Latest Articles for Experimental Physics

New findings on Josephson junctions enhance understanding of superconductivity and its applications.

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

This article discusses the significance of two-nucleon emission in neutrino interactions.

This study examines how critical currents affect superconducting quantum interference filters.

Examining the role of quantum Fisher information in chaotic quantum systems.

Examining the role of chiral interaction in photon blockade for quantum technology advancements.

Research reveals insights into strange quarks and their effects on nucleon properties.

Exploring the role of Majorana zero modes in the future of quantum computing.

Research explores elastic scattering and the significance of Pomeron and Odderon at LHC.

Scientists investigate Axion-Like Particles to address dark matter and particle interaction questions.

FASER achieves a milestone by detecting neutrinos at the LHC, enhancing future research.

Scientists explore invisible neutrino decay through DUNE and T2HKK experiments.

Quantum walks reveal unique particle behaviors and applications in technology.

Investigating acoustic Casimir forces and Bose-Einstein condensation in small helium samples.

Research delves into resonances formed by heavy quarks and their interactions.

Investigating electron behavior in quantum Hall bilayers under strong magnetic fields.

Exploring the significance of axion-like particles in physics and their connections to dark matter.

Researchers investigate the surprising magnetic properties of infinite-layer nickelates.

An overview of neutron-proton scattering and its significance in nuclear studies.

New cone-ray model enhances accuracy in flow density visualization.

Researchers examine muon g-2 anomaly and diphoton excess in search of new physics.

This study examines quantum droplets and their unique behaviors in two-dimensional traps.

Exploring the relationship between black holes and accelerated electrons through radiation.

Research aims to measure quantum gravity effects using xenon and advanced laser techniques.

This paper addresses the challenges of fermion masses in high-energy particle interactions.

New detectors may enhance our understanding of neutrinos and their interactions.

A look at how the FN mechanism helps explain particle mass variations.

Exploring the connections between neutrinos, dark matter, and lepton flavor violation.

Exploring the impact of quantum decoherence on neutrino behavior through major experiments.

New optical model potential enhances proton-nucleus interaction studies.

This article examines how central-spin models exhibit time-crystalline behavior under periodic driving.

A new approach to finding particles beyond the Standard Model.

Researching T-odd gluon TMDs reveals deeper aspects of nucleon behavior.

New insights into charge stripes and superfluidity in superconducting materials.

Investigating the elusive nature of dark matter and its interactions with particles.

A look into resonance's role in controlling particle behavior.

Investigating low-energy signals for dark matter discovery with solid-state detectors.

A new approach helps learn complex fermionic Hamiltonians with high precision.

Researchers aim to enhance phase measurement precision using quantum mechanics.

Study reveals unique behavior of Ds(2317)+ and Ds(2317)− in dense environments.