Monte Carlo simulations of trapped ultracold neutrons in the UCNτ experiment

Nathan Callahan; Chen Yu Liu; Francisco Gonzalez; E. Adamek; J. D. Bowman; L. Broussard; S. M. Clayton; S. Currie; C. Cude-Woods; E. B. Dees; X. Ding; W. Fox; P. Geltenbort; K. P. Hickerson; M. A. Hoffbauer; A. T. Holley; A. Komives; S. W.T. Macdonald; M. Makela; C. L. Morris; J. D. Ortiz; R. W. Pattie; J. Ramsey; D. J. Salvat; A. Saunders; E. I. Sharapov; S. K.L. Sjue; Z. Tang; J. Vanderwerp; B. Vogelaar; P. L. Walstrom; Z. Wang; H. Weaver; W. Wei; J. Wexler; A. R. Young

doi:10.1103/PhysRevC.100.015501

Monte Carlo simulations of trapped ultracold neutrons in the UCNτ experiment

Nathan Callahan, Chen Yu Liu, Francisco Gonzalez, E. Adamek, J. D. Bowman, L. Broussard, S. M. Clayton, S. Currie, C. Cude-Woods, E. B. Dees, X. Ding, W. Fox, P. Geltenbort, K. P. Hickerson, M. A. Hoffbauer, A. T. Holley, A. Komives, S. W.T. Macdonald, M. Makela, C. L. MorrisJ. D. Ortiz, R. W. Pattie, J. Ramsey, D. J. Salvat, A. Saunders, E. I. Sharapov, S. K.L. Sjue, Z. Tang, J. Vanderwerp, B. Vogelaar, P. L. Walstrom, Z. Wang, H. Weaver, W. Wei, J. Wexler, A. R. Young

Research output: Contribution to journal › Article › peer-review

Abstract

In the UCNτ experiment, ultracold neutrons (UCN) are confined by magnetic fields and the Earth's gravitational field. Field-trapping mitigates the problem of UCN loss on material surfaces, which caused the largest correction in prior neutron experiments using material bottles. However, the neutron dynamics in field traps differ qualitatively from those in material bottles. In the latter case, neutrons bounce off material surfaces with significant diffusivity and the population quickly reaches a static spatial distribution with a density gradient induced by the gravitational potential. In contrast, the field-confined UCN - whose dynamics can be described by Hamiltonian mechanics - do not exhibit the stochastic behaviors typical of an ideal gas model as observed in material bottles. In this report, we will describe our efforts to simulate UCN trapping in the UCNτ magnetogravitational trap. We compare the simulation output to the experimental results to determine the parameters of the neutron detector and the input neutron distribution. The tuned model is then used to understand the phase-space evolution of neutrons observed in the UCNτ experiment. We will discuss the implications of chaotic dynamics on controlling the systematic effects, such as spectral cleaning and microphonic heating, for a successful UCN lifetime experiment to reach a 0.01% level of precision.

Original language	English (US)
Article number	015501
Journal	Physical Review C
Volume	100
Issue number	1
DOIs	https://doi.org/10.1103/PhysRevC.100.015501
State	Published - Jul 8 2019
Externally published	Yes

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Nuclear and High Energy Physics

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10.1103/PhysRevC.100.015501

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Callahan, N., Liu, C. Y., Gonzalez, F., Adamek, E., Bowman, J. D., Broussard, L., Clayton, S. M., Currie, S., Cude-Woods, C., Dees, E. B., Ding, X., Fox, W., Geltenbort, P., Hickerson, K. P., Hoffbauer, M. A., Holley, A. T., Komives, A., Macdonald, S. W. T., Makela, M., ... Young, A. R. (2019). Monte Carlo simulations of trapped ultracold neutrons in the UCNτ experiment. Physical Review C, 100(1), [015501]. https://doi.org/10.1103/PhysRevC.100.015501

Callahan, N, Liu, CY, Gonzalez, F, Adamek, E, Bowman, JD, Broussard, L, Clayton, SM, Currie, S, Cude-Woods, C, Dees, EB, Ding, X, Fox, W, Geltenbort, P, Hickerson, KP, Hoffbauer, MA, Holley, AT, Komives, A, Macdonald, SWT, Makela, M, Morris, CL, Ortiz, JD, Pattie, RW, Ramsey, J, Salvat, DJ, Saunders, A, Sharapov, EI, Sjue, SKL, Tang, Z, Vanderwerp, J, Vogelaar, B, Walstrom, PL, Wang, Z, Weaver, H, Wei, W, Wexler, J & Young, AR 2019, 'Monte Carlo simulations of trapped ultracold neutrons in the UCNτ experiment', Physical Review C, vol. 100, no. 1, 015501. https://doi.org/10.1103/PhysRevC.100.015501

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title = "Monte Carlo simulations of trapped ultracold neutrons in the UCNτ experiment",

abstract = "In the UCNτ experiment, ultracold neutrons (UCN) are confined by magnetic fields and the Earth's gravitational field. Field-trapping mitigates the problem of UCN loss on material surfaces, which caused the largest correction in prior neutron experiments using material bottles. However, the neutron dynamics in field traps differ qualitatively from those in material bottles. In the latter case, neutrons bounce off material surfaces with significant diffusivity and the population quickly reaches a static spatial distribution with a density gradient induced by the gravitational potential. In contrast, the field-confined UCN - whose dynamics can be described by Hamiltonian mechanics - do not exhibit the stochastic behaviors typical of an ideal gas model as observed in material bottles. In this report, we will describe our efforts to simulate UCN trapping in the UCNτ magnetogravitational trap. We compare the simulation output to the experimental results to determine the parameters of the neutron detector and the input neutron distribution. The tuned model is then used to understand the phase-space evolution of neutrons observed in the UCNτ experiment. We will discuss the implications of chaotic dynamics on controlling the systematic effects, such as spectral cleaning and microphonic heating, for a successful UCN lifetime experiment to reach a 0.01% level of precision.",

