Demonstration of a solid deuterium source of ultra-cold neutrons

A. Saunders; J. M. Anaya; T. J. Bowles; B. W. Filippone; P. Geltenbort; R. E. Hill; M. Hino; S. Hoedl; G. E. Hogan; T. M. Ito; K. W. Jones; T. Kawai; K. Kirch; S. K. Lamoreaux; C. Y. Liu; M. Makela; L. J. Marek; J. W. Martin; C. L. Morris; R. N. Mortensen; A. Pichlmaier; S. J. Seestrom; A. Serebrov; D. Smith; W. Teasdale; B. Tipton; R. B. Vogelaar; A. R. Young; J. Yuan

doi:10.1016/j.physletb.2004.04.048

Demonstration of a solid deuterium source of ultra-cold neutrons

A. Saunders, J. M. Anaya, T. J. Bowles, B. W. Filippone, P. Geltenbort, R. E. Hill, M. Hino, S. Hoedl, G. E. Hogan, T. M. Ito, K. W. Jones, T. Kawai, K. Kirch, S. K. Lamoreaux, C. Y. Liu, M. Makela, L. J. Marek, J. W. Martin, C. L. Morris, R. N. MortensenA. Pichlmaier, S. J. Seestrom, A. Serebrov, D. Smith, W. Teasdale, B. Tipton, R. B. Vogelaar, A. R. Young, J. Yuan

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

Abstract

Ultra-cold neutrons (UCN), neutrons with energies low enough to be confined by the Fermi potential in material bottles, are playing an increasing role in measurements of fundamental properties of the neutron. The ability to manipulate UCN with material guides and bottles, magnetic fields, and gravity can lead to experiments with lower systematic errors than have been obtained in experiments with cold neutron beams. The UCN densities provided by existing reactor sources limit these experiments. The promise of much higher densities from solid deuterium sources has led to proposed facilities coupled to both reactor and spallation neutron sources. In this Letter we report on the performance of a prototype spallation neutron-driven solid deuterium source. This source produced bottled UCN densities of 145±7 UCN/cm³, about three times greater than the largest bottled UCN densities previously reported. These results indicate that a production UCN source with substantially higher densities should be possible.

Original language	English (US)
Pages (from-to)	55-60
Number of pages	6
Journal	Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics
Volume	593
Issue number	1-4
DOIs	https://doi.org/10.1016/j.physletb.2004.04.048
State	Published - Jul 22 2004
Externally published	Yes

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Nuclear and High Energy Physics

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10.1016/j.physletb.2004.04.048

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Saunders, A., Anaya, J. M., Bowles, T. J., Filippone, B. W., Geltenbort, P., Hill, R. E., Hino, M., Hoedl, S., Hogan, G. E., Ito, T. M., Jones, K. W., Kawai, T., Kirch, K., Lamoreaux, S. K., Liu, C. Y., Makela, M., Marek, L. J., Martin, J. W., Morris, C. L., ... Yuan, J. (2004). Demonstration of a solid deuterium source of ultra-cold neutrons. Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics, 593(1-4), 55-60. https://doi.org/10.1016/j.physletb.2004.04.048

Saunders, A, Anaya, JM, Bowles, TJ, Filippone, BW, Geltenbort, P, Hill, RE, Hino, M, Hoedl, S, Hogan, GE, Ito, TM, Jones, KW, Kawai, T, Kirch, K, Lamoreaux, SK, Liu, CY, Makela, M, Marek, LJ, Martin, JW, Morris, CL, Mortensen, RN, Pichlmaier, A, Seestrom, SJ, Serebrov, A, Smith, D, Teasdale, W, Tipton, B, Vogelaar, RB, Young, AR & Yuan, J 2004, 'Demonstration of a solid deuterium source of ultra-cold neutrons', Physics Letters, Section B: Nuclear, Elementary Particle and High-Energy Physics, vol. 593, no. 1-4, pp. 55-60. https://doi.org/10.1016/j.physletb.2004.04.048

