Two-scale Homogenization and Numerical Methods for Stationary Mean-field Games

Yang, Xianjin

07 1900

Mean-field games (MFGs) study the behavior of rational and indistinguishable agents in a large population. Agents seek to minimize their cost based upon statis- tical information on the population’s distribution. In this dissertation, we study the homogenization of a stationary first-order MFG and seek to find a numerical method to solve the homogenized problem. More precisely, we characterize the asymptotic behavior of a first-order stationary MFG with a periodically oscillating potential. Our main tool is the two-scale convergence. Using this convergence, we rigorously derive the two-scale homogenized and the homogenized MFG problems. Moreover, we prove existence and uniqueness of the solution to these limit problems. Next, we notice that the homogenized problem resembles the problem involving effective Hamiltoni- ans and Mather measures, which arise in several problems, including homogenization of Hamilton–Jacobi equations, nonlinear control systems, and Aubry–Mather theory. Thus, we develop algorithms to solve the homogenized problem, the effective Hamil- tonians, and Mather measures. To do that, we construct the Hessian Riemannian flow. We prove the convergence of the Hessian Riemannian flow in the continuous setting. For the discrete case, we give both the existence and the convergence of the Hessian Riemannian flow. In addition, we explore a variant of Newton’s method that greatly improves the performance of the Hessian Riemannian flow. In our numerical experiments, we see that our algorithms preserve the non-negativity of Mather mea- sures and are more stable than related methods in problems that are close to singular. Furthermore, our method also provides a way to approximate stationary MFGs.

Mean-field Games

Homogenization

Effective Hamiltonian

Two-scale convergence

Hessian Riemannian Flow

Mather Measures

Quantum Decoherence in Time-Dependent Anharmonic Systems

Beus, Ty

15 June 2022

This dissertation studies quantum decoherence in anharmonic oscillator systems to monitor and understand the way the systems evolve. It also explores methods to control the systems' evolution, and the effects of decoherence when applicable. We primarily do this by finding the time evolution of the systems using their Lie algebraic structures. We solve for a generalized Caldirola-Kanai Hamiltonian, and propose a general way to produce a desired evolution of the system. We apply the analysis to the effects of Dirac delta fluctuations in mass and frequency, both separately and simultaneously. We also numerically demonstrate control of the generalized Caldirola-Kanai system for the case of timed Gaussian fluctuations in the mass term. This is done in a way that can be applied to any system that is made up of a Lie algebra. We also explore the evolution of an optomechanical coupled mirror-laser system while maintaining a second order coupling. This system creates anharmonic effects that can produce cat states which can be used for quantum computing. We find that the decoherence in this system causes a rotational smearing effect in the Husimi function which, with the second order term added, causes rotational smearing after a squeezing effect. Finally, we also address the dynamic evolution and decoherence of an anharmonic oscillator with infinite coupling using the Born-Markov master equation. This is done by using the Lie algebraic structure of the Born-Markov master equation's superoperators when applying a strategic mean field approximation to maintain dynamic flexibility. The system is compared to the Born-Markov master equation for the harmonic oscillator, the regular anharmonic oscillator, and the dynamic double anharmonic oscillator. Throughout, Husimi plots are provided to visualize the dynamic decoherence of these systems.

Quantum Dynamics

Anharmonic

Decoherence

Lie Algebra

Representation

Mean Field

Unitarity Conditions

Physical Sciences and Mathematics

Globalization and inequality in an agent-based wealth exchange model

Khouw, Timothy

24 February 2022

Agent-based asset exchange models serve as an interesting and tractable means by which to study the emergence of an economy's wealth distribution. Although asset exchange models have reproduced certain features of real-world wealth distributions, previous research has largely neglected the effects of economic growth and network connectivity between agents. In this work, we study the effects of globalization on wealth inequality in the Growth, Exchange, and Distribution (GED) model [Liu et al, Klein et al] on a network or lattice that connects potential trading partners. We find that increasing the number of trading partners per agent results in higher levels of wealth inequality as measured by the Gini coefficient and the variance of the agent wealth distribution. However, if globalization is accompanied by a proportionate increase in the economic growth rate, the level of inequality can be held constant. We present a mean-field theory to describe the GED model based on the Fokker-Planck equation and derive the stationary wealth distributions of the network GED model. For large Ginzburg parameter for which mean-field theory is applicable, the wealth distributions for the fully connected model are found to be Gaussian; however, for sparse trade networks, a non-Gaussian "hyperequal" phase is found even for large Ginzburg parameter. It is shown that several networks (Erdos-Renyi, Barabsi-Albert, one-dimensional and two-dimensional lattices) display mean-field critical exponents when the Ginzburg parameter is large and held constant and the system parameters are scaled properly.

