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1. Nuclear magnetic resonance studies in a model transverse field Ising system

   https://doi.org/10.3389/fphy.2024.1393229  

   Nian, Y-H; Vinograd, I; Chaffey, C; Li, Y; Zic, M P; Massat, P; Singh, R_R P; Fisher, I R; Curro, N J (June 2024, Frontiers in Physics)

   The suppression of ferroquadrupolar order in TmVO₄in a magnetic field is well-described by the transverse field Ising model, enabling detailed studies of critical dynamics near the quantum phase transition. We describe nuclear magnetic resonance measurements in pure and Y-doped single crystals. The non-Kramers nature of the ground state doublet leads to a unique form of the hyperfine coupling that exclusively probes the transverse field susceptibility. Our results show that this quantity diverges at the critical field, in contrast to the mean-field prediction. Furthermore, we find evidence for quantum critical fluctuations present near Tm-rich regions in Y-doped crystals at levels beyond which long-range order is suppressed, suggesting the presence of quantum Griffiths phases. 

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2. Measurement induced criticality in quasiperiodic modulated random hybrid circuits

   https://doi.org/10.1103/PhysRevB.108.184204  

   Shkolnik, Gal; Zabalo, Aidan; Vasseur, Romain; Huse, David A.; Pixley, J. H.; Gazit, Snir (November 2023, Physical Review B)

   We study one-dimensional hybrid quantum circuits perturbed by quenched quasiperiodic (QP) modulations across the measurement-induced phase transition (MIPT). Considering non-Pisot QP structures, characterized by unbounded fluctuations, allows us to tune the wandering exponent β to exceed the Luck bound ν ≥ 1/(1−β) for the stability of the MIPT, where ν = 1.28(2). Via robust numerical simulations of random Clifford circuits interleaved with local projective measurements, we find that sufficiently large QP structural fluctuations destabilize the MIPT and induce a flow to a broad family of critical dynamical phase transitions of the infinite QP type that is governed by the wandering exponent β. We numerically determine the associated critical properties, including the correlation length exponent consistent with saturating the Luck bound, and a universal activated dynamical scaling with activation exponent ψ ≅ β, finding excellent agreement with the conclusions of real-space renormalization group calculations. 

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3. A nonlinear journey from structural phase transitions to quantum annealing

   Thudiyangal, M; Kevrekidis, PG; Saxena, A; Bishop, AR (May 2024, Chaos)

   Motivated by an exact mapping between equilibrium properties of a one-dimensional chain of quantum Ising spins in a transverse field (the transverse field Ising (TFI) model) and a two-dimensional classical array of particles in double-well potentials (the “ 4 model”) with weak inter-chain coupling, we explore connections between the driven variants of the two systems. We argue that coupling between the fundamen- tal topological solitary waves in the form of kinks between neighboring chains in the classical  4 system is the analog of the competing effect of the transverse field on spin flips in the quantum TFI model. As an example application, we mimic simplified measurement protocols in a closed quantum model system by studying the classical  phi 4 model subjected to periodic perturbations. This reveals memory/loss of mem- ory and coherence/decoherence regimes, whose quantum analogs are essential in annealing phenomena. In particular, we examine regimes where the topological excitations control the thermal equilibration following perturbations. This paves the way for further explorations of the analogy between lower-dimensional linear quantum and higher-dimensional classical nonlinear systems. 

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4. Excitations of quantum Ising chain CoNb2O6 in low transverse field: Quantitative description of bound states stabilized by off-diagonal exchange and applied field

   https://doi.org/10.1103/PhysRevB.108.184417  

   Woodland, Leonie; Lovas, Izabella; Telling, M; Prabhakaran, D; Balents, Leon; Coldea, Radu (November 2023, Physical Review B)

   We present experimental and theoretical evidence of novel bound state formation in the low transverse field or- dered phase of the quasi-one-dimensional Ising-like material CoNb2O6. High-resolution single-crystal inelastic neutron scattering measurements observe that small transverse fields lead to a breakup of the spectrum into three parts, each evolving very differently upon increasing field. This can be naturally understood starting from the excitations of the ordered phase of the transverse field Ising model, domain wall quasiparticles (solitons). Here, the transverse field and a staggered off-diagonal exchange create one-soliton hopping terms with opposite signs. We show that this leads to a rich spectrum and a special field, when the strengths of the off-diagonal exchange and transverse field match, at which solitons become localized; the highest field investigated is very close to this special regime. We solve this case analytically and find three two-soliton continua, along with three novel bound states. Perturbing away from this novel localized limit, we find very good qualitative agreement with the experimental data. We also present calculations using exact diagonalization of a recently refined Hamiltonian model for CoNb2O6 and using diagonalization of the two-soliton subspace, both of which provide a quantitative agreement with the observed spectrum. The theoretical models qualitatively and quantitatively capture a variety of nontrivial features in the observed spectrum, providing insight into the underlying physics of bound state formation. 

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5. Scattering in the Ising model with the quantum Lanczos algorithm ^*

   https://doi.org/10.1088/1367-2630/abe63d  

   Yeter-Aydeniz, Kübra; Siopsis, George; Pooser, Raphael C (April 2021, New Journal of Physics)

   Abstract Time evolution and scattering simulation in phenomenological models are of great interest for testing and validating the potential for near-term quantum computers to simulate quantum field theories. Here, we simulate one-particle propagation and two-particle scattering in the one-dimensional transverse Ising model for 3 and 4 spatial sites with periodic boundary conditions on a quantum computer. We use the quantum Lanczos algorithm to obtain all energy levels and corresponding eigenstates of the system. We simplify the quantum computation by taking advantage of the symmetries of the system. These results enable us to compute one- and two-particle transition amplitudes, particle numbers for spatial sites, and the transverse magnetization as functions of time. The quantum circuits were executed on various IBM Q superconducting hardware. The experimental results are in very good agreement with the values obtained using exact diagonalization. 

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