Difference between revisions of "Publications"

From DoyleGroup
Jump to: navigation, search
(Other Documents)
m (Publications)
Line 45: Line 45:
 
# [[Media:PRL_103_103005_2009.pdf | Buffer-gas cooled Bose-Einstein condensate]], S. C. Doret, C. B. Connolly, W. Ketterle, and J. M. Doyle.  PRL '''103''', 103005 (2009).
 
# [[Media:PRL_103_103005_2009.pdf | Buffer-gas cooled Bose-Einstein condensate]], S. C. Doret, C. B. Connolly, W. Ketterle, and J. M. Doyle.  PRL '''103''', 103005 (2009).
 
# [http://arxiv.org/PS_cache/arxiv/pdf/0908/0908.2412v1.pdf Search for the electric dipole moment of the electron with thorium monoxide], A. Vutha, W. Campbell, Y. Gurevich, N. Hutzler, M. Parsons, D. Patterson, E. Petrik, B. Spaun, J. Doyle, G. Gabrielse, D. DeMille.  Submitted to J. Phys. B.
 
# [http://arxiv.org/PS_cache/arxiv/pdf/0908/0908.2412v1.pdf Search for the electric dipole moment of the electron with thorium monoxide], A. Vutha, W. Campbell, Y. Gurevich, N. Hutzler, M. Parsons, D. Patterson, E. Petrik, B. Spaun, J. Doyle, G. Gabrielse, D. DeMille.  Submitted to J. Phys. B.
# [[Media:PhysRevA_81_010702R.pdf | Large spin relaxation rates in trapped submerged-shell atoms]], C. B. Connolly, Y. S. Au, S. C. Doret, W. Ketterle, J. M. Doyle.  Phys Rev A '''81''' 010702(R) (2010).
+
# [[Media:PhysRevA_81_010702R.pdf | Large spin relaxation rates in trapped submerged-shell atoms]], C. B. Connolly, Y. S. Au, S. C. Doret, W. Ketterle, J. M. Doyle.  Phys Rev A '''81''', 010702(R) (2010).
 
# Zeeman Relaxation of Cold Atomic Iron and Nickel in Collisions with 3He.  Cort Johnson, Bonna Newman, Nathan Brahms, John Doyle, Dan Kleppner and Tom Greytak.  (To be published.  Please contact first author for details.)  [http://laserstorm.harvard.edu/wiki/index.php/Internal:Main_Page Draft.] (Login required.)
 
# Zeeman Relaxation of Cold Atomic Iron and Nickel in Collisions with 3He.  Cort Johnson, Bonna Newman, Nathan Brahms, John Doyle, Dan Kleppner and Tom Greytak.  (To be published.  Please contact first author for details.)  [http://laserstorm.harvard.edu/wiki/index.php/Internal:Main_Page Draft.] (Login required.)
 
# Magnetic reorientation in collisions of trapped atomic dysprosium.  Bonna Newman, Nathan Brahms, Yat Shan Au, Cort Johnson, Colin Connolly, John M. Doyle, Daniel Kleppner and Thomas J. Greytak.  (To be published.  Please contact first author for details.)  [http://laserstorm.harvard.edu/wiki/index.php/Internal:Main_Page Draft.] (Login required.)
 
# Magnetic reorientation in collisions of trapped atomic dysprosium.  Bonna Newman, Nathan Brahms, Yat Shan Au, Cort Johnson, Colin Connolly, John M. Doyle, Daniel Kleppner and Thomas J. Greytak.  (To be published.  Please contact first author for details.)  [http://laserstorm.harvard.edu/wiki/index.php/Internal:Main_Page Draft.] (Login required.)

