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Fermions at unitarity as a nonrelativistic CFT. Yusuke Nishida (INT, Univ. of Washington) in collaboration with D. T. Son (INT) Ref: Phys. Rev. D 76, 086004 (2007) [arXiv:0708.4056] 22 January, 2008 @ UW particle theory group. Contents of this talk Fermions at infinite scattering length
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Fermions at unitarityas a nonrelativistic CFT Yusuke Nishida (INT, Univ. of Washington) in collaboration with D. T. Son (INT) Ref: Phys. Rev. D 76, 086004 (2007) [arXiv:0708.4056] 22 January, 2008 @ UW particle theory group
Contents of this talk • Fermions at infinite scattering length • scale free system realized using cold atoms • Operator-State correspondence • scaling dimensions in NR-CFT energy eigenvalues in a harmonic potential • Results using e(=d-2,4-d) expansions • scaling dimensions near d=2 and d=4 • extrapolations to d=3 • Summary and outlook
Fermions at infinite scattering length Introduction
Symmetry of nonrelativistic systems • Nonrelativistic systems are invariant under • Translations in time (1) and space (3) • Rotations (3) • Galilean transformations (3) • Two additional symmetries under • Scale transformation (dilatation) : • Conformal transformation : If the interaction is scale free Not only theoretically interesting Experimental realization of scale free system !
Feshbach resonance C.A.Regal and D.S.Jin, Phys.Rev.Lett. 90 (2003) add a V0(a) r0 Cold atom experiments high designability and tunability Attraction is arbitrarily tunable by magnetic field scattering length : a (rBohr) zero binding energy a>0 bound molecules = unitarity limit |a| a<0 No bound state add=0.6a >0 40K B (Gauss)
Scale invariant systems a= • Fermions at unitarity • Strong coupling limit : |a| • Cold atoms @ Feshbach resonance • 0r0 << lde Broglie << |a| • Scale invariant Nonrelativistic CFT l • Fermions with two- and three-body resonances • Y.N., D.T. Son, and S. Tan, arXiv:0711.1562 • Particles obeying fractional statistics in d=2 (anyons) • R. Jackiw and S.Y. Pi, Phys. Rev. D42, 3500 (1990) • Resonantly interacting anyons Y.N., arXiv:0708.4056 External potential breaks scale invariance Isotropic harmonic potential NR-CFT in free space
Measurement of 2 fermion energy T. Stöferle et al., Phys.Rev.Lett. 96 (2006) • |a| Energy in a harmonic potential • Schrödinger eq. • CFT calculation
NR-CFT and operator-statecorrespondence Part I Scaling dimension of operator in NR-CFT Energy eigenvalue in a harmonic potential
Nonrelativistic CFT C.R.Hagen, Phys.Rev.D (’72) U.Niederer, Helv.Phys.Acta.(’72) • Two additional symmetries under • scale transformation (dilatation) : • conformal transformation : Corresponding generators in quantum field theory D, C, and Hamiltonian form a closed algebra : SO(2,1) Continuity eq. If the interaction is scale invariant !
Commutator [D, H] • E.g. Hamiltonian with two-body potential V(r) Generator of dilatation : scale invariance
Primary operator Local operator has • scaling dimension • particle number Primary operator E.g., primary operator : nonprimary operator :
Proof of correspondence Hamiltonian with a harmonic potential is Construct a state using a primary operator : is an eigenstate of particles in a harmonic potential with the energy eigenvalue !!!
Trivial examples of • Noninteracting particles in d dimensions operator state N=1 : Lowest operator . . . 2nd lowest operator N=3 : Interacting case corrections byanomalous dimensions!
Ladders of eigenstates . . . . . . . . . • Raising and lowering operators F.Werner and Y.Castin, Phys.Rev.A 74 (2006) E . . . breathing modes Each state created by the primary operator has a semi-infinite ladder with energy spacing Cf. Equivalent result derived from Schrödinger equation S. Tan, arXiv:cond-mat/0412764
Operator-state correspondence Energy eigenvalues of N-particle state in a harmonic potential Scaling dimensions of N-body composite operator in NR-CFT Computable using diagrammatic techniques ! • Particles interacting via a 1/r2 potential • Fermions with two- and three-body resonances • Anyons / resonantly interacting anyons • expansions by statistics parameter near boson/fermion limits • Spin-1/2 fermions at infinite scattering length e (=d-2, 4-d) expansions near d=2 or d=4
e expansion for fermions at unitarity Part II • Field theories for fermions at unitarity • perturbative near d=2 or d=4 • Scaling dimensions of operators • up to 6 fermions • expansions over e=d-2 or 4-d • Extrapolations to d=3
Specialty of d=4 and 2 Z.Nussinov and S.Nussinov, cond-mat/0410597 2-body wave function Normalization at unitarity a diverges at r→0 for d4 Pair wave function is concentrated at its origin Fermions at unitarity in d4 form free bosons At d2, any attractive potential leads to bound states Zero binding energy “a” corresponds to zero interaction Fermions at unitarity in d2 becomes free fermions How to organize systematic expansions near d=2 or d=4 ?
