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Ultracold Alkali Metal Atoms and Dimers: A Quantum Paradise Paul S. Julienne Atomic Physics Division, NIST Joint Quantum Institute, NIST/U. Md 62 nd International.

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Presentation on theme: "Ultracold Alkali Metal Atoms and Dimers: A Quantum Paradise Paul S. Julienne Atomic Physics Division, NIST Joint Quantum Institute, NIST/U. Md 62 nd International."— Presentation transcript:

1 Ultracold Alkali Metal Atoms and Dimers: A Quantum Paradise Paul S. Julienne Atomic Physics Division, NIST Joint Quantum Institute, NIST/U. Md 62 nd International Symposium on Molecular Spectroscopy, Columbus, OH, June 22, 2007 Thanks to Eite Tiesinga (NIST), Svetlana Kotochigova (Temple/NIST) Bo Gao (U. Toledo), Thorsten Köhler (Oxford) Roman Ciurylo (Torun), Pascal Naidon (NIST) M. Kitagawa, K. Enomoto, K. Kasa, Y. Takahashi (Kyoto University) Looking for good students/postdocs Joint Quantum Institute, NIST/University of Maryland http://www.jqi.umd.edu/ http://physics.nist.gov/

2 Cold alkali atoms and molecules Widely used in forefront experiments Ultra-cold Bose or Fermi gases Optical lattices and reduced dimensional structures Precision measurements Multidisciplinary studies and applications Complex calculations required coupled channels methods ab initio structure and properties But remain amenable to simple models based on long range potentials Control interaction properties by static or dynamic electromagnetic fields s-wave scattering length (a quantum phase shift)

3 1 pK 1 nK 1  K 1 mK 1 K 1000 K 10 6 K 10 9 K Surface of sun Room temperature Outer space (3K) Laser cooled atoms Bose-Einstein condensates Interior of sun Atomic clock atoms Fermionic quantum gases Cold He Molecules Buffer gas cooling Decelerated beams Photoassociated atoms Feshbach molecules Molecular BEC 1 neV

4 Grou From Wolfgang Ketterle Group, MIT 23 Na BEC BEC of molecules of paired 6 Li Superfluid pairing of 6 Li atoms

5 An Optical Lattice Laser 1 Laser 2 2 atoms in a cell Typical well depth, 100 kHz /2

6 from H. T. C. Stoof, in News and Views, Nature 415, 25 (2002) Put a BEC in a Lattice 40 K 87 Rb 87 Rb 2 Quantum phase transition from a superfluid to a Mott insulator in a gas of ultracold atoms Greiner, Mandel, Esslinger, Haensch, and Bloch Nature 415, 39, (2002)

7 A+B AB Long range 1/R n “simple” analytic long-range theory Asymptotic Properties of separated species “simple” Measured Ab initio 10 -7 eV (1 mK) Chemistry 1 - 10 eV Semi-empirical Ab initio “Complex” Ground state And Collision complex Optical transfer

8 “Size” of -C 6 /R 6 van der Waals potential V(R) See Jones, Lett, Tiesinga, Julienne, Rev. Mod. Phys. 78, 483 (2006)

9 Adapted from Gao, Phys. Rev. A 62, 050702 (2000); Figure from E. Tiesinga Bound states from van der Waals theory

10 Noninteracting atoms Interacting atoms See Jones, Lett, Tiesinga, Julienne, Rev. Mod. Phys. 78, 483 (2006)

11 6 Li a+b mixture

12 6 Li 2 M=0 s-wave Methodology: Coupled channels methods with full Hamiltonian Simplified models based on long-range properties

13

14 Data: M. Bartenstein, et al., Phys. Rev. Lett. 94, 103201 (2005) ab ac Chin and Julienne, PRA 71, 012713 (2005)

15 From M. Bartenstein, et al., Phys. Rev. Lett. 94, 103201 (2005) 1  g + scattering length: 45.167(8) a 0 3  u + scattering length: -2140(18) a 0 ab resonance: 834.1(1.5) Gauss ac resonance: 690.4(5) Gauss

16 6 Li a+b Scattering Length vs. B Model from Bartenstein et al., PRL 94, 103201 (2005) 543 G 834 G

17 Closed channel dominated Open channel dominated Julienne and Gao, Atomic Physics 20, AIP, (2006) and physics/0609013 sin 2  (E,B)

18 Leo, Williams, Julienne, Phys. Rev. Lett. 85, 2721 (2000) Vuletic, Kerman, Chin, Chu, Phys. Rev. Lett. 85, 2717 (2000)) Cesium threshold resonance spectroscopy 5 mK trap Tune magnetic field Measure collision rates Fit theoretical model parameters * * * * * A( 1  g + ) = +280(10) a 0 A( 3  u + ) = +2400(100) a 0 C 6 = 6890(35) a.u.

19 6 Li ab M=0 133 Cs aa M=+6 87 Rb aa M=+2 23 Na aa M=+2

20

21 From M. Kitagawa, K. Enomoto, K. Kasa, Y. Takahashi (Kyoto University)

22 All-optical Yb trap Few  K 2-color photoassociation

23 12 PA lines among 6 different isotopes

24 C 6 + N C8C8 Model: LJ 6-12 + C 8 van der Waals 1 potential + reduced mass C 6 =1932(15) au C 8 =1.9(5)x10 5 au N=72 bound states in 174 Yb 2

25 Last bound state energies versus mass Solid: J=0 Dashed: J=2 fit

26 Scattering lengths for Yb ground state model (in a 0 units) 168 170 171 172 173 174 176 168 252(6) 117(1) 89(1) 65(1) 39(1) 2(2) -360(30) 170 117 64(1) 37(1) -2(2) -81(4) -520(50) 209(4) 171 89 37 -3(2) -84(5) -580(60) 430(20) 142(2) 172 65 -2 -84 -600(60) 420(20) 201(3) 106(1) 173 39 -81 -580 420 199(3) 139(2) 80(1) 174 2 -520 430 201 139 105(1) 55(1) 176 -360 209 142 106 80 55 -24(2)

27 Variation of scattering length with mass Enomoto et al., PRL, 98, 203201(2007)

28 Gribakin and Flambaum Phys. Rev. A 48, 546 (1993) Number of bound states in V(R) =

29 Pure van der Waals theory (Gribakin-Flambaum and B. Gao)

30 Species Spin % Abundance 84 Sr 0 0.6 86 Sr 0 9.9 87 Sr 9/2 7.0 88 Sr 0 82.6 130 Ba 0 0.1 132 Ba 0 0.1 134 Ba 0 2.4 135 Ba 3/2 6.6 136 Ba 0 7.9 137 Ba 3/2 11.2 138 Ba 0 71.7 Species Spin % Abundance 106 Cd 0 1.3 108 Cd 0 0.9 110 Cd 0 12.5 111 Cd 1/2 12.8 112 Cd 0 24.1 113 Cd 1/2 12.2 114 Cd 0 28.7 116 Cd 0 7.5 196 Hg 0 0.2 198 Hg 0 10.0 199 Hg 1/2 16.9 200 Hg 0 23.1 201 Hg 3/2 13.2 202 Hg 0 29.9 204 Hg 0 6.9

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