Revision as of 12:34, 5 April 2010

Buffer Gas Cooling

Publications

More publications under the neutron section

  1. Buffer-gas loading of atoms and molecules into a magnetic trap. John M. Doyle, Bretislav Friedrich, Jinha Kim and David Patterson. Physical Review A, 52 (4), pp. R2515-2518 (1995)
  2. Buffer-Gas Loading and Magnetic Trapping of Atomic Europium. Jinha Kim, Bretislav Friedrich, Daniel P. Katz, David Patterson, Jonathan D. Weinstein, Robert DeCarvalho, and John M. Doyle. Physical Review Letters, 78 (19), pp.3665-3668 (1997)
  3. Magnetic Trapping of Atomic Chromium. J. D. Weinstein, Robert deCarvalho, Jinha Kim, David Patterson, Bretislav Friedrich, and John M. Doyle. Physical Review A, 57 (5) pp.R3173-R3175 (1998)
  4. Towards magnetic trapping of molecules, B. Friedrich, R. deCarvalho, J. Kim, D. Patterson, J.D. Weinstein, and J.M Doyle, J. Chem. Soc., Faraday Trans. 94 1783-91 (1998).
  5. Spectroscopy of Buffer-gas Cooled Vanadium Monoxide in a Magnetic Trapping Field. Jonathan D. Weinstein, Robert deCarvalho, Karine Amar, Andrea Boca, Brian C. Odom, Bretislav Friedrich, and John M. Doyle. Journal of Chemical Physics, 109 (7) pp. 2656-2661 (1998)
  6. Magnetic trapping of calcium monohydride molecules at milliKelvin temperatures. Jonathan D. Weinstein, Robert deCarvalho, Thierry Guillet, Bretislav Friedrich, and John M. Doyle. Nature, 395, pp. 148-150 (1998)
  7. Zeeman spectroscopy of CaH molecules in a magnetic trap. Bretislav Friedrich, Jonathan D. Weinstein, Robert deCarvalho, and John M. Doyle. The Journal of Chemical Physics 110, pp. 2376-2383 (1999)
  8. Buffer-gas loaded magnetic traps for atoms and molecules: a primer. Robert deCarvalho, John M. Doyle, Bretislav Friedrich, Thierry Guillet, Jinha Kim, David Patterson, and Jonathan D. Weinstein. European Physical Journal D 7, pp. 289-309 (1999)
  9. Simulation of the hyperfine-resloved Zeeman spectrum of Eu atoms in a magnetic trap. Long Cai, B. Friedrich, and John M. Doyle. Phys. Rev. A 61, 033412 (2000)
  10. Spectroscopy of laser-ablated buffer-gas-cooled PbO at 4 K and the prospects for measuring the electric dipole moment of the electron. D. Egorov, J. D. Weinstein, D. Patterson, B. Friedrich, and J. M. Doyle. Phys Rev A 63 030501 (2001)
  11. Evaporative cooling of atomic chromium. Jonathan D. Weinstein, Robert deCarvalho, Cindy I. Hancox, and John M. Doyle. Phys Rev A 65 (2), 021604(R) (2002)
  12. Buffer-gas cooling of atomic and molecular beams. Dima Egorov, Thierry Lahaye, Wieland Schöllkopf, Bretislav Friedrich, and John M. Doyle. Phys Rev A 66, 043401 (2002)
  13. Enhanced inelastic scattering rates of cold atomic chromium. Robert deCarvalho, Cindy I. Hancox, and John M. Doyle. J. Opt. Soc. Am. B 20, No. 5, 1131 (2003)
  14. Deep superconducting magnetic traps for neutral atoms and molecules. J.G.E. Harris, W.C. Campbell, D. Egorov, S.E. Maxwell, R.A. Michniak, S.V. Nguyen, L.D. van Buuren, J.M. Doyle. Review of Scientific Instruments 75, 14 (2004).
  15. Magnetic Trapping of the rare-earth atoms at milliKelvin temperatures, C.I. Hancox, S.C. Doret, M.T. Hummon, L. Luo, J.M. Doyle. Nature 431, 281 (2004).
  16. Buffer gas cooling and trapping of atoms with small effective magnetic moments, J.G.E. Harris, R.A. Michniak, S.V. Nguyen, N. Brahms, W. Ketterle, J.M. Doyle, Europhysics Letters 67, 198 (2004).
  17. Evaporative cooling at low trap depth. R. deCarvalho, J.M. Doyle. Phys Rev A 70, 053409 (2004).
  18. Buffer-gas cooling of NH via the beam loaded buffer-gas method, D. Egorov, W.C. Campbell, B. Friedrich, S.E. Maxwell, E. Tsikata, L.D. van Buuren, J.M. Doyle. European Physical Journal D 31, 307 (2004)
  19. Zeeman Effect in CaF, R.V. Krems, D. Egorov, J.S. Helton, K. Maussang, S.V. Nguyen, J.M. Doyle. J. Chem. Phys. 121, 11639 (2004)
  20. Supression of angular momentum transfer in cold collisions of non-S-state transition metal atoms, C.I. Hancox, S.C. Doret, M. Hummon, R. Krems, J.M. Doyle. Phys Rev Lett 94, 013201 (2004).
  21. Evaporative cooling of magnetically trapped atomic molybdenum, C.I. Hancox, M.T. Hummon, S.V. Nguyen, J.M. Doyle, Phys Rev A 71, 031402 (2004)
  22. Zeeman relaxation of CaF in low temperature collisions with helium, K. Maussang, D. Egorov, J.S. Helton, S.V. Nguyen, J.M. Doyle, Phys Rev Lett 94, 123002 (2004)
  23. Magnetic trapping of an atomic Mn-Cr mixture, S.V. Nguyen, J.S. Helton, K. Maussang, W. Ketterle, J.M. Doyle, Phys Rev A 71,0256602 (2005)
