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Kubo formula
The Reality of Casimir Friction
Green-Kubo Formula for Open Systems
Quantum Noise and Quantum Measurement
Quantum Dissipation and Decoherence of Collective Telefon 08 21/598-32 34 Prof
Conductance of Single Electron Devices from Imaginary–Time Path Integrals
LINEAR RESPONSE THEORY 3.1 the Generalized Susceptibility
Conductivity Tensor of Graphene Dominated by Spin-Orbit
The Optical Conductivity of Dirac Materials
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ELECTRICAL RESISTIVITY of a THIN METALLIC FILM 15 783 Cally Zero; However, This Line of Reasoning Is Simplistic: the Tum Loss As Outgoing Boundary Conditions
The Green-Kubo Formula and the Onsager Reciprocity Relations in Quantum Statistical Mechanics Vojkan Jaksic, Yoshiko Ogata, Claude-Alain Pillet
Linear Response Theory — a Modern Analytic-Algebraic Approach
Arxiv:2104.02428V2 [Cond-Mat.Quant-Gas] 11 Apr 2021 Physics [13–19] Has Become Quite Active, Mostly for Its General Theory
Quantum Transport Through Open Systems
Linear Response Theory in Quantum Statistical Mechanics Vojkan Jaksic, Yoshiko Ogata, Claude-Alain Pillet
Boltzmann Equation and Kubo Formula Branislav K
Concepts of Many-Body Physics
Linear Response Theory: the Connection Between QFT and Experiments
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Quantum Pumping in Closed Systems, Adiabatic Transport, and the Kubo
Reworking Zubarev's Approach to Nonequilibrium Quantum Statistical
Scattering Theory Approach to Electrodynamic Casimir Forces 7-)'
A New Regularization Procedure for Calculating the Casimir Energy
Linear Response Theory of Entanglement Entropy
Geometry and Response of Lindbladians
Electron Quantum Optics at Fractional Filling Factor
The Green-Kubo Formula and the Onsager Reciprocity Relations in Quantum Statistical Mechanics
Comparison of the Kubo Formula, the Microscopic Response Method, and the Greenwood Formula
Statistical Field Theory
Mesoscopic Transport and Quantum Chaos Oogle
Theory of Electric Transport
Deconstructing Kubo Formula Usage: Exact Conductance of a Mesoscopic System from Weak to Strong Disorder Limit
Arxiv:0810.4729V2 [Cond-Mat.Mes-Hall] 15 Apr 2010 A
The Casimir Effect in Topological Matter
Relativistic Electronic Transport Theory - the Spin Hall Effect and Related Phenomena
Quantum Transport Calculations Using Wave Function Propagation and the Kubo Formula
Black Holes and Chaos
Fast Converging Path Integrals for Time-Dependent Potentials: I
Disordered Electronic Systems
Arxiv:1811.07387V3 [Cond-Mat.Mes-Hall] 20 Aug 2020 Comparison
The Quantum Hall Effect
Green-Kubo Formula for Thermal Conductivity
PHY-892 Problème À N-Corps (Notes De Cours)
Quantum Pumping in Closed Systems, Adiabatic Transport, and the Kubo Formula
Coherence and Quantum Noise in Mesoscopic Physics
Quantum Dynamics of Charged Fermions in the Wigner Formulation of Quantum Mechanics
Nonequilibrium Temperature Response for Stochastic Overdamped Systems
Coherent Quantum Transport in Anisotropic Two Dimensional Systems in Magnetic fields
A Toy Model for Time Evolving QFT on a Lattice with Controllable Chaos
4. Linear Response
Electron Transport, Interaction and Spin in Graphene and Graphene Nanoribbons
M.Sc Physics 2016-18
Lecture Notes
Arxiv:2001.06993V5 [Cond-Mat.Mes-Hall] 21 Mar 2021
Statistical Mechanics
Arxiv:Cond-Mat/9707301V1 29 Jul 1997 I Hoeia Aspects Theoretical III 1983 and 1951 Between Period the Survey: Historical Introduction II I Nrdcint Uesmer
Dissipative Dynamics of Non-Interacting Fermion Systems and Conductivity
Justifying Kubo's Formula for Gapped Systems at Zero Temperature
Physics 215A: Particles and Fields Fall 2017
Quantum Transport in Finite Disordered Electron Systems
Chapter 6 ELECTRON TRANSPORT
Energy Transport and Relaxation in One-Dimensional Hamiltonian Systems
The Kubo Formula of the Electric Conductivity We Consider an Electron Under the Influence of an Electric field E(T)