Exact Results in Quantum Theory
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2016-06-10 (Piątek)
Miłosz Panfil (IFT UW)
Quench Dynamics in Two-Dimensional (Integrable) SUSY Models
I will analyse quench processes in two dimensional quantum field theories with infinite number of conservation laws which also include fermionic charges that close a N=1 supersymmetric algebra. While in general the quench protocol induces a breaking of supersymmetry, we show that there are particular initial states which ensure the persistence of supersymmetry also for the dynamics out of equilibrium. We will discuss the conditions that identify such states and, as application, we present the significant case of the Sine-Gordon model at its supersymmetric point. I will also address the issue of the Generalized Gibbs Ensemble in the presence of fermionic conserved charges. If time allows we will also discuss the N=2 SUSY case where it is possible to compute exactly the infinite-time limit of certain correlation functions.
2016-06-03 (Piątek)
Grzegorz Łach (IFT UW)
Atom-atom interactions with retardation and without Born-Oppenheimer approximation
The interaction energy between two ground-state atoms behaves as 1/R^6.for distances smaller then that of the lowest transition wavelength, and so does the finite nuclear mass correction to the energy. For larger distances the interaction energy is modified by the retardation of the electromagnetic interactions and asymptotically falls-off as 1/R^7. We have derived the finite nuclear mass correction to the retardation of the atom-atom potential, and have shown that besides the expected contribution from the finite masscorrection to atomic matrix elements another term is present.
2016-05-27 (Piątek)
Seminarium nie odbędzie się
2016-05-20 (Piątek)
Andrzej Dragan (IFT UW)
Still not quite decided what will be the content, but itwill be something interesting at the intersection of quantum theoryand relativity and, as required by the theme of the seminar discussedthe results will be analytical.
Coś kwantowego i relatywistycznego
Something quantum and relativistic
Jeszcze nie do końca zdecydowałem, jaka będzie zawartośćreferatu, ale bedzie o czymś ciekawym na przecięciu teorii kwantowej irelatywistycznej oraz, jak wymaga tego tematyka seminarium, omówionerezultaty beda ścisle.
Still not quite decided what will be the content, but itwill be something interesting at the intersection of quantum theoryand relativity and, as required by the theme of the seminar discussedthe results will be analytical.
2016-05-13 (Piątek)
Axel Cortes Cubero (SISSA Triest)
In and out of equilibrium thermodynamics of planar field theories: exact results
We study the thermodynamics of a (1+1)-dimensional integrable quantum field theory in the planar infinite N limit. Unlike isovector-valued O(N) models, matrix valued field theories in the infinite-N are not solvable by the Hartre-Fock approximation, and are nontrivial interacting theories. By combining the planar limit with integrable bootstrap techniques, one can compute the exact S-matrix, form factors and correlation functions. Thermal expectation values are easily computable as a form factor sum, since many difficult terms are suppressed by powers of 1/N. We also compute out of equilibrium, time dependent correlation functions after a quantum quench, which are also simplified by discarding 1/N suppressed terms. These 1/N suppressions are not related to integrability, and can greatly simplify the computation in other models that are not exactly solvable.
