Publications: Quantum Nonequilibrium & Integrable Systems Group @ UMB

Books

[Olsh13] Maxim Olshanii, Back-of-the-Envelope Quantum Mechanics: With Extensions to Many-Body Systems and Integrable PDEs (World Scientific (2013))

Invited reviews, editorials, etc

[DO18] Vanja Dunjko and Maxim Olshanii, Escape the thermal fate, Nature Physics, 14th (May 2018)
Adolfo del Campo, Maxim Olshanii, and Gregory Astrakharchik, Marvin Denham Girardeau Obituary, Physics Today, 68, 64 (May 2015)
[DO13] Vanja Dunjko and Maxim Olshanii, Thermalization in isolated quantum systems, Annual Review on Cold Atoms (World Scientific (2013))

[DMBO11] Vanja Dunjko, Michael G. Moore, Thomas Bergeman, and Maxim Olshanii, Confinement-Induced Resonances, Advances in Atomic, Molecular, and Optical Physics, 60, 461 (2011)
[YuOW08] Vladimir Yurovsky, Maxim Olshanii, and David Weiss, Collisions, Correlations, and Integrability in Atom Waveguides, Advances in Atomic, Molecular, and Optical Physics, 55, 62 (2008)
[PPO04] L. Pricoupenko, H. Perrin and M. Olshanii (Editors), Quantum Gases in Low Dimensions, Les Houches School, (2003), J. Phys. IV France 116, III-IV (2004)
[LOO95] V. S. Letokhov, M. A. Ol'shanii, and Yu. B. Ovchinnikov, Laser Cooling of Atoms, Quantum Optics 7, 5 (1995)
[Olsh94] M. Ol'shanii, Atomic Interferometry, Laser Physics 4, 995 (1994)