Physics

Agent-based modeling

GED model

Globalization

Inequality

Mean-field theory

Yard sale model

Variational Discrete Action Theory

Cheng, Zhengqian

January 2021

This thesis focuses on developing new approaches to solving the ground state properties of quantum many-body Hamiltonians, and the goal is to develop a systematic approach which properly balances efficiency and accuracy. Two new formalisms are proposed in this thesis: the Variational Discrete Action Theory (VDAT) and the Off-Shell Effective Energy Theory (OET). The VDAT exploits the advantages of both variational wavefunctions and many-body Green's functions for solving quantum Hamiltonians. VDAT consists of two central components: the Sequential Product Density matrix (SPD) and the Discrete Action associated with the SPD. The SPD is a variational ansatz inspired by the Trotter decomposition and characterized by an integer N, and N controls the balance of accuracy and cost; monotonically converging to the exact solution for N → ∞. The Discrete Action emerges by treating the each projector in the SPD as an effective discrete time evolution. We generalize the path integral to our discrete formalism, which converts a dynamic correlation function to a static correlation function in a compound space. We also generalize the usual many-body Green's function formalism, which results in analogous but distinct mathematical structures due to the non-abelian nature of the SPD, yielding discrete versions of the generating functional, Dyson equation, and Bethe-Salpeter equation. We apply VDAT to two canonical models of interacting electrons: the Anderson impurity model (AIM) and the Hubbard model. We prove that the SPD can be exactly evaluated in the AIM, and demonstrate that N=3 provides a robust description of the exact results with a relatively negligible cost. For the Hubbard model, we introduce the local self-consistent approximation (LSA), which is the analogue of the dynamical mean-field theory, and prove that LSA exactly evaluates VDAT for d=∞. Furthermore, VDAT within the LSA at N=2 exactly recovers the Gutzwiller approximation (GA), and therefore N>2 provides a new class of theories which balance efficiency and accuracy. For the d=∞ Hubbard model, we evaluate N=2-4 and show that N=3 provides a truly minimal yet precise description of Mott physics with a cost similar to the GA. VDAT provides a flexible scheme for studying quantum Hamiltonians, competing both with state-of-the-art methods and simple, efficient approaches all within a single framework. VDAT will have broad applications in condensed matter and materials physics. In the second part of the thesis, we propose a different formalism, off-shell effective energy theory (OET), which combines the variational principle and effective energy theory, providing a ground state description of a quantum many-body Hamiltonian. The OET is based on a partitioning of the Hamiltonian and a corresponding density matrix ansatz constructed from an off-shell extension of the equilibrium density matrix; and there are dual realizations based on a given partitioning. To approximate OET, we introduce the central point expansion (CPE), which is an expansion of the density matrix ansatz, and we renormalize the CPE using a standard expansion of the ground state energy. We showcase the OET for the one band Hubbard model in d=1, 2, and ∞, using a partitioning between kinetic and potential energy, yielding two realizations denoted as K and X. OET shows favorable agreement with exact or state-of-the-art results over all parameter space, and has a negligible computational cost. Physically, K describes the Fermi liquid, while X gives an analogous description of both the Luttinger liquid and the Mott insulator. Our approach should find broad applicability in lattice model Hamiltonians, in addition to real materials systems. The VDAT can immediately be applied to generic quantum models, and in some cases will rival the best existing theories, allowing the discovery of new physics in strongly correlated electron scenarios. Alternatively, the OET provides a practical formalism for encapsulating the complex physics of some model and allowing extrapolation over all phase space. Both of the formalisms should find broad applications in both model Hamiltonians and real materials.