2016-04-29 (Piątek)
Leszek Stolarczyk (PChK WCh UW)
Quasiparticle model of many-fermion systems based on the Coupled-Cluster Ansatz, part II
Given a system of many interacting fermions described by a time-independent Hamiltonian Ĥ, the Coupled-Cluster (CC) Ansatz introduces an exponential representation of the Hamiltonian eigenstates: Ψ = exp(T̂) Φ, where Φ is some indpendent-fermion wave function, and T̂ is the so-called cluster operator which produces excitations out of Ψ. The CC Ansatz has turned out to be a very effective computational tool in quantum chemistry and nuclear theory.In my talk I will present a general mathematical model of many-fermion systems based on the notion of quasiparticles and the CC Ansatz. This model, called the quasiparticle Fock-space coupled-cluster (QFSCC) theory, was introduced in 1985 by me and Henk Monkhorst.The departing point is the second-quantization formalism based on the algebraic approximation: one chooses a finite basis of single-fermion states (the spin orbitals), and builds the fermionic Fock space which represent all possible antisymmetric many-fermion states of a given system. A necessary algebraic machinery is provided by the algebra of linear operators acting in the Fock space, generated by the fermion creation and annihilation operators. The physics is governed by the Fock-space Hamiltonian operator Ĥ, commuting with the fermion-number operator N̂, that determines the system stationary states and their energies.The first step into the QFSCC theory is to apply the Bogoliubov-Valatin transformation, which converts the primary fermionic particles into some fermionic quasiparticles. Then one arrives at a new representation of the Fock basis: the new hierarchy of states is built upon the quasiparticle vacuum instead of the physical vacuum. The new creation and annihilation operators (which now correspond to the quasiparticles) fulfill the same anticommutation relations as the old (original) ones. By rewriting the Hamiltonian Ĥ with the help of the new quasiparticle operators, one immediately realizes that Ĥ does not commute with the quasiparticle-number operator N̂q.The crucial step in the QFSCC theory is to enforce the quasiparticle-number conservation principle. This is done by applying a special similarity transformation which converts Ĥ into the quasiparticle Hamiltonian Ĝ that explicitly commutes with N̂q. The corresponding transformation operator is built by employing the CC Ansatz, which has to be substantially generalized for this purpose. Now the spectrum of Ĝ corresponding to 0, 1, 2,... quasiparticles can be easily found -- this is equivalent to calculating a part of the spectrum of Ĥ corresponding to some N, N±1, N±2,... fermion states (where the ground state of the system, represented by the quasiparticle vacuum, is a N-fermion state).The QFSCC theory requires a substantial reformulation of the traditional second-quantization language, by making a full use of the algebraic properties of the Fock space and its operator algebra. In particular, the role of operators not conserving the number of particles (or quasiparticles) is emphasized. These "algebraic preparations" will be presented in detail in Part I of my talk.In Part II of my talk a step-by-step construction of the QFSCC theory will be performed. It will be seen that the emerging quasiparticle model of many-fermion systems offers useful physical insights and computational effectiveness, provided a natural truncation/decoupling scheme. I will also introduce a terse diagrammatic language to write down the working CC equations.
2016-04-22 (Piątek)
Leszek Stolarczyk (PChK WCh UW)
Quasiparticle model of many-fermion systems based on the Coupled-Cluster Ansatz
Given a system of many interacting fermions described by a time-independent Hamiltonian Ĥ, the Coupled-Cluster (CC) Ansatz introduces an exponential representation of the Hamiltonian eigenstates: Ψ = exp(T̂) Φ, where Φ is some indpendent-fermion wave function, and T̂ is the so-called cluster operator which produces excitations out of Ψ. The CC Ansatz has turned out to be a very effective computational tool in quantum chemistry and nuclear theory.In my talk I will present a general mathematical model of many-fermion systems based on the notion of quasiparticles and the CC Ansatz. This model, called the quasiparticle Fock-space coupled-cluster (QFSCC) theory, was introduced in 1985 by me and Henk Monkhorst.The departing point is the second-quantization formalism based on the algebraic approximation: one chooses a finite basis of single-fermion states (the spin orbitals), and builds the fermionic Fock space which represent all possible antisymmetric many-fermion states of a given system. A necessary algebraic machinery is provided by the algebra of linear operators acting in the Fock space, generated by the fermion creation and annihilation operators. The physics is governed by the Fock-space Hamiltonian operator Ĥ, commuting with the fermion-number operator N̂, that determines the system stationary states and their energies.The