Litcius/Paper detail

Eliminating the wave-function singularity for ultracold atoms by a similarity transformation

Péter Jeszenszki, Ulrich Ebling, Hongjun Luo, Ali Alavi, Joachim Brand

2020Physical Review Research20 citationsDOIOpen Access PDF

Abstract

A hyperbolic singularity in the wave function of s-wave interacting atoms is the root problem for any accurate numerical simulation. Here, we apply the transcorrelated method, whereby the wave-function singularity is explicitly described by a two-body Jastrow factor, and then folded into the Hamiltonian via a similarity transformation. The resulting nonsingular eigenfunctions are approximated by stochastic Fock-space diagonalization with energy errors scaling with 1/M in the number M of single-particle basis functions. The performance of the transcorrelated method is demonstrated on the example of strongly correlated fermions with unitary interactions. The current method provides the most accurate ground-state energies so far for three and four fermions in a rectangular box with periodic boundary conditions.

Topics & Concepts

SingularityPhysicsUnitary transformationEigenfunctionHamiltonian (control theory)FermionScalingInvertible matrixWave functionMatrix similarityQuantum mechanicsUnitary stateEssential singularityPeriodic boundary conditionsMathematical physicsEigenvalues and eigenvectorsBoundary value problemClassical mechanicsEnergy spectrumDynamical billiardsLanczos resamplingFunction (biology)Boundary (topology)Ultracold atomTransformation (genetics)Parity (physics)Potential energyOrthonormalitySingularity theoryMetric (unit)MathematicsAmplitudeEnergy (signal processing)Similarity (geometry)Cold Atom Physics and Bose-Einstein CondensatesQuantum Information and CryptographyQuantum Computing Algorithms and Architecture
Eliminating the wave-function singularity for ultracold atoms by a similarity transformation | Litcius