Physics

Materials science

Hamiltonian systems

Hubbard model

Quantum theory

Mean field theory

Bethe-Salpeter equation

Study on non-equilibrium quasi-stationary states for Hamiltonian systems with long-range interaction / 長距離相互作用を有するハミルトン系の非平衡準定常状態に関する研究

Ogawa, Shun

24 September 2013

京都大学 / 0048 / 新制・課程博士 / 博士(情報学) / 甲第17924号 / 情博第506号 / 新制||情||89(附属図書館) / 30744 / 京都大学大学院情報学研究科数理工学専攻 / (主査)教授 梅野 健, 教授 中村 佳正, 教授 船越 満明 / 学位規則第4条第1項該当 / Doctor of Informatics / Kyoto University / DFAM

statistical physics

quasi-stationary state

Vlasov equation

long-range interaction

Hamiltonian mean-field model

007

Theoretical study of correlated topological insulators / 相関効果をもつトポロジカル絶縁体の理論的研究

Yoshida, Tsuneya

24 March 2014

京都大学 / 0048 / 新制・課程博士 / 博士(理学) / 甲第18062号 / 理博第3940号 / 新制||理||1568(附属図書館) / 30920 / 京都大学大学院理学研究科物理学・宇宙物理学専攻 / (主査)教授 川上 則雄, 教授 石田 憲二, 准教授 藤本 聡 / 学位規則第4条第1項該当 / Doctor of Science / Kyoto University / DGAM

strongly correlated systems

topological insulators

dynamical mean field theory

density matrix renormalization group

400

Emergent phenomena in strongly correlated electron systems: Auxiliary particle approach to the many-body problem / Emergente Phänomene in stark korrelierten Elektronensystemen: Hilfsteilchenansatz für das Vielteilchenproblem