first step into the QFSCC theory is to apply the Bogoliubov-Valatin transformation, which converts the primary fermionic particles into some fermionic quasiparticles. Then one arrives at a new representation of the Fock basis: the new hierarchy of states is built upon the quasiparticle vacuum instead of the physical vacuum. The new creation and annihilation operators (which now correspond to the quasiparticles) fulfill the same anticommutation relations as the old (original) ones. By rewriting the Hamiltonian Ĥ with the help of the new quasiparticle operators, one immediately realizes that Ĥ does not commute with the quasiparticle-number operator N̂q.The crucial step in the QFSCC theory is to enforce the quasiparticle-number conservation principle. This is done by applying a special similarity transformation which converts Ĥ into the quasiparticle Hamiltonian Ĝ that explicitly commutes with N̂q. The corresponding transformation operator is built by employing the CC Ansatz, which has to be substantially generalized for this purpose. Now the spectrum of Ĝ corresponding to 0, 1, 2,... quasiparticles can be easily found -- this is equivalent to calculating a part of the spectrum of Ĥ corresponding to some N, N±1, N±2,... fermion states (where the ground state of the system, represented by the quasiparticle vacuum, is a N-fermion state).The QFSCC theory requires a substantial reformulation of the traditional second-quantization language, by making a full use of the algebraic properties of the Fock space and its operator algebra. In particular, the role of operators not conserving the number of particles (or quasiparticles) is emphasized. These "algebraic preparations" will be presented in detail in Part I of my talk.In Part II of my talk a step-by-step construction of the QFSCC theory will be performed. It will be seen that the emerging quasiparticle model of many-fermion systems offers useful physical insights and computational effectiveness, provided a natural truncation/decoupling scheme. I will also introduce a terse diagrammatic language to write down the working CC equations.
2016-04-15 (Piątek)
Wojciech Kamiński (IFT UW)
Stress-energy tensor in QFT on curved background
2016-04-08 (Piątek)
Daniel Siemssen (IFT UW)
The Potential in General Linear Electrodynamics: Causal Structure, Propagators and Quantization
From an axiomatic point of view, the fundamental input for a theory of electrodynamics are Maxwell’s equations dF = 0 (or F = dA) and dH = J, and a constitutive law H = #F, which relates the field strength 2-form F and the excitation 2-form H. In this talk we consider general linear electrodynamics, the theory of electrodynamics defined by a linear constitutive law. The best known application of this theory is the effective description of electrodynamics inside (linear) media (e.g. birefringence). We will analyze the classical theory of the electromagnetic potential A before we use methods familiar from mathematical quantum field theory in curved spacetimes to quantize it. Our analysis of the classical theory contains the derivation of retarded and advanced propagators, the analysis of the causal structure on the basis of the constitutive law (instead of a metric) and a discussion of the classical phase space. This classical analysis sets the stage for the construction of the quantum field algebra and quantum states, including a (generalized) microlocal spectrum condition.
2016-04-01 (Piątek)
Junya Yagi (IFT UW)
Quiver gauge theories, TQFTs and integrable lattice models
I will explain how a certain class of supersymmetric gauge theories give rise to integrable lattice models in statistical mechanics, via topological quantum field theories (TQFTs). In this correspondence, Seiberg duality of gauge theory translates to the Yang-Baxter equation on the lattice model side. Time permitting, I will also discuss an application of the correspondence to surface defects in supersymmetric gauge theories.
2016-03-18 (Piątek)
Javier de Lucas (IFT UW)
Lie systems and geometric phases
A Lie system is a non-autonomous first-order ordinary differential equation admitting a (generally nonlinear) superposition rule, i.e. a function allowing us to describe the general solution of the Lie system in terms of a finite-family of particular solutions and a set of constants. Non-autonomous systems of first-order ordinary linear differential equations and matrix Riccati equations are the most simple examples of Lie systems.In the context of the Floquet theory, using a variation of parameter argument, we show that the logarithm of the monodromy of a real periodic Lie system with appropriate properties admits a splitting into two parts called dynamic and geometric phases. The dynamic phase is intrinsic and linked to the Hamiltonian of a periodic linear Euler system on the co-algebra. The geometric phase is represented as a surface integral of the symplectic form of a co-adjoint orbit. Results can be applied to the study of geometric phases of relevant physical models such as Winternitz-Smorodinsky oscillators.