  24. High-Flux Beam Source for Cold, Slow Atoms or Molecules, S.E. Maxwell, N. Brahms, R. deCarvalho, D.R. Glenn, J.S. Helton, S.V. Nguyen, D. Patterson, J. Petricka, D. DeMille, J.M. Doyle. Phys Rev Lett 95, 173201 (2005)
  25. Evaporative cooling of metastable helium in the multi-partial-wave regime, S.V. Nguyen, S.C. Doret, C.B. Connolly, R.A. Michniak, W. Ketterle, and J.M. Doyle. Phys Rev A 72, 060703(R) (2005).
  26. Cold 52Cr elastic and inelastic collision-rate determination using evaporative cooling analysis, Scott V. Nguyen, Robert deCarvalho, and John M. Doyle. Phys Rev A 75, 062706 (2007)
  27. Magnetic Trapping and Zeeman Relaxation of NH (X-triplet-Sigma), W.C. Campbell, E. Tsikata, H. Lu, L.D. van Buuren, and J.M. Doyle. Phys Rev Lett 98, 213001 (2007).
  28. A Bright, Guided Molecular Beam with Hydrodynamic Enhancement, D. Patterson and J.M. Doyle. accepted for publication in Journal of Chemical Physics.
  29. Spin-exchange collisions of submerged shell atoms below 1 Kelvin, J.G.E. Harris, S.V. Nguyen, S.C. Doret, W. Ketterle, and J.M. Doyle. Phys Rev Lett 99, 223201 (2007).
  30. Time-Domain Measurement of Spontaneous Vibrational Decay of Magnetically Trapped NH, W.C. Campbell, G.C. Groenenboom, H. Lu, E. Tsikata, J.M. Doyle. Phys Rev Lett 100, 083003 (2008).
  31. Inelastic Collisions in Optically Trapped Ultracold Metastable Ytterbium, A. Yamaguchi, S. Uetake, D. Hashimoto, J. M. Doyle, and Y. Takahashi. Phys. Rev. Lett 101, 233002 (2008).
  32. Magnetic trapping of atomic nitrogen (^14N) and cotrapping of NH (X-triplet-Sigma-), M.T. Hummon, W.C. Campbell, H. Lu, E. Tsikata, Y. Wang, and J.M. Doyle, Phys Rev A 78, 050702(R) (2008).
  33. Novel Coherent Optical Medium Based on Buffer-Gas-Cooled Rb Vapor, T. Hong, A. V. Gorshkov, D. Patterson, A. S. Zibrov, J. M. Doyle, M. D. Lukin, and M. G. Prentiss. Phys. Rev. A 79, 013806 (2009).
  34. Magnetic trapping of silver and copper, and anomolous spin relaxation in the Ag-He system, N. Brahms, B. Newman, C. Johnson, T. Greytak, D. Kleppner, J. Doyle. Phys Rev Lett 101, 103002 (2008).
  35. Collision-induced spin depolarization of alkali metal atoms in cold 3He gas, T. V. Tscherbul, P. Zhang, H. R. Sadeghpour, A. Dalgarno, N. Brahms, Y. S. Au, and J. M. Doyle. Phys Rev A 78, 060703(R) (2008).
  36. Spin-orbit interaction and large inelastic rates in bismuth-helium collisions, S. E. Maxwell, M. T. Hummon, Y. Wang, A. A. Buchachenko, R. V. Krems, and J. M. Doyle, Phys Rev A 78, 042706 (2008).
  37. Mechanism of Collisional Spin Relaxation in Triplet-Sigma Molecules, W.C. Campbell, T. V. Tscherbul, H.-I Lu, E. Tsikata, R. V. Krems, and J.M. Doyle. Phys Rev Lett 102, 013003 (2009).
  38. Intense atomic and molecular beams via neon buffer-gas cooling, D. Patterson, J. Rasmussen, and J.M. Doyle. New Journal of Physics 11, 055018 (2009).
  39. Buffer-gas cooled Bose-Einstein condensate, S. C. Doret, C. B. Connolly, W. Ketterle, and J. M. Doyle. PRL 103, 103005 (2009).
  40. Search for the electric dipole moment of the electron with thorium monoxide, A. Vutha, W. Campbell, Y. Gurevich, N. Hutzler, M. Parsons, D. Patterson, E. Petrik, B. Spaun, J. Doyle, G. Gabrielse, D. DeMille. Submitted to J. Phys. B.
  41. Large spin relaxation rates in trapped submerged-shell atoms, C. B. Connolly, Y. S. Au, S. C. Doret, W. Ketterle, J. M. Doyle. Phys Rev A 81, 010702(R) (2010).
  42. Zeeman Relaxation of Cold Atomic Iron and Nickel in Collisions with 3He. Cort Johnson, Bonna Newman, Nathan Brahms, John Doyle, Dan Kleppner and Tom Greytak. (To be published. Please contact first author for details.) Draft. (Login required.)
  43. Magnetic reorientation in collisions of trapped atomic dysprosium. Bonna Newman, Nathan Brahms, Yat Shan Au, Cort Johnson, Colin Connolly, John M. Doyle, Daniel Kleppner and Thomas J. Greytak. (To be published. Please contact first author for details.) Draft. (Login required.)
  44. Suppression of Zeeman relaxation in cold collisions of [sup 2]P[sub 1/2] atoms. Tscherbul, T., Buchachenko, A., Dalgarno, A., Lu, M.-J., and Weinstein, J. Phys. Rev. A 80, 040701(R) (2009)
  45. Cooling, trap loading, and beam production using a cryogenic helium buffer gas - Draft Copy. W. Campbell and J. Doyle. From Cold Molecules: Theory, Experiment, Applications R. Krems et al (2009).
  46. Magnetic Trapping of NH Molecules with 20 s Lifetimes. E Tsikata, W Campbell, M Hummon, H-I Lu, J Doyle. Submitted for Publication.

