Latest Articles for Ground States

Thouless pumps demonstrate quantized particle transport in quantum systems with practical implications.

Cooling methods enhance quantum computation efficiency for complex problem solving.

Exploring the link between real and imaginary time in quantum systems.

This study introduces NNBF to enhance ground state calculations in quantum chemistry.

A study on frustrated ladders reveals complex spin interactions and their behaviors.

This article explores anyons and their unique entanglement properties in quantum systems.

A new method for preparing ground states in quantum systems using cooling techniques.

Research on trapped ions reveals insights into their dynamics and interactions.

Research explores VQAs for solving nonlinear quantum dynamics challenges.

Research on spatiotemporal quenches enhances quantum state preparation for future technologies.

Study reveals how Rényi entropy relates to quantum ground states during phase changes.

Exploring the relationship between gauge theories, ADE singularities, and Chern-Simons theory.

Exploring the behavior of electrons in atoms through the Lorentz model.

This study examines phase separation in spin-1 and spin-2 Bose-Einstein condensates.

A look into randomized plaquette models and their impact on materials' phase transitions.

A look at the interaction between light and quantum states.

New algorithms enhance predictions of quantum ground states using limited data.

A look into how dynamic critical exponents shape the behavior of frustration-free systems.

Research into Chern bands reveals complex behaviors influenced by electron interactions.

This study explores the unique arrangements of particles under random conditions.

Exploring the toric code using machine learning for quantum computing advancements.

A new method enhances quantum state preparation in computing.

An overview of the Choquard equation and its applications in physics and mathematics.

Machine learning techniques enhance understanding of quantum systems and phase transitions.

Examining the stability and energy states of neutral bosonic molecules.

Exploring nonlinear PDEs through linearized versions reveals complex system behaviors.

Quantum computing may enhance research in complex chemical systems and materials.

A look into the properties and calculations of spin-2 BECs.

Research into quantum droplets reveals their unique behaviors in different dimensions.

A new method employs symmetries in neural networks to improve quantum system predictions.

Investigating how light and materials interact shapes future technology.

New models improve understanding of anharmonic oscillators' energy levels.

Researchers combine VQE and DBQA for better ground state preparation in quantum systems.

A study on how parametric resonance impacts quantum systems and their energy states.

This article discusses how electron energies affect chemical reactions and material properties.

Research sheds light on stable wave patterns in nonlocal coupled systems.

Researchers leverage quantum computing to study electron interactions in materials.

Researchers leverage new algorithms to enhance lattice gauge theory simulations.

Using neural networks to enhance variational Monte Carlo in quantum systems.

Exploring behavior of particles in many-body systems through density of states.