author = "Nathan Callahan and Liu, {Chen Yu} and Francisco Gonzalez and E. Adamek and Bowman, {J. D.} and L. Broussard and Clayton, {S. M.} and S. Currie and C. Cude-Woods and Dees, {E. B.} and X. Ding and W. Fox and P. Geltenbort and Hickerson, {K. P.} and Hoffbauer, {M. A.} and Holley, {A. T.} and A. Komives and Macdonald, {S. W.T.} and M. Makela and Morris, {C. L.} and Ortiz, {J. D.} and Pattie, {R. W.} and J. Ramsey and Salvat, {D. J.} and A. Saunders and Sharapov, {E. I.} and Sjue, {S. K.L.} and Z. Tang and J. Vanderwerp and B. Vogelaar and Walstrom, {P. L.} and Z. Wang and H. Weaver and W. Wei and J. Wexler and Young, {A. R.}",

note = "Funding Information: We acknowledge the support from the NIST Precision Measurement Grant No. 00402661, the NSF Grant No. PHY-1614545, and the DOE Office of Science Graduate Student Research (SCGSR) program, through Contract No. DESC0014664. The simulation work used the Big Red II HPC, supported in part by Lilly Endowment, Inc., through its support for the Indiana University Pervasive Technology Institute and the Indiana METACyt Initiative. Publisher Copyright: {\textcopyright} 2019 American Physical Society.",

year = "2019",

month = jul,

day = "8",

doi = "10.1103/PhysRevC.100.015501",

language = "English (US)",

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AU - Callahan, Nathan

AU - Liu, Chen Yu

AU - Gonzalez, Francisco

AU - Adamek, E.

AU - Bowman, J. D.

AU - Broussard, L.

AU - Clayton, S. M.

AU - Currie, S.

AU - Cude-Woods, C.

AU - Dees, E. B.

AU - Ding, X.

AU - Fox, W.

AU - Geltenbort, P.

AU - Hickerson, K. P.

AU - Hoffbauer, M. A.

AU - Holley, A. T.

AU - Komives, A.

AU - Macdonald, S. W.T.

AU - Makela, M.

AU - Morris, C. L.

AU - Ortiz, J. D.

AU - Pattie, R. W.

AU - Ramsey, J.

AU - Salvat, D. J.

AU - Saunders, A.

AU - Sharapov, E. I.

AU - Sjue, S. K.L.

AU - Tang, Z.

AU - Vanderwerp, J.

AU - Vogelaar, B.

AU - Walstrom, P. L.

AU - Wang, Z.

AU - Weaver, H.

AU - Wei, W.

AU - Wexler, J.

AU - Young, A. R.

N1 - Funding Information: We acknowledge the support from the NIST Precision Measurement Grant No. 00402661, the NSF Grant No. PHY-1614545, and the DOE Office of Science Graduate Student Research (SCGSR) program, through Contract No. DESC0014664. The simulation work used the Big Red II HPC, supported in part by Lilly Endowment, Inc., through its support for the Indiana University Pervasive Technology Institute and the Indiana METACyt Initiative. Publisher Copyright: © 2019 American Physical Society.

PY - 2019/7/8

Y1 - 2019/7/8

N2 - In the UCNτ experiment, ultracold neutrons (UCN) are confined by magnetic fields and the Earth's gravitational field. Field-trapping mitigates the problem of UCN loss on material surfaces, which caused the largest correction in prior neutron experiments using material bottles. However, the neutron dynamics in field traps differ qualitatively from those in material bottles. In the latter case, neutrons bounce off material surfaces with significant diffusivity and the population quickly reaches a static spatial distribution with a density gradient induced by the gravitational potential. In contrast, the field-confined UCN - whose dynamics can be described by Hamiltonian mechanics - do not exhibit the stochastic behaviors typical of an ideal gas model as observed in material bottles. In this report, we will describe our efforts to simulate UCN trapping in the UCNτ magnetogravitational trap. We compare the simulation output to the experimental results to determine the parameters of the neutron detector and the input neutron distribution. The tuned model is then used to understand the phase-space evolution of neutrons observed in the UCNτ experiment. We will discuss the implications of chaotic dynamics on controlling the systematic effects, such as spectral cleaning and microphonic heating, for a successful UCN lifetime experiment to reach a 0.01% level of precision.

AB - In the UCNτ experiment, ultracold neutrons (UCN) are confined by magnetic fields and the Earth's gravitational field. Field-trapping mitigates the problem of UCN loss on material surfaces, which caused the largest correction in prior neutron experiments using material bottles. However, the neutron dynamics in field traps differ qualitatively from those in material bottles. In the latter case, neutrons bounce off material surfaces with significant diffusivity and the population quickly reaches a static spatial distribution with a density gradient induced by the gravitational potential. In contrast, the field-confined UCN - whose dynamics can be described by Hamiltonian mechanics - do not exhibit the stochastic behaviors typical of an ideal gas model as observed in material bottles. In this report, we will describe our efforts to simulate UCN trapping in the UCNτ magnetogravitational trap. We compare the simulation output to the experimental results to determine the parameters of the neutron detector and the input neutron distribution. The tuned model is then used to understand the phase-space evolution of neutrons observed in the UCNτ experiment. We will discuss the implications of chaotic dynamics on controlling the systematic effects, such as spectral cleaning and microphonic heating, for a successful UCN lifetime experiment to reach a 0.01% level of precision.

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Monte Carlo simulations of trapped ultracold neutrons in the UCNτ experiment

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