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title = "Demonstration of a solid deuterium source of ultra-cold neutrons",

abstract = "Ultra-cold neutrons (UCN), neutrons with energies low enough to be confined by the Fermi potential in material bottles, are playing an increasing role in measurements of fundamental properties of the neutron. The ability to manipulate UCN with material guides and bottles, magnetic fields, and gravity can lead to experiments with lower systematic errors than have been obtained in experiments with cold neutron beams. The UCN densities provided by existing reactor sources limit these experiments. The promise of much higher densities from solid deuterium sources has led to proposed facilities coupled to both reactor and spallation neutron sources. In this Letter we report on the performance of a prototype spallation neutron-driven solid deuterium source. This source produced bottled UCN densities of 145±7 UCN/cm3, about three times greater than the largest bottled UCN densities previously reported. These results indicate that a production UCN source with substantially higher densities should be possible.",

author = "A. Saunders and Anaya, {J. M.} and Bowles, {T. J.} and Filippone, {B. W.} and P. Geltenbort and Hill, {R. E.} and M. Hino and S. Hoedl and Hogan, {G. E.} and Ito, {T. M.} and Jones, {K. W.} and T. Kawai and K. Kirch and Lamoreaux, {S. K.} and Liu, {C. Y.} and M. Makela and Marek, {L. J.} and Martin, {J. W.} and Morris, {C. L.} and Mortensen, {R. N.} and A. Pichlmaier and Seestrom, {S. J.} and A. Serebrov and D. Smith and W. Teasdale and B. Tipton and Vogelaar, {R. B.} and Young, {A. R.} and J. Yuan",

note = "Funding Information: This work has been supported by the DOE LDRD program and by the NSF 9420470, 9600202, 9807133, 0071856.",

year = "2004",

month = jul,

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doi = "10.1016/j.physletb.2004.04.048",

language = "English (US)",

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T1 - Demonstration of a solid deuterium source of ultra-cold neutrons

AU - Saunders, A.

AU - Anaya, J. M.

AU - Bowles, T. J.

AU - Filippone, B. W.

AU - Geltenbort, P.

AU - Hill, R. E.

AU - Hino, M.

AU - Hoedl, S.

AU - Hogan, G. E.

AU - Ito, T. M.

AU - Jones, K. W.

AU - Kawai, T.

AU - Kirch, K.

AU - Lamoreaux, S. K.

AU - Liu, C. Y.

AU - Makela, M.

AU - Marek, L. J.

AU - Martin, J. W.

AU - Morris, C. L.

AU - Mortensen, R. N.

AU - Pichlmaier, A.

AU - Seestrom, S. J.

AU - Serebrov, A.

AU - Smith, D.

AU - Teasdale, W.

AU - Tipton, B.

AU - Vogelaar, R. B.

AU - Young, A. R.

AU - Yuan, J.

N1 - Funding Information: This work has been supported by the DOE LDRD program and by the NSF 9420470, 9600202, 9807133, 0071856.

PY - 2004/7/22

Y1 - 2004/7/22

N2 - Ultra-cold neutrons (UCN), neutrons with energies low enough to be confined by the Fermi potential in material bottles, are playing an increasing role in measurements of fundamental properties of the neutron. The ability to manipulate UCN with material guides and bottles, magnetic fields, and gravity can lead to experiments with lower systematic errors than have been obtained in experiments with cold neutron beams. The UCN densities provided by existing reactor sources limit these experiments. The promise of much higher densities from solid deuterium sources has led to proposed facilities coupled to both reactor and spallation neutron sources. In this Letter we report on the performance of a prototype spallation neutron-driven solid deuterium source. This source produced bottled UCN densities of 145±7 UCN/cm3, about three times greater than the largest bottled UCN densities previously reported. These results indicate that a production UCN source with substantially higher densities should be possible.

AB - Ultra-cold neutrons (UCN), neutrons with energies low enough to be confined by the Fermi potential in material bottles, are playing an increasing role in measurements of fundamental properties of the neutron. The ability to manipulate UCN with material guides and bottles, magnetic fields, and gravity can lead to experiments with lower systematic errors than have been obtained in experiments with cold neutron beams. The UCN densities provided by existing reactor sources limit these experiments. The promise of much higher densities from solid deuterium sources has led to proposed facilities coupled to both reactor and spallation neutron sources. In this Letter we report on the performance of a prototype spallation neutron-driven solid deuterium source. This source produced bottled UCN densities of 145±7 UCN/cm3, about three times greater than the largest bottled UCN densities previously reported. These results indicate that a production UCN source with substantially higher densities should be possible.

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ER -

Demonstration of a solid deuterium source of ultra-cold neutrons

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