Latest Articles for Hamiltonian

A new method enhances simulations in lattice gauge theories using maximal tree gauge fixing.

Quantum many-body scars defy thermalization, preserving unique states in complex systems.

Investigating how minimal length affects space, time, and particle interactions.

Exploring spin interactions in the Sherrington-Kirkpatrick model at high temperatures.

This article presents a particle model consistent with BMS symmetries in physics.

A new algorithm aims to improve optimization in quantum computing.

Examining complex particle interactions through higher-order Hamiltonians in scattering theory.

This article examines the relationship between quantum systems and prime numbers.

Exploring the intersection of quantum computing and optimization through Quantum Max Cut.

Study of Bose excitations in plasma through non-Abelian interactions and their implications.

A new method for finding eigenvalues in quantum systems using limited resources.

A look into the advancements in non-Hermitian quantum field theories and their implications.

A basic overview of how atoms interact with light using programming.

Exploring the impact of quantum computing on understanding particle physics through lattice QCD.

A new method simplifies reaching low-energy states in quantum systems.

A new algorithm improves simulation of Hamiltonian dynamics in quantum systems.

New modeling techniques improve predictions in complex dynamical systems.

New strategy improves robustness of quantum gates for practical applications.

A look at the Whitham equation's role in shallow water wave studies.

New insights into the Kitaev spin liquid model reveal intriguing properties of anyons.

Researchers are studying non-linear sigma models to improve quantum computing methods.

A look at boundary states and their role in quantum mechanics.

A deep learning approach enhances Hamiltonian reconstruction for quantum simulations.

Researchers develop LOWESA to efficiently simulate quantum systems using classical computers.

Twisted trilayer graphene shows unique electronic properties through its layered and twisted structure.

A look at the basics of quantum systems and their practical applications.

Exploring the Partial Qubit Hamiltonian method for efficient molecular simulations in quantum chemistry.

A new method for learning Hamiltonians enhances quantum technology performance.

A look into Hamiltonians and their role in quantum electrodynamics.

Exploring flatbands and their impact on electron localization and material properties.

TDMVCC enhances our ability to study molecular behavior over time.

This article examines the evolution from string vacuum solutions to complex cosmological models.

Examining equalities in thermodynamics to enhance energy optimization across systems.

Using the QLanczos algorithm to compute energy states in nuclear systems.

A look at dense celestial pairs and their gravitational wave emissions.

Hamiltonian learning advances quantum systems understanding, focusing on steady states and degeneracy.

Exploring the use of deep learning in modeling Hamiltonian systems.

Exploring how quantum processes shape our classical world.

Researchers study robust topological edge states using Rydberg atoms and various arrangements.

Research shows how surface changes affect magnetization in small materials.