Papers

Bethe Ansatz, Giragdeau's Fermi-Bose map, etc

[OSYDJ19] ^ Maxim Olshanii, Yuri Styrkas, Dmitry Yampolsky, Vanja Dunjko, Steven G. Jackson, Four-dimensional reflection groups and electrostatics, [ arXiv:1904.04655 ] (Apr 2019)
[GMO19] ^ Juan Polo Gomez, Maxim Olshanii, and Anna Minguzzi, Traces of integrability in scattering of one-dimensional dimers on a barrier, New Journal of Physics, 21, 023008 (Feb 2019) , [ arXiv:arXiv:1806.01820 ]
[AGHJOA17] ^ X. M. Aretxabaleta, M. Gonchenko, N. L. Harshman, S. G. Jackson, M. Olshanii, G. E. Astrakharchik, Two-ball billiard predicts digits of the number PI in non-integer numerical bases, [ arXiv:1712.06698 ] (Dec 2017)
[DO17] ^ Sumita Datta and Maxim Olshanii, Numerical Realization of Bethe Rapidities in Cold Quenched Systems by Feynman-Kac Path Integral Method, [ cond-mat/1612.01751v2 (major revision)] (May 2017)
[HODVJZ17] ^ N.L. Harshman, Maxim Olshanii, A.S. Dehkharghani, A.G. Volosniev, Steven Glenn Jackson, N.T. Zinner, Integrable families of hard-core particles with unequal masses in a one-dimensional harmonic trap, Phys. Rev. X, 7, 041001 (Oct 2017) , [ cond-mat/1704.01433]
[PBOC17] ^ S. M. Pittman, M. Beau, M. Olshanii, A. del Campo, Truncated Calogero-Sutherland models, Phys. Rev. B, 95, 205135 (May 2017) , [ cond-mat/1606.00895]
[ODML17] ^ Maxim Olshanii, Vanja Dunjko, Anna Minguzzi, Guillaume Lang, A connection between non-local one-body and local three-body correlations of the Lieb-Liniger model, Phys. Rev. A, 96, 033624 (Sep 2017) , [ cond-mat/1705.02100]
[OSDJ16] ^ Maxim Olshanii, Thibault Scoquart, Vanja Dunjko, Steven Glenn Jackson, Creating Entanglement Using Integrals of Motion, Phys. Rev. A, 97, 013630 (Jan 2018) , [ cond-mat/1610.01060]
[SSJO16] ^ T. Scoquart, J. J. Seaward, S. G. Jackson, M. Olshanii, Exactly solvable quantum few-body systems associated with the symmetries of the three-dimensional and four-dimensional icosahedra, SciPost, 1, 005 (Oct 2016)
[JO15] ^ S. G. Jackson and M. Olshanii, An Exactly Solvable Quantum Four-Body Problem Associated With The Symmetries Of An Octacube, New J. Phys., 17, 105005 (Oct 2015), focus issue on "Strongly Interacting Quantum Gases in One Dimension" commemorating the contributions of Marvin Girardeau (1930-2015) to the field
[HCO15] ^ Zaijong Hwang, Frank Cao, Maxim Olshanii, Traces of Integrability in Relaxation of One-Dimensional Two-Mass Mixtures, J. Stat. Phys., 161, 467 (Oct 2015) , [ arXiv:1412.8403 ]
[DO11] Vanja Dunjko and Maxim Olshanii, A Hermite-Pade perspective on the renormalization group, with an application to the correlation function of Lieb-Liniger gas , [ arXiv:0910.0565 ], J. Phys. A, 44, 055206 (2011)
[GNO04] M.D. Girardeau, Hieu Nguyen, M. Olshani, Effective interactions, Fermi-Bose duality, and ground states of ultracold atomic vapors in tight de Broglie waveguides , Optics Communications, 243, 3 (2004) , special issue on Ultra Cold Atoms and Degenerate Quantum Gases, [ cond-mat/0403721 ]
[GO04] M. D. Girardeau and M. Olshanii, Theory of spinor Fermi and Bose gases in tight atom waveguides , Phys. Rev. A 70, 023608 (2004) , [ cond-mat/0401402 ]
[GO03] M. D. Girardeau and M. Olshanii, Fermi-Bose mapping and N-particle ground state of spin-polarized fermions in tight atom waveguides, [ cond-mat/0309396 ] (2003)
[0D03a] Maxim Olshanii and Vanja Dunjko, Short-Distance Correlation Properties of the Lieb-Liniger System and Momentum Distributions of Trapped One-Dimensional Atomic Gases, Phys. Rev. Lett. 91, 090401 (2003) , [ cond-mat/0210629 ]
[OD03b] Maxim Olshanii and Vanja Dunjko, The short-distance first-order correlation function of the interacting one-dimensional Bose gas , New J. Phys. 5, 98 (2003)
[DLO01] Vanja Dunjko, Vincent Lorent, and Maxim Olshanii, Bosons in cigar-shape traps: Thomas-Fermi regime, Tonks-Girardeau regime, and in between, Phys. Rev. Lett., 86, 5413 (2001) , [ cond-mat/0103085]
see also J. H. Thywissen et al (1999) in the "waveguides" section
[Olsh98] M. Olshanii, Atomic scattering in the presence of an external confinement and a gas of impenetrable bosons, Phys. Rev. Lett. 81, 938 (1998), [ cond-mat/9804130 ]

Integrable PDEs, solitons (both classical and quantum)

