Motivated by the calculation of correlation functions in inhomogeneous one-dimensional (1d) quantum systems, the 2d Inhomogeneous Gaussian Free Field (IGFF) is studied and solved. The IGFF is defined in a domain Ω ⊂ 2 equipped with a conformal class of metrics [g] and with a real positive coupling constant K : Ω → >0 by the action
The recent results of [J. Dubail, J.-M. Stéphan, J. Viti, P.
Calabrese, Scipost Phys. 2, 002 (2017)], which aim at providing access
to large scale correlation functions of inhomogeneous critical
one-dimensional quantum systems —e.g. a gas of hard core bosons in a
trapping potential— are extended to a dynamical situation: a breathing
gas in a time-dependent harmonic trap. Hard core bosons in a
time-dependent harmonic potential are well known to be exactly solvable,
and can thus be used as a benchmark for the approach. An extensive
discussion of the approach and of its relation with classical and
quantum hydrodynamics in one dimension is given, and new formulas for
correlation functions, not easily obtainable by other methods, are
derived. In particular, a remarkable formula for the large scale
asymptotics of the bosonic \boldsymbol{n}𝐧-particle
function
\boldsymbol{\left< \Psi^\dagger (x_1,t_1) \dots \Psi^\dagger (x_n,t_n) \Psi(x_1',t_1') \dots \Psi(x_n',t_n') \right>}
is obtained. Numerical checks of the approach are carried out for the
fermionic two-point function —easier to access numerically in the
microscopic model than the bosonic one— with perfect agreement.
The one-particle density matrix of the one-dimensional Tonks-Girardeau gas with inhomogeneous density profile is calculated, thanks to a recent observation that relates this system to a two-dimensional conformal field theory in curved space. The result is asymptotically exact in the limit of large particle density and small density variation, and holds for arbitrary trapping potentials. In the particular case of a harmonic trap, we recover a formula obtained by Forrester et al.[23] from a different method.
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