2016-03-11 (Piątek)
Piotr Sułkowski (IFT UW)
Quantization, matrix models, and conformal field theory
I will present how to associate an infinite family of "quantum surfaces" to a given "classical" Riemann surface. I will explain how to construct such quantum surfaces in the formalism of matrix models, and present their beautiful interpretation in conformal field theory.
2016-03-04 (Piątek)
prof. Marek Napiórkowski (IFT UW)
"Critical Casimir forces and Bose-Einstein condensaton in an imperfect Bose gas"
I will introduce the model of an imperfect Bose gas. First, I will describe its bulk critical properties, the Bose-Einstein condensation in particular. Then, in the case of an imperfect Bose gas enclosed in a slit I will discuss the emerging critical Casimir forces with particular emphasis on thermodynamic states corresponding to the presence of the condensate.
2016-02-26 (Piątek)
Carmen Li (Penn State University)
Transverse deformations of extreme horizons
We consider the inverse problem of determining all extreme black hole solutions to the Einstein equations with a prescribed near-horizon geometry. We investigate this problem by considering infinitesimal deformations of the near-horizon geometry along transverse null geodesics. We show that, up to a gauge transformation, the linearised Einstein equations reduce to an elliptic PDE for the extrinsic curvature of a cross-section of the horizon. We deduce that for a given near-horizon geometry there exists a finite dimensional moduli space of infinitesimal transverse deformations. We then establish a uniqueness theorem for transverse deformations of the extreme Kerr horizon. In particular, we prove that the only smooth axisymmetric transverse deformation of the near-horizon geometry of extreme Kerr, such that cross-sections of the horizon are marginally trapped surfaces, corresponds to that of the extreme Kerr black hole. Furthermore, we determine all smooth and biaxisymmetric transverse deformations of the near-horizon geometry of extreme Myers-Perry black hole with equal angular momenta. We find a three parameter family of solutions such that cross-sections of the horizon are marginally trapped, which is more general than the known black hole solutions. We discuss the possibility that they correspond to new five dimensional vacuum black holes.
2016-01-22 (Piątek)
Wojciech Kamiński (IFT UW)
Asymptotics of classical 6-j and 10-j symbols
2016-01-15 (Piątek)
Jaromir Panas (IFT UW)
Dynamical mean-field theory study of the Bose-Hubbard model
Experiments with ultra-cold atoms in an optical lattice provide a highly-tunable quantum simulator of the Hubbard model. However, theoretical treatment of this model poses a formidable challenge. Analytic solutions are possible only in few, special cases and in general the problem needs to be simplified. In the presentation an approximation scheme of dynamical mean-field theory (DMFT) is discussed. The concept of this method is explained and it is argued why this approach is superior to the standard mean-field one. The bosonic counterpart of the DMFT method is introduced and several results for the Bose-Hubbard model are presented along with the comparison to the mean-field results.
2016-01-08 (Piątek)
Adrian Lewandowski (Albert Einstein Institute)
Chiral anomaly in nonlocal regularization
After a brief introduction to Ward identities in perturbative quantum fieldtheory I will show a simple derivation of abelian chiral anomaly in a class ofnatural smooth cutoff regularizations. The generalization to a non-abelian casewill be also discussed.
2015-12-11 (Piątek)
Prof. Ingo Runkel (Fachbereich Mathematik, Universität Hamburg)
"Defects as dictionary”
"Defects as dictionary”
Many different tools are available when studying quantum field theories: one can start from a classical action, one can constrain the correlation functions via symmetries, one can identify indices or topological subsectors which remain invariant under deformations, etc. The relations between these methods are often indirect and conjectural. In the example of two-dimensional field theories, I would like to explain how one-dimensional defect lines appear from various point of view, and how they can be valuable in linking different descriptions of quantum field theory.
