Physics - Quantum Physics

New methods enhance understanding of excited states in quantum systems.

Exploring Bayesian estimation for precise temperature measurement in quantum thermometry.

This paper explores the use of LLMs for improving quantum circuit architecture.

Discover the strategies and structures behind synchronous games in mathematical problem-solving.

QCNNs blend quantum computing with neural networks for potential advancements in data processing.

A new quantum approach speeds up attention calculations in language models.

This research explores quantum chaos by analyzing entropy in quantum systems and their environments.

A basic look at Haar measure and its role in quantum systems.

A new model enhances quantum data analysis efficiency and accuracy.

New quantum methods improve measurement precision in various scientific fields.

Exploring a method for secure quantum state authentication across distances.

Examining Krylov complexity in Lifshitz scalar field theories and its implications.

New methods using equiangular tight frames enhance entanglement detection in quantum systems.

Research shows packed measurements can enhance quantum computations in symmetry protected topological phases.

A look into the unique properties of non-Hermitian systems.

A novel method addresses coherent errors in quantum devices to improve performance.

Autonomous quantum machines operate independently, improving efficiency in various applications.

Exploring methods to improve measurement accuracy in quantum systems.

Research reveals efficient methods for preparing high-dimensional frequency entangled qudits in quantum technology.

Investigating light interactions with rubidium vapor in strong magnetic fields.

Researchers demonstrate effective storage of single photons in microfabricated devices.

Explore the behavior of bosons and their fascinating phase transitions in quantum mechanics.

New decoding methods enhance quantum error correction, ensuring accuracy in complex computations.

A new approach simplifies quantum state preparation using fewer resources.

Exploring the significance of magic states in enhancing quantum computing capabilities.

Investigating how oscillations affect defect formation during phase transitions in quantum systems.

Understanding decoherence is vital for advancing quantum computing technologies.

Exploring how quenching affects defect formation in materials during phase transitions.

Researchers propose a method to detect deviations in quantum mechanics using Kullback–Leibler divergence.

Evaluating the efficiency of indefinite causal order in quantum computing.

Study reveals new ways to stabilize remote qubit entanglement with minimal resources.

QiankunNet uses neural networks to improve quantum chemistry calculations.

Internal squeezing boosts the performance of quantum sensors across various fields.

Quantum clocks use tiny particles for accurate timekeeping.

Quantum batteries offer innovative solutions for faster energy storage and extraction.

Research on partially spatially coherent qubits enhances secure quantum communication methods.

Examining the future of integer factorization and its role in cryptography.

Exploring strategies to ensure the safety of quantum data.

Time telescopes improve information transmission in quantum networks, enhancing communication capabilities.

Research demonstrates generating distant entanglement using innovative magnomechanical systems.