Numerical Studies of Universality in Few-Boson Systems Javier von Stecher Department of Physics and JILA University of Colorado Probable configurations.

Slides:

Advertisements

Similar presentations

APRIL 2010 AARHUS UNIVERSITY Simulation of probed quantum many body systems.

Advertisements

Wave function approaches to non-adiabatic systems

The University of Tokyo

5/20/2015v. Kolck, Halo EFT1 Background by S. Hossenfelder Halo Effective Field Theory U. van Kolck University of Arizona Supported in part by US DOE.

The Efimov Effect in Ultracold Gases Weakly Bounds Systems in Atomic and Nuclear Physics March , 2010 Institut für Experimentalphysik, Universität.

Chaos and interactions in nano-size metallic grains: the competition between superconductivity and ferromagnetism Yoram Alhassid (Yale) Introduction Universal.

Competing instabilities in ultracold Fermi gases $$ NSF, AFOSR MURI, DARPA ARO Harvard-MIT David Pekker (Harvard) Mehrtash Babadi (Harvard) Lode Pollet.

Lattice regularized diffusion Monte Carlo

Observation of universality in 7 Li three-body recombination across a Feshbach resonance Lev Khaykovich Physics Department, Bar Ilan University,

Semi-Classical Methods and N-Body Recombination Seth Rittenhouse ITAMP, Harvard-Smithsonian Center for Astrophysics, Cambridge, MA Efimov States.

Universality in ultra-cold fermionic atom gases. with S. Diehl, H.Gies, J.Pawlowski S. Diehl, H.Gies, J.Pawlowski.

Strongly Interacting Atoms in Optical Lattices Javier von Stecher JILA and Department of Physics, University of Colorado Support INT 2011 “Fermions from.

What can we learn about quantum gases from 2- and 3-atom problems? Fei Zhou University of British Columbia, Vancouver at Institute for Nuclear Theory,

Stability of a Fermi Gas with Three Spin States The Pennsylvania State University Ken O’Hara Jason Williams Eric Hazlett Ronald Stites Yi Zhang John Huckans.

ULTRACOLD COLLISIONS IN THE PRESENCE OF TRAPPING POTENTIALS ZBIGNIEW IDZIASZEK Institute for Quantum Information, University of Ulm, 18 February 2008 Institute.

Monte Carlo Simulation of Interacting Electron Models by a New Determinant Approach Mucheng Zhang (Under the direction of Robert W. Robinson and Heinz-Bernd.

System and definitions In harmonic trap (ideal): er.

ATOM-ION COLLISIONS ZBIGNIEW IDZIASZEK Institute for Quantum Information, University of Ulm, 20 February 2008 Institute for Theoretical Physics, University.

VARIATIONAL APPROACH FOR THE TWO-DIMENSIONAL TRAPPED BOSE GAS L. Pricoupenko Trento, June 2003 LABORATOIRE DE PHYSIQUE THEORIQUE DES LIQUIDES Université.

INTRODUCTION TO PHYSICS OF ULTRACOLD COLLISIONS ZBIGNIEW IDZIASZEK Institute for Quantum Information, University of Ulm, 14 February 2008 Institute for.

Three-body recombination at vanishing scattering lengths in ultracold atoms Lev Khaykovich Physics Department, Bar-Ilan University, Ramat Gan, Israel.

Experimental study of universal few-body physics with ultracold atoms Lev Khaykovich Physics Department, Bar-Ilan University, Ramat Gan, Israel Laboratoire.

Observation of an Efimov spectrum in an atomic system Matteo Zaccanti LENS, University of Florence.

Quantum Monte Carlo Simulations of Mixed 3 He/ 4 He Clusters Dario Bressanini Universita’ degli.

XII Nuclear Physics Workshop Maria and Pierre Curie: Nuclear Structure Physics and Low-Energy Reactions, Sept , Kazimierz Dolny, Poland Self-Consistent.

Efimov Physics in a Many-Body Background

Few-body physics with ultracold fermions Selim Jochim Physikalisches Institut Universität Heidelberg.

Quantum Monte Carlo methods applied to ultracold gases Stefano Giorgini Istituto Nazionale per la Fisica della Materia Research and Development Center.

Stochastic methods beyond the independent particle picture Denis Lacroix IPN-Orsay Collaboration: S. Ayik, D. Gambacurta, B. Yilmaz, K. Washiyama, G. Scamps.

E. Kuhnle, P. Dyke, M. Mark, Chris Vale S. Hoinka, Chris Vale, P. Hannaford Swinburne University of Technology, Melbourne, Australia P. Drummond, H. Hu,

Maurizio Rossi Critical Stability 2014 October 13, 2014 – Santos (Brazil) Department of Physics and Astronomy “Galileo Galilei”

A chaotic collection of thoughts on stochastic transport what are the issues that M3D must consider to accurately determine heat transport which analytical.