[MMYODH19] ^ Oleksandr V. Marchukov, Boris A. Malomed, Vladimir A. Yurovsky, Maxim Olshanii, Vanja Dunjko, Randall G. Hulet, Splitting of nonlinear-Schrodinger breathers by linear and nonlinear localized potentials, Phys. Rev. A, 99.063623 , [ arXiv:1904.10853 ] (Jun 2019)
[NGDPOAM19] ^ Piero Naldesi, Juan Polo Gomez, Vanja Dunjko, Hélène Perrin, Maxim Olshanii, Luigi Amico, Anna Minguzzi, Angular momentum fractionalization: the quantum advantage of entangled bosons, [ arXiv:1901.09398 ] (Jan 2019)
[NGMMOA18] ^ Piero Naldesi, Juan Polo Gomez, Anna Minguzzi, Boris Malomed, Maxim Olshanii, Luigi Amico, Raise and fall of a bright soliton in an optical lattice, Phys. Rev. Lett., 122.053001 , [ arXiv:1804.10133 ] ( Feb 2019)
[DO17] ^ Sumita Datta and Maxim Olshanii, Numerical Realization of Bethe Rapidities in Cold Quenched Systems by Feynman-Kac Path Integral Method, [ cond-mat/1612.01751v2 (major revision)] (May 2017)
[GRDMOD18] ^ Jake Golde, Joanna Ruhl, Sumita Datta, Boris A. Malomed, Maxim Olshanii, Vanja Dunjko, Metastability versus collapse following a quench in attractive Bose-Einstein condensates, Phys. Rev. A, 97.053604 (May 2018) , [ arXiv:1706.07114]
[OCD15] ^ M. Olshanii, S. Choi, V. Dunjko, A. E. Feiguin, H. Perrin, J. Ruhl, D. Aveline, Three-dimensional Gross-Pitaevskii solitary waves in optical lattices: stabilization using the artificial quartic kinetic energy induced by lattice shaking, Phys. Lett. A, 380, 177 (Jan 2016), [ arXiv:1509.02065 ]
[YMHOA17] ^ Vladimir A. Yurovsky, Boris A. Malomed, Randall G. Hulet, Maxim Olshanii, Dissociation of one-dimensional matter-wave breathers due to quantum many-body effects, Phys. Rev. Lett., 119, 220401 (Nov 2017) , [ arXiv:1706.07114]
[DO15] ^ ^ Vanja Dunjko, Maxim Olshanii, Superheated integrability and multisoliton survival through scattering off barriers, [ arXiv:1501.00075 ] (2015)
[KHO15] ^ ^ Andrew Koller, Zaijong Hwang, Maxim Olshanii, Emergence of Reflectionless Scattering from Linearizations of Integrable PDEs around Solitons, [ arXiv:1306.0300 ], J. Phys. A 48, 075203 (2015)
[HOC14] Christopher Herzog, Maxim Olshanii, and Yvan Castin, Une transition liquide-gaz pour des bosons en interaction attractive à une dimension (A liquid-gas transition for bosons with attractive interaction in one dimension), Comptes Rendus Physique 15, 285 (2014) , [ cond-mat/1311.3857]
[KO11] ^ Andrew Koller and Maxim Olshanii, Supersymmetric Quantum Mechanics and Solitons of the sine-Gordon and Nonlinear Schrödinger Equations, [ arXiv:1012.2843 ], Phys. Rev. E 84, 066601 (2011)
[DHC03] Vanja Dunjko, Christopher P. Herzog, Yvan Castin, and Maxim Olshanii, No-soliton--soliton phase transition of 1D Bose gas, [ cond-mat/0306514 ] (2003)

Scale invariance, quantum anomalies, etc

[CDZO15] ^ S. Choi, V. Dunjko, Z.D. Zhang, M. Olshanii, Monopole excitations of a harmonically trapped one-dimensional Bose gas from the ideal gas to the Tonks-Girardeau regime , [ arXiv:1412.6855 ], Phys. Rev. Lett. 89, 063616 (2015)
[ZAA14] ^ Z. D. Zhang, G. E. Astrakharchik, D. C. Aveline, S. Choi, H. Perrin, T. H. Bergeman, and M. Olshanii, Breakdown of scale invariance in the vicinity of the Tonks-Girardeau limit, [ arXiv:1312.7005 ], Phys. Rev. A 89, 063616 (2014)
[MDL13] ^ Karina Merloti, Romain Dubessy, Laurent Longchambon, Maxim Olshanii, and Hélène Perrin, Breakdown of scale invariance in a quasi-two-dimensional Bose gas due to the presence of the third dimension, [ arXiv:1311.1028 ], Phys. Rev. A 88, 061603(R) (2013)
[OPL10] ^ Maxim Olshanii, Hélène Perrin and Vincent Lorent, Example of a Quantum Anomaly in the Physics of Ultracold Gases, [ arXiv:1006.1072 ], Phys. Rev. Lett. 105, 095302 (2010)

