Vine codes generalize directional codes to open planar boundaries, delivering up to 28% fewer data/measure qubits at circuit distance 7 and better simulated performance than the surface code at 10^{-3} noise while using fewer total qubits.
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Dolanet al., Phys
Canonical reference. 77% of citing Pith papers cite this work as background.
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representative citing papers
The RDM of 2D topological order at an entanglement cut realizes a 1D Z2 SW-SSB mixed-state phase whose correlations and disorder parameters encode anyon deconfinement and spinon fractionalization.
Classical codes plus SAT search yield no-go theorems limiting error detection in sub-8-qubit distillation and new minimal-qubit protocols for T-to-T (distances 4-5 on 10-11 qubits) and T-to-CCZ (distances 3-4 on 9-10 qubits).
In disordered 1D quantum spin ensembles with Ising symmetry, gapped phases exhibit a strict trade-off: they have either long-range Edwards-Anderson order or even-parity disorder, but not both.
Quantum coherences bind to hydrodynamic voids forming polaron-like objects, parametrically enhancing lifetimes and producing subdiffusive Green's functions in charge-conserving dynamics.
For PEPS with strong injectivity above a threshold, belief propagation finds fixed points efficiently and cluster-corrected BP approximates observables to 1/poly(N) error in poly(N) time, with local perturbations affecting the fixed point only locally.
Cryogenic shock exfoliation yields large rhombohedral graphene devices over 1300 square micrometers with 90% fabrication yield, mean free path exceeding 200 micrometers, and signatures of electron hydrodynamics.
Alterelectrics exhibit quadrupolar piezoelectricity, hyperbolic wave dispersion, and surface-dependent anisotropic electronic transport as an electric analog to altermagnets.
Genuine quantum scars survive in Floquet many-body systems with additional drive-induced scars and a stability diagram explained by classical Lyapunov exponents.
For PEPS states with loop-decay, BP with cluster corrections approximates local observables exponentially accurately, and loop-decay necessarily implies exponential decay of connected correlations, ruling out BP at critical points.
Engineered disorder drives a photonic lattice into a topological Anderson insulator regime that produces emergent chiral edge states for boundary-selective, ultranarrow lasing with enhanced robustness.
Shaping the pump in a honeycomb photonic-crystal laser creates a smooth potential that traps lasing states with reconfigurable real-space polarization singularities pinned to envelope critical points, while the momentum-space vortex at Gamma remains fixed.
Averaging symmetric Z_N quantum circuits over random noise produces a noisy surface code whose logical information is protected against symmetric errors up to a threshold, with charge-sharpening transitions coinciding with bulk confinement transitions that differ for N≤4 versus N>4.
Symmetry classification of measurement-inclusive fermionic dynamics with equivalence between many-body and single-particle schemes, plus post-selection-free adaptive circuits for topological states in four classes.
A sample-optimal quantum state tomography algorithm that is memory-efficient by using unitary Schur sampling with streaming access to samples.
Derivation of spin-current high-harmonic selection rules that distinguish altermagnetic spin-group phases from ferromagnetic, antiferromagnetic, and magnetic-point-group mimics under different light polarizations in the weak-SOC regime.
Numerical simulations of plane gravitational waves through Gaussian, NFW and Burkert potentials show non-geodesic propagation for Gaussian profiles and wave convexity reversal for Burkert in strong gravity, with order-one deviations from scalar-wave predictions inside the lens.
QTT-NEGF simulations on up to 256x256 lattices reveal momentum-dependent thermalization bottlenecks extending the phonon-window effect in nonequilibrium electron-phonon systems.
Thousands of foundry-fabricated quantum-dot spin-photon interfaces demonstrate state-of-the-art efficiency, stable near-unity purity, seven-partite entanglement, and cross-source indistinguishability.
Derives improved mode-independent sample complexity bounds O(η log η) for fermionic classical shadows on particle-preserving operators and Slater determinant overlaps.
Experimental observation of nonlinear dependence of ion loss rate on spin polarization in Ba+ immersed in two-component Li Fermi gas, consistent with antisymmetrization restricting recombination channels.
Proposes relative-entropy-based measures to diagnose chirality in mixed-state topological phases after showing pure-state diagnostics are unreliable.
Broadband laser pulses enhance two-plasmon decay instability and hot electron generation via stochastic intensity spikes, as identified in experiments and particle-in-cell simulations.
