1. In situ resonant ultrasound spectroscopy for neutron scattering
- Author
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Yuya Shinohara, Andrew F. May, Raphaël P. Hermann, James R. Torres, Mariano Ruiz-Rodriguez, and V. R. Fanelli
- Subjects
Resonant ultrasound spectroscopy ,Neutron transport ,Cuboid ,Materials science ,Acoustics and Ultrasonics ,business.industry ,Oak Ridge National Laboratory ,Neutron scattering ,Optics ,Data acquisition ,Arts and Humanities (miscellaneous) ,Cylinder ,business ,Spallation Neutron Source - Abstract
Resonant ultrasound spectroscopy (RUS) is an efficient nondestructive technique to study the elastic properties of solid materials. In principle, the full elastic tensor can be determined for regularly shaped solids (e.g., sphere, cuboid, cylinder). Here, we report our progress in developing RUS probes for in situ neutron scattering at beamlines of the Spallation Neutron Source at Oak Ridge National Laboratory. A low-temperature (2–300 K) probe has been assembled and tested at the NOMAD and SEQUOIA beamlines to assess the probe’s neutronics, data acquisition system, and compatibility with the existing sample environment. Our discussion will include how the probe and data acquisition system operate as well as results for two measurements: bulk metallic glass (La65Cu20Al10Co5) and bismuth-antimony (Bi0.89Sb0.11 [1]). Assembly of a high-temperature (300–875 K) probe is currently underway and both probes are scheduled to be available to users by late-2021. Our aim is to provide users with live monitoring of an intrinsic variable at the neutron scattering beamlines, in addition to existing controls, to monitor the state of their samples and make informed decisions in real time. The probe developments are accompanied by developments of data acquisition and analysis software. 1. D. Vu et al., arXiv: 1906.02248 [cond-mat.mtrl-sci] (2019).
- Published
- 2021
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