2015-12-04 (Piątek)
— (—)
seminarium nie odbędzie się (ze względu na trwającą konferencję "Scalars 100")
this Friday our seminar is cancelled (due to ongoing "Scalars 100" conference)
2015-11-20 (Piątek)
Paweł Czachorowski (IFT UW)
Explicitly correlated exponential functions for H2 molecule - the Taylor series algorithm
Obtaining highly accurate energies of molecular systems requires a well-optimized set of basis functions. The commonly used explicitly correlated Gaussian (ECG) functions, despite the simplicity of integration algorithms, exhibit slow convergence and expectation values for some singular operators can converge to incorrect limit. In this talk I will present the techniques allowing the use of a much better class of functions for hydrogen molecule calculations: an explicitly correlated exponential basis. So far these functions were rarely used due to cumbersome integrals that arise during calculations. The algorithm for evaluation of these integrals via Taylor series, which is stable for all possible values of variational parameters, will be presented, together with a benchmark of nonrelativistic Born-Oppenheimer H2 energies.
2015-11-13 (Piątek)
Johannes Thürigen (MPI Potsdam)
Spin-foam sums for all Loop Quantum Gravity
2015-11-06 (Piątek)
Grzegorz Łach (IFT UW)
Casimir Friction
2015-10-30 (Piątek)
Alfred Michel Grundland (Centre de Recherches Mathematiques, Universite Montreal)
Soliton surfaces in the symmetry approach
In this talk, we investigate certain features of generalized symmetries of integrable systems in order to construct the Fokas-Gel'fand formula for the immersion of 2D-soliton surfaces in Lie algebras. We demonstrate that if there exists a common symmetry of the zero-curvature representation of an integrable PDE and its linear spectral problem then the Fokas-Gel'fand immersion formula is applicable in its original form. In the general case, we show that when a symmetry of the zero-curvature representation is not necessarily a symmetry of its linear spectral problem, the immersion function of a 2D-surface is governed by an extended formula involving additional terms in the expression for the tangent vectors. We show that the Sym-Tafel formula for the immersion of soliton surfaces in Lie algebras can be mapped to its counterparts, the Cieslinski-Doliwa formula and the Fokas-Gelfand formula. Finally, we illustrate these results by examples involving an elliptic ODE and the CPN-1 sigma model equation.
2015-10-23 (Piątek)
Vladimir Yerokhin (Center for Advanced Studies, Peter the Great St. Petersburg Polytechnic University)
Bound-electron g factor in light ions
Experiments on the bound-electron g factor provide one of the most stingent tests of the bound-state QED. In combination with sophisticated theoretical calculations, these experiments deliver presently the best determination of the electron mass. In my talk, I review the present status of theory and experiment of the g factor of light hydrogen-like and lithium-like ions. Perspectives for the determination of the fine structure constant from a weigthed difference of the g factors of hydrogen-like and lithlium-like ions are discussed.
2015-10-16 (Piątek)
Jan Dereziński (KMMF UW)
On the excitation spectrum of quantum gases II
A lot of interesting physical and mathematical information about quantum gases at zero temperature in large volume is encoded in the spectral properties of their Hamiltonian and their total momentum. The joint spectrum of these commuting self-adjoint operators after the subtraction of the ground state energy can be called the excitation spectrum. One can conjecture that in some situations the excitation spectrum should have an interesting shape characterized by a positive critical velocity, which is related to superfluidity.
2015-10-09 (Piątek)
Adam Latosiński (Max-Planck-Instutut für Gravitationsphysik, Potsdam-Golm)
Gauge covariant propagators: derivation and applications
The most commonly used metod of derivation of quantities in quantum field theory uses Feynman diagrams and Feynman propagators. Unfortunately, when applied to gauge theories, it mostly ignored the gauge symmetry, which becomes obscured at intermediate steps, and even in the final result it's not always visible. However there exist a manifestly covariant way to make calculations within a quantum field theory, with the use of gauge-field-dependent propagators instead of the free-field Feynman propagators.I'm going to present a way to derive gauge-field dependent propagators in the form that can be used in perturbative calculations made with Feynman diagrams and show several examples of application of such propagator in Feynman diagrams of different degree of complexity.
2015-10-02 (Piątek)
Jan Dereziński (KMMF UW)