Field theories at unitarity 1 • Field theory becoming perturbative near d=2 Renormalization of g RG equation : Fixed point : The theory at fixed point is NR-CFT for fermions at unitarity Near d=2, weakly-interacting fermions perturbative expansion in terms of e=d-2 Y.N. and D.T.Son, PRL(’06) & PRA(’07); P.Nikolić and S.Sachdev, PRA(’07)
Field theories at unitarity 2 p p • Field theory becoming perturbative near d=4 WF renormalization of RG equation : Fixed point : The theory at fixed point is NR-CFT for fermions at unitarity Near d=4, weakly-interacting fermions and bosons perturbative expansion in terms of e=4-d Y.N. and D.T.Son, PRL(’06) & PRA(’07); P.Nikolić and S.Sachdev, PRA(’07)
Scaling dimensionsnear d=2 and d=4 g g Strong coupling d=2 d=3 d=4 Cf. Applications to thermodynamics of fermions at unitarity Y.N. and D.T.Son, PRL 97 (’06) & PRA 75 (’07); Y.N., PRA 75 (’07)
2-fermion operators p p • Anomalous dimension near d=2 • Anomalous dimension near d=4 Ground state energy of N=2 is exactly in any 2d4
3-fermion operators near d=2 • Lowest operator has L=1 ground state O(e) O(e) N=3 L=1 N=3 L=0 • Lowest operator with L=0 1st excited state
3-fermion operators near d=4 • Lowest operator has L=0 ground state O(e) O(e) N=3 L=0 N=3 L=1 • Lowest operator with L=1 1st excited state
Operators and dimensions • NLO results of e=d-2 and e=4-d expansions e.g. N=5
Operators and dimensions • NLO results of e=d-2 and e=4-d expansions O(e) O(e2) O(e)
Comparison to results in d=3 • Naïve extrapolations of NLO results to d=3 *) S. Tan, cond-mat/0412764 †) D. Blume et al., arXiv:0708.2734 Extrapolated results are reasonably close to values in d=3 But not for N=4,6 from d=4 due to huge NLO corrections
3 fermion energy in d dimensions 2d 4d 4d 2d Fit two expansions using Padé approx. Interpolations to d=3 span in a small interval very close to the exact values !
Exact 3 fermion energy Padé fits have behaviors consistent withexact 3 fermion energy in d dimension Exact is computed from = +
Energy level crossing Level crossing between L=0 and L=1 states at d=3.3277 Ground state at d=3 has L=1 Excited state Ground state
Summary • Operator-state correspondence in nonrelativistic CFT Energy eigenvalues of N-particle state in a harmonic potential Scaling dimensions of N-body composite operator in NR-CFT Exact relation for any nonrelativistic systems if the interaction is scale invariant and the potential is harmonic and isotropic • e(=d-2,4-d) expansions near d=2 or d=4 • for spin-1/2 fermions at infinite scattering length • Statistics parameter expansions for anyons
Summary and outlook 2 e (=d-2, 4-d) expansions for fermions at unitarity • Clear picture near d=2 (weakly-interacting fermions) • and d=4 (weakly-interacting bosons & fermions) • Exact results for N=2,3 fermions in any dimensions d • Padé fits of NLO expansions agree well with exact values • Underestimate values in d=3 as N is increased How to improve e expanions? Accurate predictions in 3d • Calculations of NN…LO corrections • Are expansions convergent ? (Yes, when N=3 !) • What is the best function to fit two expansions ? • Exact result for N=4 fermions
5 fermion energy in d dimensions 2d 2d 4d 4d • Level crossing between L=0 and L=1 states at d>3 • Padé interpolations to d=3 span in a small interval but underestimate numerical values at d=3
4 fermion and 6 fermion energy 2d 2d 4d 4d • Ground state has L=0 both near d=2 and d=4 • Padé interpolations to d=3 [4/0], [0/4] Padé are off from others due to huge 4d NLO
Anyon spectrum to NLO • Ground state energy of N anyons in a harmonic potential • Perturbative expansion in terms of statistics parameter a • a0 : boson limit a1 : fermion limit Coincidewith resultsby Rayleigh-Schrödingerperturbation New analyticresultsconsistentwithnumericalresults Cf. anyon field interacts via Chern-Simons gauge field
Anyon spectrum to NLO 4 anyon spectrum M. Sporre et al., Phys.Rev.B (1992) • Ground state energy of N anyons in a harmonic potential • Perturbative expansion in terms of statistics parameter a • a0 : boson limit a1 : fermion limit Coincidewith resultsby Rayleigh-Schrödingerperturbation New analyticresultsconsistentwithnumericalresults Cf. anyon field interacts via Chern-Simons gauge field