Analytical derivation shows mutual relations between density, magnetic, and pairing susceptibilities in the Hubbard model, revealing a degeneracy between d-wave pairing and d-density wave instabilities near the metal-insulator transition that is lifted by frustration.
citing papers explorer
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Dissipation-assisted preparation of Floquet-Laughlin states in superconducting circuits
Driven-dissipative stabilization of Floquet-Laughlin states in the bosonic Harper-Hofstadter-Hubbard model is achieved by coupling to tuneable artificial environments realized with leaky cavity modes.
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Exact solution and pair correlation functions for a generalized three-chain Ising tube with multispin interactions
Exact transfer-matrix solution for a C3-symmetric three-chain Ising tube with general multispin interactions, giving free energy, specific heat, magnetization, and pair correlations in the thermodynamic limit.
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Few-Attosecond electron pulse trains with tunable periods produced by two counter-propagating lasers
Two counter-propagating lasers enable stable ~1 as electron pulse trains with gamma up to 15 and extended focal length through a previously unidentified parametric resonance condition.
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Nonlinear Hamiltonians and Boolean satisfiability
Nonlinear Hamiltonians on ancilla qubits enable efficient solution of UNIQUE SAT with ⟨σ^z⟩σ^z, 3SAT with ⟨σ^x⟩σ^y - ⟨σ^y⟩σ^x, and #SAT with ⟨σ^y⟩⟨σ^z⟩σ^x - ⟨σ^x⟩⟨σ^z⟩σ^y nonlinearity.
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Laboratory rivers extremize friction and are cosmological analogues
River cross-sectional profiles satisfy the Friedmann equation for an Anti-de Sitter universe; the associated action extremizes friction and dissipation, and the extremum is a maximum by second variation analysis.
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$\Lambda$-enhanced gray-molasses loading and EIT cooling of neutral atoms in nanophotonic traps
Lambda-enhanced gray-molasses loading yields a six-fold increase in trapped cesium atoms and EIT cooling extends storage time five-fold in nanophotonic nanofiber traps.
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Measuring cosmic bulk flow with kinetic Sunyaev-Zel'dovich velocity reconstruction
Kinetic Sunyaev-Zel'dovich reconstruction from WISExSuperCOSMOS and unWISE galaxies with Planck data yields tight upper limits on bulk velocities consistent with LambdaCDM out to 2000 h^{-1} Mpc while showing tension with a quasar dipole interpretation.
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Cell divisions suppress dynamical correlations in solid tissues
Cell divisions fluidize tissues below yield stress but suppress system-spanning avalanches, preserving marginal stability via finite energy budget from divisions.
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Classification of Chimera States via Fourier Analysis and Unsupervised Learning
Fourier feature extraction combined with unsupervised clustering on total variations of amplitude, phase, and frequency classifies chimera state types in Rayleigh oscillator networks.
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Lattice Quantization of Free Fermions without Doublers
A lattice quantization of free fermions eliminates doublers in any dimension for m=0 by combining second-order equations with non-Hermitian tools and a new pseudo-Hermitian symmetry.
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The Good, the Bad, and the Subtle: Relativistic mode sums for neutron-star tidal response
A practical relativistic mode-sum method for neutron-star tidal response is implemented, with robust f-mode agreement to direct matching but acknowledged limitations in convergence and tidal field uniqueness.
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Systematic Extraction of Exact Yang-Mills Solutions via Algebraic Tensor Ring Decomposition
An algebraic tensor ring decomposition converts Yang-Mills nonlinearities into tractable differential-algebraic ideals whose bifurcation analysis produces exact solutions including mass-gapped color waves, screened dyonic tubes, and chaotic SU(3) phases.
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Testing General Relativity with Individual Supermassive Black Hole Binaries
A framework is developed to test beyond-GR effects in nanohertz continuous waves from individual SMBHBs, deriving modified inter-pulsar correlations, antenna responses, and phase delays for three deviation classes, validated by injection-recovery simulations showing parameter recovery and no GR bias
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Quantum Magic in early FTQC: From Diagonal Clifford Hierarchy No-Go Theorems to Architecture Design Blueprints
No-go theorems prove hierarchy level and state-independent sequences cannot maximize operational magic in early FTQC, requiring state-aware differentiable optimization and nonlinear phases for scalable magic generation.
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Factoring $2048$ bit RSA integers with a half-million-qubit modular atomic processor
A modular atomic processor with 500,000 qubits factors 2048-bit RSA numbers in roughly the same time as a single large module when inter-module Bell-pair communication runs at 10^5 per second.