Theses

More theses under the neutron section.

  1. Jinha Kim. Buffer-gas Loading and Magnetic Trapping of Atomic Europium. Harvard University, 1997.
  2. Jonathan David Weinstein. Magnetic Trapping of Atomic Chromium and Molecular Calcium Monohydride. Harvard University, 2002.
  3. Robert deCarvalho. Inelastic Scattering of Magnetically Trapped Atomic Chromium. Harvard University, 2003.
  4. Bob Michniak. Enhanced Buffer Gas Loading:Cooling and Trapping of Atoms with Low Effective Magnetic Moments. Harvard University, 2004.
  5. Dimitri Egorov. Buffer-Gas Cooling of Diatomic Molecules. Harvard University, 2004.
  6. Cindy Hancox. Magnetic Trapping of transition-metal and rare-earth atoms using buffer gas loading. Harvard University, 2005.
  7. Scott Nguyen. Buffer Gas Loading and Evaporative Cooling in the Multi-Partial-Wave Regime. Harvard University, 2006.
  8. Stephen Maxwell. Buffer gas cooled atoms and molecules: production, collisional studies, and applications. Harvard University, 2007.
  9. Wes Campbell. Magnetic Trapping of Imidogen Molecules. Harvard University, 2008.
  10. Cort Johnson. Zeeman Relaxation of Cold Iron and Nickel in Collisions with 3He. MIT, 2008. Errata.
  11. Nathaniel Brahms. Trapping of 1 mu B atoms using buffer gas loading. Harvard University, 2008. Errata.
  12. Bonna Newman.Trapped Atom Collisions and Evaporative Cooling of non-S State Atoms. MIT, 2008. Errata.
  13. Edem Tsikata. Magnetic Trapping and Thermal Isolation of NH Molecules Using the Buffer Gas Technique. Harvard University, 2009
  14. Stephen Charles Doret. A Buffer-gas Cooled Bose Einstein Condensate. Harvard University, 2009
  15. Matthew Hummon. Magnetic trapping of atomic nitrogen and cotrapping of NH. Harvard University, 2010.

Polar Molecules and Quantum Computation

  1. A coherent all-electrical interface between polar molecules and mesoscopic superconducting resonators, A. Andre, D. DeMille, J.M. Doyle, M.D. Lukin, S.E. Maxwell, P. Rabl, R.J. Schoelkopf, and P. Zoller. Nature Physics, 2, 636 (2006).
  2. Hybrid Quantum Processors: Molecular Ensembles as Quantum Memory for Solid State Circuits, P. Rabl, D. DeMille, J.M. Doyle, M.D. Lukin, R.J. Shoelkopf, and P. Zoller. Physical Review Letters, 97, 033003 (2006).