Quantum non-equilibrium dynamics, atomtronics

[ZDO15] ^ Zhedong Zhang, Vanja Dunjko, Maxim Olshanii, Atom transistor from the point of view of quantum nonequilibrium dynamics, [ arXiv:1506.02467 ], New J. Phys. 17 125008 (Dec 2015), focus issue on "Atomtronics"
[Ols15] ^ Maxim Olshanii, Geometry of quantum observables and thermodynamics of small systems, [ arXiv:1208.0582 ], Phys. Rev. Lett. 114, 060401 (2015)
[SJD14] ^ Luciano Silvestri, Kurt Jacobs, Vanja Dunjko, and Maxim Olshanii, Typical, finite baths as a means of exact simulation of open quantum systems, Phys. Rev. E 89, 042131 (2014)
[OJRD12] ^ Maxim Olshanii, Kurt Jacobs, Marcos Rigol, Vanja Dunjko, Harry Kennard, and Vladimir A. Yurovsky, An exactly solvable model for the integrability-chaos transition in rough quantum billiards, [ arXiv:1203.1972 ], Nature Communications 3, 641 (2012)
[YuBO11] Vladimir A. Yurovsky, Abraham Ben-Reuven, and Maxim Olshanii, Dynamics of Relaxation and Fluctuations of the Equilibrium State in an Incompletely Chaotic System , J. Phys. Chem. B, 2011, 115, 5340 (2011)
[YuO11] ^ Vladimir Yurovsky and Maxim Olshanii, Memory of the Initial Conditions in an Incompletely Chaotic Quantum System: Universal Predictions with Application to Cold Atoms , arXiv:0911.5587 ], Phys. Rev. Lett. 106, 025303 (2011)
[YuO10] Vladimir Yurovsky and Maxim Olshanii, Restricted thermalization for two interacting atoms in a multimode harmonic waveguide , [ arXiv:1001.0225 ], Phys. Rev. A 81, 043641 (2010)
[SAYuO10] ^ Cavan Stone, Yassine Ait El Aoud, Vladimir A Yurovsky, and Maxim Olshanii, Two simple systems with cold atoms: quantum chaos tests and non-equilibrium dynamics , [ arXiv:1005.5463 ], New J. Phys. 12 (2010) 055022 (2010)
[CMDO09] Amy C. Cassidy, Douglas Mason, Vanja Dunjko, and Maxim Olshanii, Threshold for Chaos and Thermalization in the One-Dimensional Mean-Field Bose-Hubbard Model , [ arXiv:0805.3388 ], Phys. Rev. Lett. 102, 025302 (2009)
[RDO08] ^ Marcos Rigol, Vanja Dunjko, and Maxim Olshani, Thermalization and its mechanism for generic isolated quantum systems , [ arXiv:0708.1324 ], Nature, 452, 854 (2008)
[RDYuO07] ^ Marcos Rigol, Vanja Dunjko, Vladimir Yurovsky, Maxim Olshani, Relaxation in a completely integrable many-body quantum system: an ab initio study of the dynamics of the highly excited states of lattice hard-core bosons , [ cond-mat/0604476 ], Phys. Rev. Lett. 98, 050405 (2007) See also supplementary animations.
[RMO06] Marcos Rigol, Alejandro Muramatsu, and Maxim Olshanii, Hard-core bosons on optical superlattices: Dynamics and relaxation in the superfluid and insulating regimes , [ cond-mat/0604476 ], Phys. Rev. A 74, 053616 (2006).
[YuBO06] V. A. Yurovsky, A. Ben-Reuven, M. Olshanii, One-dimensional Bose chemistry: effects of non-integrability, Phys. Rev. Lett. 96, 163201 (2006) , [ physics/0512033

Microfabricated atom waveguides: design, loading and interferometry

[OD05] Maxim Olshanii and Vanja Dunjko, Interferometry in dense nonlinear media and interaction-induced loss of contrast in microfabricated atom interferometers, [ cond-mat/0505358 ] (2005)
[CKO03] Y. Colombe, D. Kadio, Maxim Olshanii, B. Mercier, H. Perrin, and V. Lorent, Schemes for Loading a Bose-Einstein Condensate into a Two-Dimensional Dipole Trap, J. Opt. B: Quantum Semiclass. Opt. 5, S155 (2003)
[OW02] Maxim Olshanii and David Weiss, Producing Bose condensates using optical lattices, Phys. Rev. Lett 89, 090404 (2002), [ cond-mat/0205243 ]
[BSO00] A. H. Barnett, S. P. Smith, M. Olshanii, K. S. Johnson, A. W. Adams, and M. Prentiss, Substrate-based atom waveguide using guided two-color evanescent light fields, Phys. Rev. A 61, 023608 (2000), [ physics/9907014]
[TOZ99] J. H. Thywissen, M. Olshanii, G. Zabow, M. Drndic, K. S. Johnson, R. M. Westervelt, and M. Prentiss, Microfabricated Magnetic Waveguides for Neutral Atoms, Eur. Phys. J. D 7, 361 (1999) (spec. issue on "Laser Cooling and Trapping")
[Olsh98] M. A. Olshanii, Far-off-Resonant ac-Stark potential for Alkali Optical Traps, local preprint, Harvard (1998)
[Olsh97] M. A. Olshanii, Variational Approach to the Problem of Coupled Electromagnetic Wave-Guides, local preprint, Harvard (1997)
[OJP96] M. Olshanii, J. Vanicek, and M. Prentiss, Atomic Beam-Splitter Based on Multiple Adiabatic Passage in the Optical Interference Pattern, Quantum and Semiclassical Optics 8, 655 (1996), (spec. issue on "Atom Optics")
[Olsh94] M. Ol'shanii, Berry-Phase-Induced Achromatic Phase Plate for the Atomic Interferometry, Physics Letters A 186, 369 (1994)
[OOL93] M. A. Ol'Shanii, Yu. B. Ovchinnikov, and V. S. Letokhov, Laser Guiding of Atoms in a Hollow Optical Fiber, Optics Communications 98, 77 (1993)

