Latest Articles for Experimental Physics

Research reveals universal behaviors in autocorrelation through Krylov complexity analysis.

Examining how superconducting circuits advance our grasp of quantum mechanics and information transfer.

Exploring kinetic energy distribution in quantum systems and thermalization processes.

Research reveals unique properties of iron-based superconductors like FeSe1-xTex.

A new framework to measure changes in quantum observables.

Researchers propose a model with new particles to explain unexplained phenomena.

This study explores light nuclei formation during heavy-ion collisions and its implications for nuclear physics.

Researchers investigate dipolar supersolids, merging solid and superfluid properties for new insights.

Using QSVMs to improve flavor tagging in high-energy physics experiments.

Researchers investigate long-range interactions in quantum systems, focusing on magnetism and phase transitions.

Study of drop impacts reveals insights into fluid dynamics and natural processes.

Exploring the complexities of Higgs boson decay and its significance in particle physics.

Color-center qubits offer unique benefits for future quantum computing and communication.

Leptoquark models offer insights into fundamental interactions and anomalies in particle physics.

Explore the significance and computational challenges of double parton distributions.

Exploring the 3-3-1 model’s insights into fermions and dark matter.

Recent work enhances predictions about the Higgs boson decay width and its implications.

Researchers use multi-loop methods to measure complex non-Abelian gauge fields accurately.

A deep dive into quartet superfluidity and its implications in quantum systems.

Examining the interactions of quarks and gluons in Quantum Chromodynamics.

This article examines how monopolium loses energy while moving through materials.

Investigating lepton flavor violation could reveal unknown particles and forces.

Exploring how trapped-ion systems could enhance our understanding of quantum phenomena.

Study reveals complex interactions in Rydberg atoms leading to non-ergodic behaviors.

Research dives into the role of dopants in antiferromagnetic materials.

Study reveals unique magnetic behaviors in cesium superoxide at low temperatures.

Researchers investigate optical bistability in atom-cavity systems, revealing new phases and implications.

Research reveals how gas jets fluidize particles in a unique bed setup.

Research sheds light on gluonic components within protons through quarkonium studies.

Researching Higgs triplet particles to explain neutrino masses.

Researchers investigate the impact of disorder on Majorana nanowires for future computing.

This study investigates the impact of material defects on SRF cavity performance.

A look into non-standard interactions of neutrinos and their significance.

Study reveals key factors in particle mixing, influencing hadron decays.

Neutrino forces could challenge our understanding of interactions in the universe.

Exploring the Higgs boson, naturalness problem, and new particle models.

Examining atomic boson sampling and its implications for quantum computing.

This research explores the role of keV neutrinos in dark matter production.

Research improves atom interactions, enabling long-range communication in quantum technologies.

This study examines how baryons interact and form complex structures during scattering.