Sangam: A Confluence of Knowledge Streams

A Magneto-Gravitational Neutron Trap for the Measurement of the Neutron Lifetime

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dc.contributor Liu, Chen-Yu
dc.creator Salvat, Daniel Joseph
dc.date 2015-04-19T07:23:08Z
dc.date 2015-04-19T07:23:08Z
dc.date 2015-04
dc.date 2015
dc.date.accessioned 2023-02-21T11:19:38Z
dc.date.available 2023-02-21T11:19:38Z
dc.identifier http://hdl.handle.net/2022/19794
dc.identifier.uri http://localhost:8080/xmlui/handle/CUHPOERS/253007
dc.description Thesis (Ph.D.) - Indiana University, Physics, 2015
dc.description Neutron decay is the simplest example of nuclear beta-decay. The mean decay lifetime is a key input for predicting the abundance of light elements in the early universe. A precise measurement of the neutron lifetime, when combined with other neutron decay observables, can test for physics beyond the standard model in a way that is complimentary to, and potentially competitive with, results from high energy collider experiments. Many previous measurements of the neutron lifetime used ultracold neutrons (UCN) confined in material bottles. In a material bottle experiment, UCN are loaded into the apparatus, stored for varying times, and the surviving UCN are emptied and counted. These measurements are in poor agreement with experiments that use neutron beams, and new experiments are needed to resolve the discrepancy and precisely determine the lifetime. Here we present an experiment that uses a bowl-shaped array of NdFeB magnets to confine neutrons without material wall interactions. The trap shape is designed to rapidly remove higher energy UCN that might slowly leak from the top of the trap, and can facilitate new techniques to count surviving UCN within the trap. We review the scientific motivation for a precise measurement of the neutron lifetime, and present the commissioning of the trap. Data are presented using a vanadium activation technique to count UCN within the trap, providing an alternative method to emptying neutrons from the trap and into a counter. Potential systematic effects in the experiment are then discussed and estimated using analytical and numerical techniques. We also investigate solid nitrogen-15 as a source of UCN using neutron time-of-flight spectroscopy. We conclude with a discussion of forthcoming research and development for UCN detection and UCN sources.
dc.language en
dc.publisher [Bloomington, Ind.] : Indiana University
dc.subject magnetic trap
dc.subject neutron lifetime
dc.subject neutron scattering
dc.subject solid nitrogen
dc.subject ultracold neutrons
dc.subject vanadium
dc.subject Physics
dc.subject Particle physics
dc.subject Nuclear physics
dc.title A Magneto-Gravitational Neutron Trap for the Measurement of the Neutron Lifetime
dc.type Doctoral Dissertation


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