Shielding Helium Cold neutron source Shutter Cooled filters Radial Collimators Variable Aperture Focusing monochromator on translation stage Focusing monochromator.

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Shielding Helium Cold neutron source Shutter Cooled filters Radial Collimators Variable Aperture Focusing monochromator on translation stage Focusing monochromator on translation stage 20 ft Focusing supermirror Aperture Attenuator Monitor Aperture Attenuator Monitor Sample position 20 channel detection system A “neutron microscope” for nano-scale motion in new materials Collin Broholm, Johns Hopkins University, DMR MACS will open a new window on atomic scale structure and dynamics at the early stages of materials development. Located at the NIST center for neutron research, the instrument employs a bold new configuration to probe minute crystals and man-made nano-structures.

High flux on small samples is achieved through a neutron focusing “Bragg lens”. The device reflects and concentrates neutrons from an area of 221 square inches to the sample. The flux will exceed that of conventional instrumentation by more than an order of magnitude. Maximizing neutron flux on small “hot” samples Collin Broholm, Johns Hopkins University, DMR pieces of graphite are accurately positioned to form a Bragg lens for exploring the nano-world. It was built at Johns Hopkins University by engineers with previous expertise in optics for astronomy The PI inspects the MACS incident beam line at the NIST Center for neutron research. Buried within shielding is the neutron focusing Bragg lens, which moves along the reactor beam to select different neutron energies. The circular region where the PI stands will accommodate an adjustable super-mirror guide that further concentrates reflected neutrons on the sample. Engineering by P. Brand, M. English, R.Hammond, P. Hundertmark, J. LaRock, J. Moyer, J. Orndorff, D. Pierce, T. Pike, G. Scharfstein, S. Smee, et al.

Window on the nano-world: A multi-channel neutron detector Collin Broholm, Johns Hopkins University, DMR ×20 The centerpiece in each channel is a vertically focusing double crystal analyzer system actuated by a single motor. Engineering by C. Brocker, Z. Huang, P. Hundertmark, N. Maliszewskyj, T. Pike et al. Neutron scattering showing quasi-particle decay in a quantum spin liquid (Stone et al Science (2006)) 20 channels operate simultaneously to detect an order of magnitude more neutrons than conventional instrumentation.