Efimov Physics with Ultracold Atoms Selim Jochim Max-Planck-Institute for Nuclear Physics and Heidelberg University.

Experimental study of Efimov scenario in ultracold bosonic lithium

Phase Separation and Dynamics of a Two Component Bose-Einstein Condensate.

Coupling of (deformed) core and weakly bound neutron M. Kimura (Hokkaido Univ.)

Triatomic states in ultracold gases Marcelo Takeshi Yamashita Universidade Estadual Paulista - Brazil  Lauro Tomio – IFT / Unesp  Tobias Frederico –

Trap loss of spin-polarized 4 He* & He* Feshbach resonances Joe Borbely ( ) Rob van Rooij, Steven Knoop, Wim Vassen.

Efimov physics in ultracold gases Efimov physics in ultracold gases Rudolf Grimm “Center for Quantum Optics” in Innsbruck Austrian Academy of Sciences.

NCN nanoHUB.org Wagner The basics of quantum Monte Carlo Lucas K. Wagner Computational Nanosciences Group University of California, Berkeley In collaboration.

Application of correlated basis to a description of continuum states 19 th International IUPAP Conference on Few- Body Problems in Physics University of.

Part A - Comments on the papers of Burovski et al. Part B - On Superfluid Properties of Asymmetric Dilute Fermi Systems Dilute Fermi Systems.

Scales of critically stable few-body halo system Tobias Frederico Instituto Tecnológico de Aeronáutica São José dos Campos - Brazil  Marcelo T. Yamashita.

Experimental determination of Universal Thermodynamic Functions for a Unitary Fermi Gas Takashi Mukaiyama Japan Science Technology Agency, ERATO University.

Application of the operator product expansion and sum rules to the study of the single-particle spectral density of the unitary Fermi gas Seminar at Yonsei.

Unitarity potentials and neutron matter at unitary limit T.T.S. Kuo (Stony Brook) H. Dong (Stony Brook), R. Machleidt (Idaho) Collaborators:

VERSITET NIKOLAJ THOMAS ZINNER DEPARTMENT OF PHYSICS AND ASTRONOMY AARHUS UNIVERSITET OCTOBER UNI STRONGLY INTERACTING QUANTUM PARTICLES IN ONE.

Interacting Molecules in a Dense Fluid

Quantum Monte Carlo Simulations of Mixed 3 He/ 4 He Clusters Dario Bressanini Universita’ degli.

D. Jin JILA, NIST and the University of Colorado $ NIST, NSF Using a Fermi gas to create Bose-Einstein condensates.

Daniel Hrivňák a, František Karlický a, Ivan Janeček a, Ivana Paidarová b, and René Kalus a a Department of Physics, University of Ostrava, Ostrava, Czech.

Strong tensor correlation in light nuclei with tensor-optimized antisymmetrized molecular dynamics (TOAMD) International symposium on “High-resolution.

Adiabatic hyperspherical study of triatomic helium systems

Precision collective excitation measurements in the BEC-BCS crossover regime 15/06/2005, Strong correlations in Fermi systems A. Altmeyer 1, S. Riedl 12,

Computational Physics (Lecture 11) PHY4061. Variation quantum Monte Carlo the approximate solution of the Hamiltonian Time Independent many-body Schrodinger’s.

Few-body approach for structure of light kaonic nuclei Shota Ohnishi (Hokkaido Univ.) In collaboration with Tsubasa Hoshino (Hokkaido Univ.) Wataru Horiuchi.

Comp. Mat. Science School Electrons in Materials Density Functional Theory Richard M. Martin Electron density in La 2 CuO 4 - difference from sum.

Few-Body Models of Light Nuclei The 8th APCTP-BLTP JINR Joint Workshop June 29 – July 4, 2014, Jeju, Korea S. N. Ershov.

Agenda Brief overview of dilute ultra-cold gases

NTNU 2011 Dimer-superfluid phase in the attractive Extended Bose-Hubbard model with three-body constraint Kwai-Kong Ng Department of Physics Tunghai University,

7/11/20161 Harmonic Effective Field Theory U. van Kolck University of Arizona with B. Barrett (Arizona) J. Rotureau (Arizona) I. Stetcu (Washington) Supported.

Deterministic preparation and control of a few fermion system.

Local Density Functional Theory for Superfluid Fermionic Systems The Unitary Fermi Gas The Unitary Fermi Gas A.Bulgac, University of Washington arXiv:cond-mat/ ,

Low energy scattering and charmonium radiative decay from lattice QCD

Open quantum systems.