Neutrons

Publications

  1. On Measuring the Neutron Beta-Decay Lifetime using Ultracold Neutrons Produced and Stored in a Superfluid-4He-Filled Magnetic Trap. J. M. Doyle and S. K. Lamoreaux. Europhysics Letters, 26, 253 (1994).
  2. Fluorescence Efficiencies of Thin Scintillating Films in the Extreme Ultraviolet Spectral Region. D. N. McKinsey, C. R. Brome, J. S. Butterworth, R. Golub, K. Habicht, P. R. Huffman, S. K. Lamoreaux, C. E. H. Mattoni and J. M. Doyle. Nuclear Instruments and Methods B, 132, 351 (1997).
  3. Statistical planning for a neutron lifetime experiment using magnetically trapped neutrons. K. J. Coakley. Nuclear Instruments and Methods A, 406, 451 (1998).
  4. A Demountable Cryogenic Feedthrough for Plastic Optical Fibers. J. S. Butterworth, C. R. Brome, P. R. Huffman, C. E. H. Mattoni, D. N. McKinsey, and J. M. Doyle. Review of Scientific Instruments, 69, 3697 (1998).
  5. A Removable Cryogenic Window for Transmission of Light and Neutrons. J. S. Butterworth, C. R. Brome, P. R. Huffman, C. E. H. Mattoni, D. N. McKinsey, and J. M. Doyle. Review of Scientific Instruments, 69, 3998 (1998).
  6. The Radiative Lifetime of the Metastable Helium Molecule He2*(3Sigmau+) in Liquid Helium. D. N. McKinsey, C. R. Brome, J. S. Butterworth, S. Dzhosyuk, R. Golub, K. Habicht, P. R. Huffman, S. K. Lamoreaux, C. E. H. Mattoni, and J. M. Doyle. Physical Review A, 59, 200 (1999).
  7. Progress Towards Magnetic Trapping of Ultracold Neutrons. P. R. Huffman, C. R. Brome, J. S. Butterworth, K. J. Coakley, M. S. Dewey, S. N. Dzhosyuk, D. M. Gilliam, R. Golub, G. L. Greene, K. Habicht, S. K. Lamoreaux, C. E. H. Mattoni, D. N. McKinsey, F. E. Wietfeldt, and J. M. Doyle. Nuclear Instruments and Methods A, 440(3), 522-527 (2000).
  8. Magnetic Trapping of Neutrons. P. R. Huffman, C. R. Brome, J. S. Butterworth, K. J. Coakley, M. S. Dewey, S. N. Dzhosyuk, R. Golub, G. L. Greene, K. Habicht, S. K. Lamoreaux, C. E. H. Mattoni, D. N. McKinsey, F. E. Wietfeldt, and J. M. Doyle. Nature, 403, 62-64 (2000).
  9. Liquid Helium and Neon - Sensitive, Low Background Scintillation Media For the Detection of Low Energy Neutrinos. D. N. McKinsey and J. M. Doyle. Journal of Low Temperature Physics, 118 153-165 (2000).
  10. Likelihood models for two-stage neutron lifetime experiments. G. L. Yang and K. J. Coakley. Physical Review C, 63, 014602 (2000).
  11. Magnetically Stabilized Luminescent Excitations in Hexagonal Boron Nitride. P. R. Huffman, C. R. Brome, J. S. Butterworth, S. N. Dzhosyuk, R. Golub, S. K. Lamoreaux, C. E. H. Mattoni, D. N. McKinsey, F. E. Wietfeldt, and J. M. Doyle. Journal of Luminescence, 92, 291-296 (2001).
  12. Magnetic trapping of ultracold neutrons. C. R. Brome, J. S. Butterworth, K. J. Coakley, M. S. Dewey, S. N. Dzhosyuk, R. Golub, G. L. Greene, K. Habicht, P. R. Huffman, S. K. Lamoreaux, C. E. H. Mattoni, D. N. McKinsey, F. E. Wietfeldt, and J. M. Doyle. Physical Review C, 63, 055502 (2001).
  13. [http://jsbach.harvard.edu/neutron/publications/Papers/background.pdf Neutron lifetime experiments using magnetically trapped neutrons: optimal background correction strategies. K. J. Coakley. Nuclear Instruments and Methods A, 469, 354 (2001).