Quantum state engineering

[ODH00] M. Olshanii, N. Dekker, C. Herzog, and M. Prentiss, de-Broglie Wave Front Engineering, Phys. Rev. A , 62, 033612 (2000) , [ quant-ph/9811021 ]

Collisions in low-dimensional atom waveguides

[OWR16] M. Olshanii, W. Xu, M. Rigol, Multiband Effects and the Bose-Hubbard Model in One-Dimensional Lattices, Phys. Rev. A 94, 031601(R) (Sep 2016) , [ arXiv:1604.00410 ]
[PO07] Ludovic Pricoupenko and Maxim Olshanii, Three body losses in two-dimensional Bose gases with negative scattering length, J. Phys. B 40, 2065 (2007) , [ cond-mat/0205210 ]
[MBO04] M. G. Moore, T. Bergeman, and M. Olshanii, Scattering in tight atom waveguides, lecture course, Les Houches School on Quantum Gases in Low Dimensions (2003), J. Phys. IV France 116, 69 (2004) , [ cond-mat/0402149 ]
[BMO03] T. Bergeman, M. G. Moore, and M. Olshanii, Atom-Atom Scattering in the Presence of a Cylindrical Harmonic Potential: Numerical Results and an Extended Analytic Theory, Phys. Rev. Lett. 91, 163201 (2003) , [ cond-mat/0210556 ]
see also M. Olshanii's PRL of (1998) in the "1D" section

Atom laser

[OCD95] M. Olshanii, Y. Castin and J. Dalibard, A Model for an Atom Laser, Procc. of the 12th Conference on Laser Spectroscopy, edited by M. Inguscio, M. Allegrini, and A. Lasso, (World Scientific, 1995)
[OCD96] M. Olshanii, Y. Castin and J. Dalibard, Almost Bose-Einstein Phase Transition in VSCPT cooling, Procc. of International School of Physics "Enrico Fermi", CXXXI course, Coherent and Collective Interactions of Particles and Radiation Beams, edited by A. Aspect, W. Barletta, and R. Bonifacio (IOS Press, Amsterdam, 1996)

Bose condensation

[OP02] Maxim Olshanii and Ludovic Pricoupenko, Rigorous approach to the problem of ultraviolet divergencies in dilute Bose gases, Phys. Rev. Lett. 88, 010402 (2002) [ cond-mat/0101275 ]
see also Maxim Olshanii and David Weiss's PRL of (2002) in the "waveguides" section
[WOH01] Stefan Wessel, Maxim Olshanii, and Stephan Haas, Field-Induced Magnetic Order in Quantum Spin Liquids, Phys. Rev. Lett 87, 206407 (2001) [ cond-mat/0105464 ]
[SO00] P. Storey and M. Olshanii, A Closed Class of Hydrodynamical Solutions for the Collective Excitations of a Bose-Einstein Condensate, Phys. Rev. A, 62, 033604 (2000) , [ cond-mat/9903211 ]
[ON98] M. Olshanii and M. Naraschewski, Berry's Phase Induced Bose-Einstein condensation into a Vortex State, [ cond-mat/9811314 ]
[Olsh98] M. Olshanii, Finite-Temperature Collective Excitation of a Bose-Einstein Condensate, [ cond-mat/9807412 ]
[HO97] C. Herzog and M. Olshanii, Trapped Bose gas: The canonical versus grand canonical statistics, Phys. Rev. A 55, 3254 (1997)
[ atom-ph/9609002]