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Minimum lifetime of a black hole
A minimum purification time for evaporating black holes is derived as scaling with M0^4/hbar^{3/2}, becoming exponential in initial area under a metastability assumption for Planck-scale holes, implying white-hole remnants.
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Experimental demonstration of a coherent detector blinding attack on a real CV-QKD system
Experimental coherent detector blinding attack on a real CV-QKD system reliably hides excess noise above 2.5 SNU by impairing the receiver's channel parameter estimation.
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Quantum Tilted Loss in Variational Optimization: Theory and Applications
QTL unifies expectation-value minimization with CVaR and Gibbs heuristics under one tunable operator, amplifying gradients in structured cases while preserving global minima and shifting the bottleneck to measurement variance.
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Development of a quadripartite wakefield structure as dechirper for free electron laser
A four-plate symmetric corrugated structure suppresses quadrupole wakefields in FEL dechirpers, yielding lower projected emittance growth and 25% shorter length than planar designs per simulations.
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Entropy transport through a superfluid quantum point contact: A Keldysh field-theory approach
Entropy transport through a superfluid quantum point contact exhibits an oscillatory behavior at low voltage in the ballistic limit according to Keldysh calculations in the BCS regime.
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Scalar emission from binary neutron stars in scalar-tensor theories with kinetic screening
Kinetic screening non-monotonically suppresses or enhances scalar quadrupolar emission from equal-mass neutron star binaries depending on screening radius versus wavelength, with a dipole re-emerging linearly with mass asymmetry.
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Merger remnant and eccentricity dynamics surrogates for eccentric nonspinning black hole binaries
Two new surrogate models, trained on NR simulations, predict remnant properties and eccentricity dynamics for nonspinning eccentric black hole binaries with q ≤ 4 and e < 0.23.
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Locality versus Fock-space structure in East-type models
Randomizing Fock-space connections in the quantum East model preserves the localization transition, showing that Fock-space graph structure matters more than geometric locality.
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On the proposed concept of mechanical phasons in Ni-Mn-Ga modulated martensite
A simple mechanical model shows that modulation phasons in Ni-Mn-Ga 10M martensite relax shear loadings for commensurate and weakly incommensurate modulations but not for strongly incommensurate ones, explaining anomalous elastic behavior and related lattice properties.
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On the Quantisation of Linear Gauge Theories on Lorentzian Manifolds: Maxwell's Theory via Complete Gauge Fixing
A new complete gauge fixing at initial data via Hodge decomposition on complete Riemannian manifolds enables existence proofs for Hadamard states in the quantization of Maxwell theory on globally hyperbolic Lorentzian manifolds.
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Minimal action shortcut to adiabaticity in a driven Kitaev chain: competing gaps in a topological transition at finite-time
A multi-step MA-STA control achieves high-fidelity driving of the Kitaev chain across its trivial-to-topological transition at times much shorter than linear protocols while reducing work fluctuations.
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Universal transport of active colloids with sensory delay in motility landscapes
Mapping spatial motility variations to stochastic switching allows analytical prediction of diffusion and density patterns for delayed active colloids, matching experiments across scales.
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Flat band in multiband-metal MnSb$_2$
MnSb2 has been synthesized under high pressure and shows transport signatures of a flat band near the Fermi level consistent with DFT band structure.
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Spectral tuning of single T centres by the Stark effect
Stark tuning of T centres in silicon nanophotonic cavities with p-i-n diodes achieves 30 GHz shifts, resonance for 55% of on-chip emitters, tunable lifetime reduction, and a model predicting large entanglement-rate gains.
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Identifying strong correlation using only the Kohn-Sham density of one-electron states
Symmetry breaking in Kohn-Sham DFT reduces the Fermi-level density of states in strongly correlated metals, and the new parameter Gamma identifies strong correlation using only the KS one-electron density of states.
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A general formalism for coupling scalar fields to the Einstein equations without a variational principle
A non-variational method for coupling scalar fields to gravity reproduces known models and produces asymptotically Kasner Bianchi I solutions under specific conditions.
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Enhanced Atom Capture via Multi-Frequency Magneto-Optical Trapping
Multi-frequency cooling in a 87Rb MOT doubles steady-state atom number to 10^10 and boosts loading rate to 1.3x10^11 atoms/s, with simulations predicting larger gains for bigger traps.
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Four-dimensional QCD equation of state from a quasi-parton model with physics-informed neural networks
A PINN-trained quasi-parton model reproduces lattice cumulants at vanishing chemical potentials and supplies a consistent four-dimensional QCD equation of state at finite densities.
