neutron scattering (SANS) measurements were performed for a range of applied magnetic fields. Small differences were found in how the different samples reached magnetic saturation. From the SANS data obtained at magnetic saturation, we found little difference in the nuclear scattering of the as-milled material and the material annealed at 265 °C. Reductions in nuclear scattering and magnetic scattering were observed for the control sample, and this was interpreted as grain growth. The material annealed at 265 °C also showed a reduction in magnetic SANS compared to the as-milled material. This was interpreted as an increase in magnetic moments of atoms at the grain boundaries after a low temperature annealing. Both Mössbauer spectroscopy and small angle neutron scattering showed an increase in the grain boundary magnetic moments after the 265 °C annealing (0.2 and 0.4µB/atom, respectively), even though there was little change in the grain boundary atomic density

    Evaluation and Benchmarking for Robot Motion Planning Problems Using TuLiP

    Get PDF
    Model checking is a technique commonly used in the verification of software and hardware. More recently, similar techniques have been employed to synthesize software that is correct by construction. TuLiP is a toolkit which interfaces with game solvers and model checkers to achieve this, producing a finite-state automaton representing a controller that satisfies the supplied specification. For motion planning in particular, a model checker may be employed in a deterministic scenario to produce a path satisfying a specification φ by checking against its negation ¬φ. If a counterexample is found, it will be a trace which satisfies φ. This was achieved in the TuLiP framework using the linear temporal logic (LTL) model checkers NuSMV and SPIN. A benchmark scenario based on a regular grid-world with obstacle and goal regions and reachability properties was devised, and extended to allow control of various complexity parameters, such as grid size, number of actors, specification type etc. Different measures of performance were explored, including CPU time, memory usage and path length, and the behavior of each checker with increasing problem complexity was analyzed using these metrics. The suitability of each checker for different classes and complexities of motion-planning problem was evaluated
    corecore