TY - JOUR
T1 - Bosonic and fermionic Gaussian states from Kähler structures
AU - Hackl, Lucas
AU - Bianchi, Eugenio
N1 - Funding Information:
LH acknowledges support by VILLUM FONDEN via the QMATH center of excellence (grant No. 10059). EB acknowledges support by the NSF via the Grant PHY-1806428.
Publisher Copyright:
Copyright L. Hackl and E. Bianchi.
PY - 2021/7
Y1 - 2021/7
N2 - We show that bosonic and fermionic Gaussian states (also known as “squeezed coherent states”) can be uniquely characterized by their linear complex structure J which is a linear map on the classical phase space. This extends conventional Gaussian methods based on covariance matrices and provides a unified framework to treat bosons and fermions simultaneously. Pure Gaussian states can be identified with the triple (G, Ω, J) of compatible Kähler structures, consisting of a positive definite metric G, a symplectic form Ω and a linear complex structure J with J2 = -1. Mixed Gaussian states can also be identified with such a triple, but with J2 6= -1. We apply these methods to show how computations involving Gaussian states can be reduced to algebraic operations of these objects, leading to many known and some unknown identities. We apply these methods to the study of (A) entanglement and complexity, (B) dynamics of stable systems, (C) dynamics of driven systems. From this, we compile a comprehensive list of mathematical structures and formulas to compare bosonic and fermionic Gaussian states side-by-side.
AB - We show that bosonic and fermionic Gaussian states (also known as “squeezed coherent states”) can be uniquely characterized by their linear complex structure J which is a linear map on the classical phase space. This extends conventional Gaussian methods based on covariance matrices and provides a unified framework to treat bosons and fermions simultaneously. Pure Gaussian states can be identified with the triple (G, Ω, J) of compatible Kähler structures, consisting of a positive definite metric G, a symplectic form Ω and a linear complex structure J with J2 = -1. Mixed Gaussian states can also be identified with such a triple, but with J2 6= -1. We apply these methods to show how computations involving Gaussian states can be reduced to algebraic operations of these objects, leading to many known and some unknown identities. We apply these methods to the study of (A) entanglement and complexity, (B) dynamics of stable systems, (C) dynamics of driven systems. From this, we compile a comprehensive list of mathematical structures and formulas to compare bosonic and fermionic Gaussian states side-by-side.
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U2 - 10.21468/SciPostPhysCore.4.3.025
DO - 10.21468/SciPostPhysCore.4.3.025
M3 - Article
AN - SCOPUS:85119823398
SN - 2666-9366
VL - 4
JO - SciPost Physics Core
JF - SciPost Physics Core
IS - 3
M1 - 025
ER -