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Autonomous Emergence of Hamiltonian in Deep Generative Models
A symmetry-equivariant generative model trained on thermal snapshots of a 1D O(3) spin glass recovers the microscopic Hamiltonian parameters with 99.7% cosine similarity to ground truth through linear inversion of its learned score field.
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Tensor network surrogate models for variational quantum computation
Tensor network simulations act as effective surrogate models for training QAOA on large 2D lattices, overcoming limits of parameter transfer from small instances and remaining classically feasible with moderate bond dimensions.
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Fundamental Cosmic Anisotropy and its Ramifications II: Perturbations in Bianchi spacetimes, and fixed in the Newtonian gauge
Derives perturbation equations for Bianchi spacetimes in Newtonian gauge and computes density contrasts for EdS and Bianchi I models.
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Toward designing workload-aware Surface Code Architectures
A workload-aware surface-code architecture with ancilla-centric patches and T-gate-based floorplanning reduces required data tiles by up to 21% while maintaining near-optimal cycles per instruction and reaching 90% efficiency for 10 concurrent programs.
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Fault-Tolerant Quantum Computing with Trapped Ions: The Walking Cat Architecture
A trapped-ion architecture based on LDPC codes and cat-state factories achieves 110 logical qubits and one million T gates per day using 2514 physical qubits, with estimates for Heisenberg model simulation on 100 sites in one month using 10000 qubits.
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Stabilization of bulk quantum orders in finite Rydberg atom arrays
A protocol leverages the disordered phase to set unbiased boundary configurations in finite Rydberg arrays, stabilizing bulk-like quantum order in 1D and 2D simulations.
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Quantum many-body scars in random unitary circuits
A constructed random unitary circuit hosts one scar whose perturbations thermalize via fluctuating interfaces while the scar imprints a non-local transition in entanglement dynamics.
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Parameter Estimation of the Gravitational-Wave Angular Power Spectrum in the Dirty-Map Space
A dirty-map space inference method allows recovery of SGWB angular power spectrum parameters from LIGO O3 simulations for strong signals in auto- and cross-correlation searches up to ℓ_max=10.
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All-photonic quantum key distribution beyond the single-repeater bound
All-photonic MDI-QKD protocol surpasses the single-repeater bound with key-rate scaling approaching η^{2/5} when quantum signals travel at two-thirds classical speed, using temporal multiplexing to improve rates without perfect memories.
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When does a control system compute? Digital, mechanical and open-loop systems
All control systems perform computation according to ART, including purely mechanical ones like the centrifugal governor, which therefore cannot serve as a counter-example in cognitive computationalism.
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Status of the hadronic light-by-light contribution to the muon $g-2$ and holographic QCD predictions
Holographic QCD predicts a sizable positive tensor-meson contribution to the hadronic light-by-light part of muon g-2 that matches singly virtual data, differs from quark-model ansatzes, and may reconcile lattice and data-driven results.
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Activating entanglement and EPR steering from continuous-variable resources using witness-based measures
A witness-based framework quantifies continuous-variable resources and activates them into discrete-variable entanglement or EPR steering via measure-and-prepare channels that produce Werner states.
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Precursors of extreme events and critical transitions
In fast-slow nonlinear systems a cascade of regimes marked by changes in fast CLVs and eigenvalues precedes extreme events, enabling two precursors that predict them with 100% precision and recall in numerical tests.
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Statistical Signatures of Majorana Zero Modes in Disordered Topological Superconductor Antidot Vortices
In disordered topological superconductor antidot vortices, Majorana zero mode probability density variance is twice that of CdGM states because MZM wave functions are real while CdGM ones are complex.
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An Information-Theoretic Bound on Thermodynamic Efficiency and the Generalized Carnot's Theorem
A new bound based on state-Hamiltonian correlations gives the exact maximum efficiency for multi-bath thermal engines and is achievable beyond the quasistatic regime in a quantum dot model.
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Role of Asymmetry in the Performance Optimization of a Relativistic Quantum Otto Engine
Asymmetry in the adiabatic processes of a relativistic quantum Otto cycle allows efficiency to approach unity under sudden compression but restricts it to one-half under sudden expansion, with increasing oscillator velocity enhancing work output and expanding the engine regime.
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Quantum to classical relaxation dynamics of the dissipative Rydberg gas
Using the truncated Wigner approximation on large 1D and 2D systems, the authors find a pronounced slowdown in magnetization relaxation and transient signatures of quantum kinetically constrained dynamics starting from polarized and Néel states.