  14. Estimation of the neutron lifetime: Comparison of methods which account for background. K. J. Coakley and G. L. Yang. Physical Review C, 65, 064612 (2002).
  15. Progress Towards Measurement of the Neutron Lifetime Using Magnetically Trapped Ultracold Neutrons. P. R. Huffman, K. J. Coakley, S. N. Dzhosyuk, R. Golub, E. Korobkina, S. K. Lamoreaux, C. E. H. Mattoni, D. N. McKinsey, A.K. Thompson, G. L. Yang, L. Yang, and J. M. Doyle. To appear in the conference proceedings for the "Quark-mixing, CKM Unitarity" workshop held in Heidelberg, 19-20 September 2002. To be published online at arXiv.org.
  16. Time dependence of liquid-helium fluorescence. D. N. McKinsey, C. R. Brome, S. N. Dzhosyuk, R. Golub, K. Habicht, P. R. Huffman, E. Korobkina, S. K. Lamoreaux, C. E. H. Mattoni, A. K. Thompson, and J. M. Doyle. Physical Review A, 67, 062716 (2003).
  17. Performance of a large-area avalanche photodiode at low temperature for scintillation detection. L. Yang, S. N. Dzhosyuk, J. M. Gabrielse, C. E. H. Mattoni, S. E. Maxwell, D. N. McKinsey, J. M. Doyle. Nuclear Instruments and Methods A, 508, 388 (2003).
  18. Detecting ionizing radiation in liquid helium using wavelength shifting light collection. D. N. McKinsey, C. R. Brome, J. S. Butterworth, S. N. Dzhosyuk, R. Golub, K. Habicht, P R. Huffman, C. E. H. Mattoni, L. Yang, J. M. Doyle. Nuclear Instruments and Methods A, 516, 475 (2004).
  19. A long wavelength neutron monochromator for superthermal production of ultracold neutrons. C. E. H. Mattoni, C. P. Adams,K. J. Alvine, J M. Doyle, S. N. Dzhosyuk, R. Golub, E. Korobkina, D. N. McKinsey, A. K. Thompson, L. Yang, H. Zabel, and P. R. Huffman. Physica B 344, 343-357 (2003).
  20. Neutron-induced luminescence and activation in neutron shielding and scintillation detection materials at cryogenic temperatures. S. N. Dzhosyuk, C. E. H. Mattoni, D. N. McKinsey, A. K. Thompson, L. Yang, J M. Doyle, and P. R. Huffman. Nuclear Instrumentation and Methods B 217, 457 (2004).
  21. The production of nitrogen-13 by neutron capture in boron compounds. M. H. Schleier-Smith, L. D. van Buuren, J M. Doyle, S. N. Dzhosyuk, D. M. Gilliam, C. E. H. Mattoni, D. N. McKinsey, L. Yang, and P. R. Huffman. Nuclear Instrumentation and Methods B 215, 531 (2004)
  22. A high-field, low-current superconducting Ioffe magnetic trap. S.N. Dzhosyuk, C.R. Brome, J.S. Butterworth, P.R. Huffman, C.E.H. Mattoni, D.N. McKinsey, R.A. Michniak, L. Yang, and J.M. Doyle, IEEE Trans. on Applied Superconductivity, (submitted 8/2004)
  23. Chaotic Scattering of Marginally Trapped Neutrons, K.J. Coakley, J.M. Doyle, S.N. Dzhosyuk, L. Yang, and P.R. Huffman, lto be submitted (2004)
  24. Invited Article: Development of high-field superconducting Ioffe magnetic traps, L. Yang, C. R. Brome, J. S. Butterworth, S. N. Dzhosyuk, C. E. H. Mattoni, D. N. McKinsey, R. A. Michniak, J. M. Doyle, R. Golub, E. Korobkina, C. M. O’Shaughnessy, G. R. Palmquist, P.-N. Seo, P. R. Huffman, K. J. Coakley, H. P. Mumm, A. K. Thompson, G. L. Yang, and S. K. Lamoreaux. Review of Scientific Instruments 79, 031301 (2008)

