Latest Articles for Experimental Physics

LHCb collaboration uncovers unusual particle structures, pushing physics boundaries.

An overview of Supersymmetry's potential in addressing unanswered questions in particle physics.

Neutrinos are tiny particles that reveal secrets of the universe.

New approaches enhance calculations of Feynman integrals in particle physics.

Exploring the role of electroweak phase transition in the universe's matter dominance.

A look into Lee-Yang zeros and their relevance in quantum measurements.

Research investigates quantum entanglement and Bell inequalities through scattering experiments.

Investigating charmonia and bottomonia production in high-energy physics experiments.

Examining the challenges of quantum measurements and their implications on reality.

A method to reduce crosstalk errors in quantum systems using machine learning.

Research on muon-philic ALPs may reshape our understanding of particle physics.

This article examines the thermal Hall effect in a unique magnetic material.

New methods improve accuracy and efficiency in quantum operations.

Researchers achieve high-fidelity operations in silicon-based quantum systems.

Recent findings reveal unique behaviors in quantum systems resisting thermalization.

Advancements in connecting quantum dots to atomic memory could enhance secure communication.

This method improves secure communication by detecting eavesdroppers without key comparison.

Examining how jets behave in extreme conditions of quark-gluon plasma.

This article reviews research on electric-dipole matrix elements in atomic cesium.

Examining particle interactions and dynamics in non-equilibrium states using the Fermi-Hubbard model.

Using singular value decomposition to improve energy level analysis.

Examining the interaction of light and electron emission in laser-assisted photoionization.

Researchers investigate particle collisions to uncover mysteries of the universe.

An overview of topological phases in SSH and eSSH models.

New methods enhance precision in studying hydrogen molecular ions and their quantum states.

This study examines particle decays to reveal potential new physics.

T2K experiment enhances neutrino detection with new technology upgrades.

Investigating how magnetic domains evolve in a ferromagnetic condensate under rapid changes.

Analyzing particle interactions through effective field theory and its implications.

New MCP-PMT enhances detection capabilities for neutrinos.

Study shows quantum entanglement can persist even at elevated temperatures.

NdNiO presents unique properties influencing superconductivity and electron behavior.

Research highlights the magnetic properties of FePS3 using advanced spectroscopy techniques.

Exploring the unique properties of continuous spin particles and their implications in physics.

Researchers study unique jets formed in Bose-Einstein condensates, revealing complex atomic interactions.

Examining how external influences interact with the quantum vacuum to create particles.

Exploring the link between disorder and new phases in quantum systems.

Exploring how confinement influences interactions and behaviors in dipolar bosons.

Research enhances qubit stability through innovative noise reduction techniques.

Research reveals new insights into protons' mass, spin, and internal structure.