What are we going to talk about: BEC and Nonlinear Atom Optics

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What are we going to talk about: BEC and Nonlinear Atom Optics Nobel Prize Winners E. A. Cornell 1961JILA and NIST Boulder, Co, USA W. Ketterle C. E. Wieman 19571951MIT, JILA and UC, Cambridge.M Boulder, Co, a USA USA Plan 1. Facts about BEC. Atom cooling 3. Atom trapping 4. Condensates and diagnostics 5. Coherence and excitations 6. Nonlinear Atom Optics 7. Lattices 8. Feshbach Resonance 9. Solitons and Vorteces 10. Spinor condensates 11. Tons more Uniwersytet Warszawski Wydział Fizyki 1

Some history 195 Theory of condensation 1938 Superfluid helium discovery 1941 Landau theory 1980 Cooling breaking mk limit 1995 BEC in neutral gas observed Uniwersytet Warszawski Wydział Fizyki Some characteristics Statistics Critical temperature de Broglie a wavelength N i = exp π h kt c = m 1 [( ε µ ) / kt] 1 i ρ.61 /3 h λ ( T) = = (h / 3mkT) p

Lost identity BEC methastable state 3

Cooling of Neutral Atoms 1. Doppler cooling. Sisyphus cooling 3. Whatever else cooling 3. Evaporative cooling!!!! Doppler cooling e g 4

Sisyphus cooling 5

Evaporative cooling Evaporative colling Optical Scalpel 6

Magneto-optical optical trap T.O.P 7

Condenssate at last JILA,COLORADO 95 8

Free expansion (W.Ketterle) Interference (W.Keterle, Science 1997) 9

Excitations (C.E. Wieman, E.A. Cornell 96) Galery 10

11 Condensate Splitting Condensate Splitting (W.D. Philips, 1999) (W.D. Philips, 1999) A A i y A i x A i t A i z A NL yy xx γ γ γ β + + + = Puls propagation Puls propagation ψ ψ ψ ψ ψ ψ ψ 0 ),, ( ) ( h h U i z y x V z y x m i t + + + + = BEC evolution BEC evolution Uniwersytet Warszawski Wydział Fizyki Nonlinear Optics versus BEC Nonlinear Optics versus BEC

Four Wave Mixing (W.D. Phillips, Nature, 1999) Atomic Amplifier 1

Amplifier Ketterle (Nature, 1999) Supperradiant Rayleigh scattering (W. Ketterle, Science 1999) 13

Connections to other fields Superfluid 4 He, rotating bucket: Ω Dilute gas BEC Type-II superconductors Bell Labs Quantum Hall Systems E. J. Yarmchuk, M. J. V. Gordon, R. E. Packard Phys. Rev. Lett. 43, 14 (1979) JILA MIT ENS Oxford Votex (W. Ketterle, Science 001) 14

How to observe vortex J. Dalibard, 001 Solitons (Phillips, Science 1999) 15

16

Bose Nova (E.A. Cornell, C.E. Wieman, Nature 001) Sympathetic cooling (E.A. Cornell, C.E. Wieman 1997) 17

Eric Cornell Eric Cornell received the 001 Nobel Prize in Physics for his currently a JILA Fellow, a staff member at NIST (Boulder), and Adjoint Professor in the Physics Department at the University of Colorado at Boulder Cornell was co-leader of the research team that was the first to observe a Bosse- Einstein condensate of magnetically trapped atoms in June, 1995. This team has, since then, significantly contributed to the understanding of the geometric, thermodynamic, and mechanical properties of cold-atom Bose-Einstein condensates. Cornell recived his BS degree from Stanford University and, in 1990, his Ph.D from MIT Past awards include the Stratton Award (1995), the Carl Zeiss Award (1996), the Fritz London Prize(1996), the LI Rabi Prize (1997), and the King Faisal International Prize (1997) 18

Wolfgang Ketterle Wolfgang Ketterle received the 001 Nobel Prize for Physics for his contributions to the understanding of Bose-Einstein condensates. Since 1995, Ketterle and his group have developed novel techniques for probing condensates such as non-destructive imaging and optical trapping; have pioneered methods for better condensate confinement; and have studied important BEC topics such as condensate formation and manipulation. Ketterle received his diploma thesis from the Technical Univ. of Munich in 198, working on theoretical solid-state physics. Under the direction of Professor Herbert Walther at the University of Munich, he received his PhD in 1986, studying experimental molecular spectroscopy. His postdoctoral work included laser spectroscopy of molecules at the Max-Planck Institute for Quantum Optics in and Combustion diagnostics in Geidelberg. In 1990, he joined Professor David Pritchard's group in RLE as a postdoctoral associate. Ketterle was appointed to the MIT faculty in the Department of Physics as an assistant professor in 1993, and his promotion to full professor was recently announced. Carl Wieman Carl Wieman received the 001 Nobel Prize in Physics for his work on cold-atom Bose-Einstein condensation. Wieman is currently Professor of Physics at the University of Colorado aswell as a JILA Fellow. Wieman's research has involved the use of lasers and atoms to explore fundamental problems in physics. His group has carried out a variety of precise laserspectroscopy measurements including the most accurate measurements of parity nonconservation in atoms. He also has investigate the physics of ultracold atoms. In collaboration with Eric Cornell, Wieman developed the cooling techniques that allowed them to create the first Bose-Einstein condensate in an atomic vapor. Much of Wieman's recent research has involved the study of condensate properties and improved ways to create and study condensates. He also continues to investigate novel techniques for improved optical trapping and cooling of atoms. 19

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