Graduate Theses

  1. Klaus Habicht. Szintillationen in flüssigem Helium - ein Detektor für ultrakalte Neutronen. Technischen Universität Berlin, 1998.
  2. Clinton Reed Brome. Magnetic Trapping of Ultracold Neutrons. Harvard University, 2000.
  3. Daniel Nicholas McKinsey. Detection of Magnetically Trapped Neutrons: Liquid Helium As a Scintillator. Harvard University, 2002.
  4. Carlo Egon Heinrich Mattoni. Magnetic Trapping of Ultracold Neutrons Produced Using a Monochromatic Cold Neutron Beam. Harvard University, 2002.
  5. Sergei N. Dzhosyuk. Magnetic Trapping of Neutrons for Measurement of the Neutron Lifetime. Harvard University, 2004.
  6. Liang Yang. Towards Precision Measurement of the Neutron Lifetime using Magnetically Trapped Neutrons. Harvard University, 2006.

Undergraduate Theses

  1. Carlo Egon Heinrich Mattoni. The Precision Measurement of the Neutron Lifetime Using Magnetically Trapped Neutrons: Marginally Trapped Neutrons and Fluorescent Time Constants. Harvard University, 1995.
  2. Hayn Park. Thermal Neutron Detection Using Boron-10 and Sodium Salicylate Doped Epoxy Films. Harvard University, 1996.
  3. Irfan Ahmed Siddiqi. Absolute Quantum Efficiency Measurements of a Prototype Ultra-Cold Neutron in Liquid Helium Detection System. Harvard University, 1997.

Other Documents

  1. Notes on the theory of dynamical diffraction applied to neutrons. Anonymous
  2. Bobby learns quantum computing. Anonymous
  3. Quantum Mechanics For Advanced Beginners. R. Golub and R. Ince
  4. Permeability of noble gases through Kapton, butyl, nylon, and ‘‘SilverShield’’, S. J. Schowalter, C. B. Connolly, J. M. Doyle. Nuclear Instruments and Methods in Physical Research Section A 615 257 (2010).