Dark states: configurations

[KCO99] S. Kulin, Y. Castin, M. Ol'shanii, E. Peik, B. Saubaméa, M. Leduc and C. Cohen-Tannoudji, Exotic Quantum Dark States, Eur. Phys. J. D 7, 279 (1999) (spec. issue on "Laser Cooling and Trapping")
[Olsh94] M. Ol'shanyi, Velocity Selective Coherent Population Trapping Induced by Dynamic Stark-Shift, Optics and Spectroscopy 76 174 (1994)
[TTYuO92] A. V. Taichenachev, A. M. Tumaikin, V. I. Yudin, and M. A. Ol'shanyi Nonuniform Stationary Coherent States (the CPT-effect) for the J=3/2 -> J=1/2 and J=2 -> J=1 transitions in the Resonant Interaction with the Nonuniformly Polarized Field, Sov. Phys. JETP, 74, 952 (1992)
[OM92] M. A. Ol'shanii and V. G. Minogin, Three-Dimensional Velocity-Selective Coherent Population Trapping of (3+3)-level Atom, Optics Communications, 89, 393 (1992)
[OM91] M. A. Ol'shanii and V. G. Minogin, Three-Dimensional Velocity-Selective Coherent Population Trapping of (3+1)-level Atoms, Quantum Optics, 3, 317 (1991)
[Olsh91] M. A. Ol'shanii, Stark-Shift Induced Velocity-Selective Coherent Population Trapping, Journal of Physics B, 24, L583 (1991)
[OM91] M. Olshanii and V. G. Minogin, Three-Dimensional Velocity-Selective Coherent Atomic Population Trapping in Resonant Light Field, International Workshop on Light Induced Kinetic Effects on Atoms, Ions and Molecules, edited by L.Moi, S.Gozzini, C.Gabanini, E.Arimondo, F. Strumia (ETS Editprice Pisa, 1991)

Dark states: cooling dynamics & experiments

[HLO00] J. Hack, L. Liu, M. Olshanii, and H. Metcalf, Velocity Selective Coherent Population Trapping of Two-Level Atoms, Phys. Rev. A, 62, 013405 (2000)
see also "Exotic Quantum Dark States" (1999) in the "DS configurations" section
[OR97] M. Olshanii and R. Dum, Dark-State Cooling in the Presence of Gravity: Gravitational Limit of Laser Cooling, Phys. Rev. A 55, 1217 (1997)
[RO95] R. Dum and M. Olshanii, Gauge Structures in Atom-Laser Interaction: Bloch Oscillations in a Dark Lattice, Phys. Rev. Lett. 76, 1788 (1995)
[WEO94] M. Weidemuller, T. Esslinger, M. Olshanii, A. Hemmerich, and T. Hansch, A Novel Scheme for Efficient Cooling Below the Photon Recoil Limit, Europhys. Lett. 27, 109 (1994)
[OML92] M. Olshanii, V. G. Minogin, and V. S. Letokhov, Role of Interaction Time in Light Pressure Force on Atoms, Nonlinear Optics B 3, 283 (1992)
[TTYuO92] A. V. Taichenachev, A. M. Tumaikin, V. I. Yudin, and M. A. Ol'shanii Localization and Superdeep Cooling of Atoms due to the Coherent Population Trapping in the Inhomogeneously Polarized Field, Laser Physics, 2, 32 (1992)
[TTOYu91] A. V. Taichenachev, A. M. Tumaikin, M. A. Ol'shanyl, and V. I. Yudin, Localization of Atoms in the Nonuniformly Polarized Resonant Field as the result of a Coherent Trapping of Population, JETP Lett, 53, 351 (1991)
[MORYa90] V. G. Minogin, M. A. Olshanyi, Yu. V. Rozdestvensky, and N. N. Yakobson, Laser Cooling of Atoms Below the Single-Photon Classical Limit, Opt. Specrosc. (USSR), 68, 29 (1990)
[MOSh89] V. G. Minogin, M. A. Olshany, and S. V. Shul'ga, Laser Cooling Below One-Photon Classical Limit, JOSA B 6, 2108 (1989) (spec. issue on "Atom Cooling and Trapping")