Local Density Functional Theory for Superfluid Fermionic Systems

Local Density Functional Theory for Superfluid Fermionic Systems

Hyperspherical adiabatic description of 3n and 4n states

Spectroscopy of ultracold bosons by periodic lattice modulations

Di-nucleon correlations and soft dipole excitations in exotic nuclei

Presentation transcript:

Numerical Studies of Universality in Few-Boson Systems Javier von Stecher Department of Physics and JILA University of Colorado Probable configurations of a weakly-bound four-boson state. Acknowledgements: Doerte Blume Seth Rittenhouse Nirav Mehta NSF In collaboration with Chris H. Greene Jose P. D’Incao

 How does Efimov physics and universality extends beyond three bodies?

Outline:  Universality in four-boson systems  Numerical formulation (CG and CGH)  Four-bosons predictions  Extension to larger systems  Model Hamiltonian  Cluster states

Outline:  Universality in four-boson systems  Numerical formulation (CG and CGH)  Four-bosons predictions  Extension to larger systems  Model Hamiltonian  Cluster states

Solving the Schrödinger equation Hamiltonian: Four-body Formulation model interactions:rV(r) d0d0d0d0 a<0 a>0 V0V0V0V0a dimer energy scattering length - or combinations of Gaussians

 Analytical form of matrix elements (accurate and fast).  Efficient Optimization: Stochastical variational method  Good for bound states.  Difficult to describe scattering properties Correlated Gaussian basis set expansion: r 12 r 13 r 24 r 34 r 14 r remove CM and set L=0 Symmetrization: spin statistic basis functions: Four-body Formulation

Hyperspherical representation: Coupled 1D equations …solved at fixed R. Use correlated Gaussian to expand channel functions Divide and conquer: Find efficient way to evaluate matrix elements R  Accurate description of four-body systems!! R: overall size (collective motion) typical potential curves Four-body Formulation J. von Stecher, C. H. Greene PRA (2009)

Hyperspherical Picture R Fragmentation thresholds All particles close together: Bound and quasi- bound states Interaction region U(R U(R) …for scattering properties. Four-body Formulation

s 0 = (CG) s 0 = (CGH)  Universality arguments predict that the hyperspherical potential curves are of the type (Tan, Werner & Castin, …): J. von Stecher, C. H. Greene PRA (2009) J. von Stecher, D. Blume, C. H. Greene PRL 2007, PRA 2007, 2008 S.Y. Chang, and G. F. Bertsch PRA (R) (2007) I. Stetcu, B. Barrett, U. van Kolck, J. Vary. PRA (2007) Y. Alhassid, G. F. Bertsch, and L. Fang PRL (2008) ….. Trap system predictions: Four fermion system at unitarity  Appropriate framework to analyze universality D.S. Petrov, C. Salomon, G.V. Shlyapnikov PRL (2004) Connection to trapped system: trap frequency Predictions: See also: J. P. D’Incao et al PRA (2009) Hyperspherical Picture …for studying universality Four-body Formulation

Outline:  Universality in four-boson systems  Numerical formulation (CG and CGH)  Four-bosons predictions  Extension to larger systems  Model Hamiltonian  Cluster states

, … 3 body 4 body Efimov scaling Two four- body states same scaling relations!!! Universality in four bosons a=a= J. von Stecher, J. P. D’Incao and C. H. Greene, Nat. Phys. (2009) In agreement with Hammer & Platter EJPA (2007) (Hammer presentation)

R R 3 bodies 4 bodies Hyperspherical Picture (a=  ) Four-body potential curves follow the same scaling of the Efimov states !!! Four-body physics is universal!!

R R 3 bodies 4 bodies Hyperspherical Picture (a=  ) Four-body potential curves follow the same scaling of the Efimov states !!! Four-body physics is universal!! Three-body parameter:

R R 3 bodies 4 bodies Hyperspherical Picture (a=  ) Four-body potential curves follow the same scaling of the Efimov states !!! Four-body physics is universal!! Three-body parameter:

Four-body states a=a= J. von Stecher, J. P. D’Incao and C. H. Greene, Nat. Phys. (2009) Hammer & Platter prediction: Agreement with Hammer & Platter (2007)

Spectrum: Extended Efimov plot  1/a J. von Stecher, J. P. D’Incao and C. H. Greene, Nat. Phys. (2009)  Calculations at more than 500 scattering lengths!!! atom-trimer thresholds (green lines) four-body states (black lines) dimer-dimer threshold (red lines) dimer-two atoms threshold (red lines)

Universality away from unitarity

a<0

Universality away from unitarity Universal four-body resonances in ultracold atomic and molecular gases J. P. D’Incao This afternoon:  Important for collisional properties  Experimental observations a>0 a<0 (Innsbruck, LENS)

Outline:  Universality in four-boson systems  Numerical formulation (CG and CGH)  Four-bosons predictions  Extension to larger systems  Model Hamiltonian  Cluster states

 How to extend the analysis of universality to larger systems?