Riegler, David

January 2022

Emergent phenomena in condensed matter physics like, e.g., magnetism, superconductivity, or non-trivial topology often come along with a surprise and exert great fascination to researchers up to this day. Within this thesis, we are concerned with the analysis of associated types of order that arise due to strong electronic interactions and focus on the high-\(T_c\) cuprates and Kondo systems as two prime candidates. The underlying many-body problem cannot be solved analytically and has given rise to the development of various approximation techniques to tackle the problem. In concrete terms, we apply the auxiliary particle approach to investigate tight-binding Hamiltonians subject to a Hubbard interaction term to account for the screened Coulomb repulsion. Thereby, we adopt the so-called Kotliar-Ruckenstein slave-boson representation that reduces the problem to non-interacting quasiparticles within a mean-field approximation. Part I provides a pedagogical review of the theory and generalizes the established formalism to encompass Gaussian fluctuations around magnetic ground states as a crucial step to obtaining novel results. Part II addresses the two-dimensional one-band Hubbard model, which is known to approximately describe the physics of the high-\(T_c\) cuprates that feature high-temperature superconductivity and various other exotic quantum phases that are not yet fully understood. First, we provide a comprehensive slave-boson analysis of the model, including the discussion of incommensurate magnetic phases, collective modes, and a comparison to other theoretical methods that shows that our results can be massively improved through the newly implemented fluctuation corrections. Afterward, we focus on the underdoped regime and find an intertwining of spin and charge order signaled by divergences of the static charge susceptibility within the antiferromagnetic domain. There is experimental evidence for such inhomogeneous phases in various cuprate materials, which has recently aroused interest because such correlations are believed to impact the formation of Cooper pairs. Our analysis identifies two distinct charge-ordering vectors, one of which can be attributed to a Fermi-surface nesting effect and quantitatively fits experimental data in \(\mathrm{Nd}_{2-\mathrm{x}}\mathrm{Ce}_\mathrm{x}\mathrm{CuO}_4\) (NCCO), an electron-doped cuprate compound. The other resembles the so-called Yamada relation implying the formation of periodic, double-occupied domain walls with a crossover to phase separation for small dopings. Part III investigates Kondo systems by analyzing the periodic Anderson model and its generalizations. First, we consider Kondo metals and detect weakly magnetized ferromagnetic order in qualitative agreement with experimental observations, which hinders the formation of heavy fermions. Nevertheless, we suggest two different parameter regimes that could host a possible Kondo regime in the context of one or two conduction bands. The part is concluded with the study of topological order in Kondo insulators based on a three-dimensional model with centrosymmetric spin-orbit coupling. Thereby, we classify topologically distinct phases through appropriate \(\mathbb{Z}_2\) invariants and consider paramagnetic and antiferromagnetic mean-field ground states. Our model parameters are chosen to specifically describe samarium hexaboride (\(\mbox{SmB}_6\)), which is widely believed to be a topological Kondo insulator, and we identify topologically protected surface states in agreement with experimental evidence in that material. Moreover, our theory predicts the emergence of an antiferromagnetic topological insulator featuring one-dimensional hinge-states as the signature of higher-order topology in the strong coupling regime. While the nature of the true ground state is still under debate, corresponding long-range magnetic order has been observed in pressurized or alloyed \(\mbox{SmB}_6\), and recent experimental findings point towards non-trivial topology under these circumstances. The ability to understand and control topological systems brings forth promising applications in the context of spintronics and quantum computing. / Emergente Phänomene in der Physik der kondensierten Materie, wie z. B. Magnetismus, Supraleitung oder nicht-triviale Topologie gehen oft mit Überraschungen einher und faszinieren Wissenschaftler bis heute. Innerhalb dieser Arbeit befassen wir uns mit der Analyse damit assoziierter Art von Ordnung, die durch starke elektronische Wechselwirkungen entsteht und konzentrieren uns auf die Kuprat-Hochtemperatursupraleiter und Kondo-Systeme als zwei prominente Kandidaten. Das zugrunde liegende Vielteilchenproblem kann nicht analytisch gelöst werden und hat zur Entwicklung vielfältiger Näherungsverfahren geführt, um das Problem anzugehen. Konkret wenden wir den Hilfsteilchenansatz an, um tight-binding Hamiltonoperatoren zu untersuchen, die einen Hubbard-Wechselwirkungsterm aufweisen, um die abgeschirmte Coulomb-Abstoßung zu berücksichtigen. Dabei benutzen wir die sogenannte Kotliar-Ruckenstein-Slave-Boson-Darstellung, die das Problem im Rahmen einer Molekularfeldnäherung auf nicht-wechselwirkende Quasiteilchen zurückführt. Teil I beinhaltet eine pädagogisch aufgearbeitete Zusammenfassung der Theorie und verallgemeinert durch die Berücksichtigung Gaußscher Fluktuationen um magnetische Grundzustände den etablierten Formalismus, was sich als entscheidender Schritt herausstellt, um neuartige Ergebnisse erzielen zu können. Teil II befasst sich mit dem zweidimensionalen Einband-Hubbard-Modell, von dem bekannt ist, dass es näherungsweise die Physik der Kuprat-Hochtemperatursupraleiter beschreibt, welche Hochtemperatursupraleitung und verschiedene andere exotische Quantenphasen aufweisen, die noch nicht vollständig verstanden sind. Zunächst machen wir eine ausführliche Slave-Boson-Analyse des Modells, einschließlich der Diskussion inkommensurabler magnetischer Phasen, kollektiver Moden und eines Vergleichs mit anderen theoretischen Methoden, der zeigt, dass unsere Ergebnisse durch die neu implementierten Fluktuationskorrekturen massiv verbessert werden können. Danach konzentrieren wir uns auf den unterdotierten Bereich und finden eine Verflechtung von Spin- und Ladungsordnung, die durch Divergenzen der statischen Ladungssuszeptibilität innerhalb der antiferromagnetischen Domäne signalisiert wird. Es gibt experimentelle Hinweise auf derartige inhomogene Phasen in verschiedenen Kuprat-Materialien, was in letzter Zeit vermehrt Interesse geweckt hat, da angenommen wird, dass entsprechende Korrelationen die Bildung von Cooper-Paaren beeinflussen. Unsere Analyse identifiziert zwei unterschiedliche Ladungsordnungsvektoren, von denen einer einem Fermi-Flächeneffekt zugeschrieben werden kann und quantitativ zu experimentellen Daten von \(\mathrm{Nd}_{2-\mathrm{x}}\mathrm{Ce}_\mathrm{x}\mathrm{CuO}_4\) (NCCO), einer elektronendotierten Kupratverbindung, passt. Der andere erinnert an die sogenannte Yamada-Beziehung und impliziert die Bildung von periodischen, doppelt besetzten Domänenwänden und einem Übergang zu Phasenseperation für kleine Dotierungen. Teil III untersucht Kondo-Systeme durch Analyse des periodischen Anderson-Modells und seiner Verallgemeinerungen. Zunächst betrachten wir Kondo-Metalle und finden schwach magnetisierte ferromagnetische Ordnung in qualitativer Übereinstimmung mit experimentellen Beobachtungen, welche die Bildung von schweren Fermionen hemmt. Dennoch identifizieren wir zwei verschiedene Parameterbereiche, die ein mögliches Kondo-Regime im Kontext von einem oder zwei Leitungsbändern beherbergen könnten. Der Teil wird mit der Untersuchung topologischer Ordnung in Kondo-Isolatoren basierend auf einem dreidimensionalen Modell mit zentrosymmetrischer Spin-Bahn-Kopplung abgeschlossen. Dabei klassifizieren wir topologisch unterscheidbare Phasen durch geeignete \(\mathbb{Z}_2\)-Invarianten und betrachten paramagnetische und antiferromagnetische Molekularfeld-Grundzustände. Unsere Modellparameter wurden gewählt, um insbesondere Samariumhexaborid (\(\mbox{SmB}_6\)) zu beschreiben, von dem allgemein angenommen wird, dass es sich um einen topologischen Kondo-Isolator handelt, und wir identifizieren topologisch geschützte Oberflächenzustände in Übereinstimmung mit experimentellen Befunden in diesem Material. Darüber hinaus sagt unsere Theorie die Emergenz eines antiferromagnetischen topologischen Isolators mit eindimensionalen Randzuständen als Merkmal von Topologie höherer Ordnung im Parameterbereich starker Korrelationen voraus. Während das Wesen des korrekten Grundzustands noch umstritten ist, wurde eine entsprechende langreichweitige magnetische Ordnung in unter Druck stehendem oder legiertem \(\mbox{SmB}_6\) beobachtet und kürzliche experimentelle Befunde weisen unter diesen Umständen auf nicht-triviale Topologie hin. Die Fähigkeit, topologische Systeme zu verstehen und zu kontrollieren, bringt vielversprechende Anwendungen im Kontext von Spintronik und Quantencomputing hervor.

Elektronenkorrelation

Mean-Field-Theorie

Hochtemperatursupraleiter

Kondo-System

Topologischer Isolator

ddc:539

Density-Functional Theory+Dynamical Mean-Field Theory Study of the Magnetic Properties of Transition-Metal Nanostructures

Kabir, Alamgir

01 January 2015

In this thesis, Density Functional Theory (DFT) and Dynamical Mean-Field Theory (DMFT) approaches are applied to study the magnetic properties of transition metal nanosystems of different sizes and compositions. In particular, in order to take into account dynamical electron correlation effects (time-resolved local charge interactions), we have adopted the DFT+DMFT formalism and made it suitable for application to nanostructures. Preliminary application of this DFT+DMFT approach, using available codes, to study the magnetic properties of small (2 to 5-atom) Fe and FePt clusters provide meaningful results: dynamical effects lead to a reduction of the cluster magnetic moment as compared to that obtained from DFT or DFT+U (U being the Coulomb repulsion parameter). We have subsequently developed our own nanoDFT+DMFT code and applied it to examine the magnetization of iron particles containing10-147 atoms. Our results for the cluster magnetic moments are in a good agreement with experimental data. In particular, we are able to reproduce the oscillations in magnetic moment with size as observed in the experiments. Also, DFT+DMFT does not lead to an overestimation of magnetization for the clusters in the size range of 10-27 atoms found with DFT and DFT+U. On application of the nanoDFT+DMFT approach to systems with mixed geometry – Fe2O3 film, which are periodic (infinitely extended), in two directions, and finite in the third. Similar to DFT+U, we find that the surface atom magnetic moments are smaller compared to the bulk. However, the absolute values of the surface atoms magnetic moments are smaller in DFT+DMFT. In parallel, we have carried out a systematic study of magnetic anisotropy in bimetallic L10 FePt nanoparticles (20-484 atoms) by using two DFT-based approaches: direct and the torque method. We find that the magnetocrystalline anisotropy (MCA) of FePt clusters is larger than that of the pure Fe and Pt ones. We explain this effect by a large hybridization of 3d Fe- and 5d Pt-atom orbitals, which lead to enhancement of the magnetic moment of the Pt atom, and hence to a larger magnetic anisotropy because of large spin-orbit coupling of Pt atoms. In addition, we find that particles whose (large) central layer consists of Pt atoms, rather than Fe, have larger MCA due to stronger hybridization effects. Such 'protected' MCA, which does not require protective cladding, can be used in modern magnetic technologies.

Nanoparticle

density functional theory(dft)

dynamical mean field theory (dmft)

magnetic anisotropy

Physics

Modeling the Relaxation Dynamics of Fluids in Nanoporous Materials

Edison, John R.

01 September 2012

Mesoporous materials are being widely used in the chemical industry in various environmentally friendly separation processes and as catalysts. Our research can be broadly described as an effort to understand the behavior of fluids confined in such materials. More specifically we try to understand the influence of state variables like temperature and pore variables like size, shape, connectivity and structural heterogeneity on both the dynamic and equilibrium behavior of confined fluids. The dynamic processes associated with the approach to equilibrium are largely unexplored. It is important to look into the dynamic behavior for two reasons. First, confined fluids experience enhanced metastabilities and large equilibration times in certain classes of mesoporous materials, and the approach to the metastable/stable equilibrium is of tremendous interest. Secondly, understanding the transport resistances in a microscopic scale will help better engineer heterogeneous catalysts and separation processes. Here we present some of our preliminary studies on dynamics of fluids in ideal pore geometries. The tool that we have used extensively to investigate the relaxation dynamics of fluids in pores is the dynamic mean field theory (DMFT) as developed by Monson[P. A. Monson, J. Chem. Phys., 128, 084701 (2008) ]. The theory is based on a lattice gas model of the system and can be viewed as a highly computationally efficient approximation to the dynamics averaged over an ensemble of Kawasaki dynamics Monte Carlo trajectories of the system. It provides a theory of the dynamics of the system consistent with the thermodynamics in mean field theory. The nucleation mechanisms associated with confined fluid phase transitions are emergent features in the calculations. We begin by describing the details of the theory and then present several applications of DMFT. First we present applications to three model pore networks (a) a network of slit pores with a single pore width; (b) a network of slit pores with two pore widths arranged in intersecting channels with a single pore width in each channel; (c) a network of slit pores with two pore widths forming an array of ink-bottles. The results illustrate the effects of pore connectivity upon the dynamics of vapor liquid phase transformations as well as on the mass transfer resistances to equilibration. We then present an application to a case where the solid-fluid interactions lead to partial wetting on a planar surface. The pore filling process in such systems features an asymmetric density distribution where a liquid droplet appears on one of the walls. We also present studies on systems where there is partial drying or drying associated with weakly attractive or repulsive interactions between the fluid and the pore walls. We describe the symmetries exhibited by the lattice model between pore filling for wetting states and pore emptying for drying states, for both the thermodynamics and dynamics. We then present an extension of DMFT to mixtures and present some examples that illustrate the utility of the approach. Finally we present an assessment the accuracy of the DMFT through comparisons with a higher order approximation based on the path probability method as well as Kawasaki dynamics.

dynamic mean field theory

mesoporous materials

nucleation mechanisms

relaxation dynamics of confined fluids

Chemical Engineering

Mean Field Games price formation models

Gutierrez, Julian

06 September 2023

This thesis studies mean-field games (MFGs) models of price formation. The thesis focuses explicitly on a MFGs price formation model proposed by Gomes and Saude. The thesis is divided into two parts. The first part examines the deterministic supply case, while the second part extends the model to incorporate a stochastic supply function. We explore different approaches, such as Aubry-Mather theory, to study the properties of the MFGs price formation model and alternative formulations using a convex variational problem with constraints. We propose machine-learning-based numerical methods to approximate the solution of the MFGs price formation model in the deterministic and stochastic setting.

Mean field games

Price formation

Lagrange multiplier

Neural networks

common noise

equilibrium pricing