Schwinger-Keldysh superspace in quantum mechanics

We examine, in a quantum mechanical setting, the Hilbert space representation of the BRST symmetry associated with Schwinger-Keldysh path integrals. This structure had been postulated to encode important constraints on influence functionals in coarse-grained systems with dissipation, or in open quantum systems. Operationally, this entails uplifting the standard Schwinger-Keldysh two-copy formalism into superspace by appending BRST ghost degrees of freedom. These statements were previously argued at the level of the correlation functions. We provide herein a complementary perspective by working out the Hilbert space structure explicitly. Our analysis clarifies two crucial issues not evident in earlier works: firstly, certain background ghost insertions necessary to reproduce the correct Schwinger-Keldysh correlators arise naturally. Secondly, the Schwinger-Keldysh difference operators are systematically dressed by the ghost bilinears, which turn out to be necessary to give rise to a consistent operator algebra. We also elaborate on the structure of the final state (which is BRST closed) and the future boundary condition of the ghost fields.

[1]  R. Loganayagam,et al.  Renormalization in open quantum field theory. Part I. Scalar field theory , 2017, 1704.08335.

[2]  R. Loganayagam,et al.  Renormalization in Open Quantum Field theory I: Scalar field theory , 2017 .

[3]  M. Rangamani,et al.  Two roads to hydrodynamic effective actions: a comparison , 2017, 1701.07896.

[4]  A. Yarom,et al.  Dissipative hydrodynamics in superspace , 2017, Journal of High Energy Physics.

[5]  M. Rangamani,et al.  Classification of out-of-time-order correlators , 2017, SciPost Physics.

[6]  M. Rangamani,et al.  Schwinger-Keldysh formalism. Part I: BRST symmetries and superspace , 2016, 1610.01940.

[7]  M. Rangamani,et al.  Schwinger-Keldysh formalism. Part II: thermal equivariant cohomology , 2016, 1610.01941.

[8]  R. Pius,et al.  Cutkosky rules for superstring field theory , 2016, 1604.01783.

[9]  M. Rangamani,et al.  Topological sigma models & dissipative hydrodynamics , 2015, 1511.07809.

[10]  M. Crossley,et al.  Effective field theory of dissipative fluids , 2015, 1511.03646.

[11]  M. Rangamani,et al.  The fluid manifesto: emergent symmetries, hydrodynamics, and black holes , 2015, 1510.02494.

[12]  Shuangshuang Fu,et al.  Channel-state duality , 2013 .

[13]  H. Weldon Two sum rules for the thermal n-point functions , 2005 .

[14]  F. Wilczek,et al.  Quantum Field Theory , 1998, Compendium of Quantum Physics.

[15]  B. Hao,et al.  EQUILIBRIUM AND NONEQUILIBRIUM FORMALISMS MADE UNIFIED , 1985 .

[16]  R. Feynman,et al.  The Theory of a general quantum system interacting with a linear dissipative system , 1963 .

[17]  J. Schwinger Brownian Motion of a Quantum Oscillator , 1961 .

[18]  L. Keldysh Diagram technique for nonequilibrium processes , 1964 .