Helium and spin-polarized tritium: similar behavior Extension to larger systems Other studies: Lewerenz, JCP (1997). Blume & Greene, JCP(2000). Hanna & Blume, PRA (2006). … Blume et al., PRL(2002)  How many parameters are needed to describe N-boson systems? Hammer & Platter, EPJA (2007). Linear correlations between cluster energies (like Tjon lines) Hanna & Blume, PRA (2006):

Outline:  Universality in four-boson systems  Numerical formulation (CG and CGH)  Four-bosons predictions  Extension to larger systems  Model Hamiltonian  Cluster states

short-range physics 3 bodies Universal region Model Hamiltonian Hyperspherical potential at unitatity dilute and weakly bound ~ universal controlled by short-range physics J. von Stecher arXiv: (2009) R  Goal: construct a minimal Hamiltonian that would lead to a “universal ground state”.

short-range physics 3 bodies Universal region Model Hamiltonian Hyperspherical potential at unitatity dilute and weakly bound ~ universal !! RCRC Lowest state is universal !!! J. von Stecher arXiv: (2009)  Goal: construct a minimal Hamiltonian that would lead to a “universal ground state”.

Model Hamiltonian controls three- body physics: 3-body parameter controls two-body physics: scattering length Many-body Hamiltonian: J. von Stecher arXiv: (2009)

Model Hamiltonian Many-body Hamiltonian: 3 bodies 2 bodies r ij  (r ij ) Bethe Peierls boundary condition  Two parameters (a and R c ) to independently control two and three-body physics. U(R U(R) RCRC J. von Stecher arXiv: (2009) Hard core three-body potential

Numerical methods J. von Stecher arXiv: (2009)  Correlated Gaussian basis set expansion up to N=6.  Diffusion Monte Carlo simulations up to N=13. Gaussian potential for two and three-body interactions Hard Wall 3-body potential and an attractive square 2-body potential Trial wave function: 3-body correlations 2-body correlations HR correlations

Outline:  Universality in four-boson systems  Numerical formulation (CG and CGH)  Four-bosons predictions  Extension to larger systems  Model Hamiltonian  Cluster states

Weakly-bound Clusters Universal description: (just from dimensional analysis) Universal function Numerical predictions: J. von Stecher arXiv: (2009) Comparison with other predictions Comparison between CG and DMC  At least one N-body cluster state for each Efimov trimer!!

 “Super” Borromean states  Linear Correlations (Tjon lines):  N-body resonant enhancement of losses: Weakly-bound Clusters J. von Stecher arXiv: (2009) Position of five-body resonance: Semi-Classical Methods and N-Body Recombination S. Rittenhouse This afternoon: Properties: Positions of resonances

Dilute Clusters Pair correlation function Trayectories extracted from Quantum Monte Carlo simulations Sphere radius: ~ 4r 0 ~R c Five-body cluster state: r m ~ 7R c ~ 30 r 0 ~ 2R c N=3 N=6 J. von Stecher arXiv: (2009)

R N bodies Hyperspherical Picture Helium clusters Monte Carlo + Hyperspherical D. Blume & C. H. Greene, JCP  Potential curves scale with size and energy of cluster states  All clusters follow Efimov scaling relations J. von Stecher arXiv: (2009) …sketching potentials

Extract width of four-body states Different species or/and spin statistic? – Universality? – Four-body states? Model Hamiltonian – with Quantum Monte Carlo Cluster states – Large N limit Outlook:

Energy per particle at unitarity

Four-body states a=a= J. von Stecher, J. P. D’Incao and C. H. Greene, Nat. Phys. (2009) Hammer & Platter prediction:

Four-body states  Weakly bound atom trimer state: Large and positive atom-trimer scattering length Agreement with Hammer & Platter (2007) a=a= J. von Stecher, J. P. D’Incao and C. H. Greene, Nat. Phys. (2009) atom- trimer correlation trimer correlation Pair correlations

a>0 a<0 Blue: atom-trimer Red: dimer-dimer Green dimer-2-atoms

Deviations from universality J. von Stecher, J. P. D’Incao and C. H. Greene, Nat. Phys. (2009)  Deviations: 2nd order four-body corrections or numerical limitations? Non universalUniversal  Scattering length ratios for a<0 depends weakly on nonuniversal effects!! less than 5% deviations  Different potentials  Different Efimov states Universal Non Universal Testing universality: