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1. Quantum Dynamics of a Qubit Coupled to a Harmonic Oscillator*

   Hagimoto, Ray; Van Huele, Jean-Francois (October 2018, Bulletin of the American Physical Society)

   We investigate the quantum dynamics of the forced harmonic oscillator and Jaynes-Cummings models. We find exact solutions for the time-evolution of the Jaynes-Cummings model using Wei-Norman factorization, and describe a technique that may be used to study time-dependent interaction strengths whose evolutions may not be analytically soluble. *This project was funded by the National Science Foundation under grant #1757998. To cite this abstract, use the following reference: http://meetings.aps.org/link/BAPS.2018.TSF.G01.20 

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2. Free expansion of a Gaussian wavepacket using operator manipulations

   https://doi.org/10.1119/5.0083964  

   Orjuela, Alessandro M.; Freericks, J. K. (June 2023, American Journal of Physics)

   The free expansion of a Gaussian wavepacket is a problem commonly discussed in undergraduate quantum classes by directly solving the time-dependent Schrödinger equation as a differential equation. In this work, we provide an alternative way to calculate the free expansion by recognizing that the Gaussian wavepacket can be thought of as the ground state of a harmonic oscillator with its frequency adjusted to give the initial width of the Gaussian, and the time evolution, given by the free-particle Hamiltonian, being the same as the application of a time-dependent squeezing operator to the harmonic oscillator ground state. Operator manipulations alone (including the Hadamard lemma and the exponential disentangling identity) then allow us to directly solve the problem. As quantum instruction evolves to include more quantum information science applications, reworking this well-known problem using a squeezing formalism will help students develop intuition for how squeezed states are used in quantum sensing. 

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3. Quantum dynamics in Krylov space: Methods and applications

   https://doi.org/10.1016/j.physrep.2025.05.001  

   Nandy, Pratik; Matsoukas-Roubeas, Apollonas S; Martínez-Azcona, Pablo; Dymarsky, Anatoly; del_Campo, Adolfo (June 2025, Physics Reports)

   The dynamics of quantum systems unfolds within a subspace of the state space or operator space, known as the Krylov space. This review presents the use of Krylov subspace methods to provide an efficient description of quantum evolution and quantum chaos, with emphasis on nonequilibrium phenomena of many-body systems with a large Hilbert space. It provides a comprehensive update of recent developments, focused on the quantum evolution of operators in the Heisenberg picture as well as pure and mixed states. It further explores the notion of Krylov complexity and associated metrics as tools for quantifying operator growth, their bounds by generalized quantum speed limits, the universal operator growth hypothesis, and its relation to quantum chaos, scrambling, and generalized coherent states. A comparison of several generalizations of the Krylov construction for open quantum systems is presented. A closing discussion addresses the application of Krylov subspace methods in quantum field theory, holog- raphy, integrability, quantum control, and quantum computing, as well as current open problems. 

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4. Data assimilation in operator algebras

   https://doi.org/10.1073/pnas.2211115120  

   Freeman, David; Giannakis, Dimitrios; Mintz, Brian; Ourmazd, Abbas; Slawinska, Joanna (February 2023, Proceedings of the National Academy of Sciences)

   We develop an algebraic framework for sequential data assimilation of partially observed dynamical systems. In this framework, Bayesian data assimilation is embedded in a nonabelian operator algebra, which provides a representation of observables by multiplication operators and probability densities by density operators (quantum states). In the algebraic approach, the forecast step of data assimilation is represented by a quantum operation induced by the Koopman operator of the dynamical system. Moreover, the analysis step is described by a quantum effect, which generalizes the Bayesian observational update rule. Projecting this formulation to finite-dimensional matrix algebras leads to computational schemes that are i) automatically positivity-preserving and ii) amenable to consistent data-driven approximation using kernel methods for machine learning. Moreover, these methods are natural candidates for implementation on quantum computers. Applications to the Lorenz 96 multiscale system and the El Niño Southern Oscillation in a climate model show promising results in terms of forecast skill and uncertainty quantification. 

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5. Unveiling Operator Growth Using Spin Correlation Functions

   https://doi.org/10.3390/e23050587  

   Carrega, Matteo; Kim, Joonho; Rosa, Dario (May 2021, Entropy)

   null (Ed.)

   In this paper, we study non-equilibrium dynamics induced by a sudden quench of strongly correlated Hamiltonians with all-to-all interactions. By relying on a Sachdev-Ye-Kitaev (SYK)-based quench protocol, we show that the time evolution of simple spin-spin correlation functions is highly sensitive to the degree of k-locality of the corresponding operators, once an appropriate set of fundamental fields is identified. By tracking the time-evolution of specific spin-spin correlation functions and their decay, we argue that it is possible to distinguish between operator-hopping and operator growth dynamics; the latter being a hallmark of quantum chaos in many-body quantum systems. Such an observation, in turn, could constitute a promising tool to probe the emergence of chaotic behavior, rather accessible in state-of-the-art quench setups. 

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