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1. Subharmonic spin correlations and spectral pairing in Floquet time crystals

   https://doi.org/10.1103/PhysRevB.111.184308  

   Penner, Alexander-Georg; Schmid, Harald; Glazman, Leonid I; von_Oppen, Felix (May 2025, Physical Review B)

   Floquet time crystals are characterized by the subharmonic behavior of temporal correlation functions. Studying the paradigmatic time crystal based on the disordered Floquet quantum Ising model, we show that its temporal spin correlations are directly related to spectral characteristics and that this relation provides analytical expressions for the correlation function of finite chains, which compare favorably with numerical simulations. Specifically, we show that the disorder-averaged temporal spin correlations are proportional to the Fourier transform of the splitting distribution of the pairs of eigenvalues of the Floquet operator, which differ by $\pi$to exponential accuracy in the chain length. We find that the splittings are well described by a log-normal distribution, implying that the temporal spin correlations are characterized by two parameters. We discuss possible implications for the phase diagram of Floquet time crystals. 

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2. Quantum‐classical path integral evaluation of reaction rates with a near‐equilibrium flux formulation

   https://doi.org/10.1002/qua.26618  

   Bose, Amartya; Makri, Nancy (February 2021, International Journal of Quantum Chemistry)

   Abstract Quantum‐classical formulations of reactive flux correlation functions require the partial Weyl–Wigner transform of the thermalized flux operator, whose numerical evaluation is unstable because of phase cancelation. In a recent paper, we introduced a non‐equilibrium formulation which eliminates the need for construction of this distribution and which gives the reaction rate along with the time evolution of the reactant population. In this work, we describe a near‐equilibrium formulation of the reactive flux, which accounts for important thermal correlations between the quantum system and its environment while avoiding the numerical instabilities of the full Weyl–Wigner transform. By minimizing early‐time transients, the near‐equilibrium formulation leads to an earlier onset of the plateau regime, allowing determination of the reaction rate from short‐time dynamics. In combination with the quantum‐classical path integral methodology, the near‐equilibrium formulation offers an accurate and efficient approach for determining reaction rate constants in condensed phase environments. The near‐equilibrium formulation may also be combined with a variety of approximate quantum‐classical propagation methods. 

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3. Proposal for many-body quantum chaos detection

   https://doi.org/10.1103/PhysRevResearch.7.013181  

   Das, Adway Kumar; Cianci, Cameron; Cabral, Delmar_G A; Zarate-Herrada, David A; Pinney, Patrick; Pilatowsky-Cameo, Saúl; Matsoukas-Roubeas, Apollonas S; Batista, Victor S; del_Campo, Adolfo; Torres-Herrera, E Jonathan; et al (February 2025, Physical Review Research)

   In this work, the term “quantum chaos” refers to spectral correlations similar to those found in the random matrix theory. Quantum chaos can be diagnosed through the analysis of level statistics using, e.g., the spectral form factor, which detects both short- and long-range level correlations. The spectral form factor corresponds to the Fourier transform of the two-point spectral correlation function and exhibits a typical slope-dip-ramp-plateau structure (aka correlation hole) when the system is chaotic. We discuss how this structure could be detected through the quench dynamics of two physical quantities accessible to experimental many-body quantum systems: the survival probability and the spin autocorrelation function. The survival probability is equivalent to the spectral form factor with an additional filter. When the system is small, the dip of the correlation hole reaches sufficiently large values at times which are short enough to be detected with current experimental platforms. As the system is pushed away from chaos, the correlation hole disappears, signaling integrability or localization. We also provide a relatively shallow circuit with which the correlation hole could be detected with commercially available quantum computers. 

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4. Bridging two quantum quench problems — local joining quantum quench and Möbius quench — and their holographic dual descriptions

   https://doi.org/10.1007/JHEP08(2024)213  

   Kudler-Flam, Jonah; Nozaki, Masahiro; Numasawa, Tokiro; Ryu, Shinsei; Tan, Mao Tian (August 2024, Journal of High Energy Physics)

   A<sc>bstract</sc> We establish an equivalence between two different quantum quench problems, the joining local quantum quench and the Möbius quench, in the context of (1 + 1)-dimensional conformal field theory (CFT). Here, in the former, two initially decoupled systems (CFTs) on finite intervals are joined att= 0. In the latter, we consider the system that is initially prepared in the ground state of the regular homogeneous Hamiltonian on a finite interval and, aftert= 0, let it time-evolve by the so-called Möbius Hamiltonian that is spatially inhomogeneous. The equivalence allows us to relate the time-dependent physical observables in one of these problems to those in the other. As an application of the equivalence, we construct a holographic dual of the Möbius quench from that of the local quantum quench. The holographic geometry involves an end-of-the-world brane whose profile exhibits non-trivial dynamics. 

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5. A quantum mechanical approach for data assimilation in climate dynamics

   Slawinska, Joanna; Ourmazd, Abbas; Giannakis, Dimitrios (January 2019, International Conference on Machine Learning Workshop on "Climate Change: How Can AI Help?")

   A framework for data assimilation in climate dynamics is presented, combining aspects of quantum mechanics, Koopman operator theory, and kernel methods for machine learning. This approach adapts the formalism of quantum dynamics and measurement to perform data assimilation (filtering), using the Koopman operator governing the evolution of observables as an analog of the Heisenberg operator in quantum mechanics, and a quantum mechanical density operator to represent the data assimilation state. The framework is implemented in a fully empirical, data-driven manner by representing the evolution and measurement operators via matrices in a basis learned from time-ordered observations. Applications to data assimilation of the Nino 3.4 index for the El Nino Southern Oscillation (ENSO) in a comprehensive climate model show promising results. 

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