Latest Articles for Particle Physics

Introducing a unified approach for analyzing electron interactions in heavy elements.

Exploring Majorana fermions and their role in improving quantum computing reliability.

This article examines the bootstrap method for simplifying inflation correlator calculations.

AMoRE-II seeks to detect rare neutrinoless double beta decay to unveil neutrino mysteries.

Research reveals effects of higher-order gradients on spin polarization in high-energy environments.

Research at LHC investigates flavons and their link to top quarks.

Researchers aim to detect elusive dark matter particles through innovative experiments.

Recent experiments reveal quantum effects in radiation reaction under extreme conditions.

Examining how strong magnetic fields influence the running coupling constant in quarks.

Research reveals insights into cosmic rays and their local behaviors.

Exploring the relationship between particle behavior and fluid dynamics.

Scientists analyze quark and gluon contributions to proton spin through advanced techniques.

Exploring the potential of Majorana particles in quantum computations.

This article examines the impact of theta term on particle masses.

Exploring the relationship between quantum systems and classical behavior through innovative models.

Research reveals how Hawking radiation affects quantum uncertainty in black holes.

Scientists investigate axions as a potential component of dark matter.

Exploring the complexities and developments in Yang-Mills theory.

Researching how the Higgs boson interacts with electrons through spin asymmetries.

A novel technique enhances top quark mass measurements using energy correlators.

Recent IXPE observations shed light on the Crab Pulsar and its environment.

Overview of the ECR panel's activities and developments throughout 2023.

Research reveals how unique particle shapes interact and form arrangements.

Research reveals crucial interactions between neutrinos and neutrinophilic mediators.

Exploring the intricate patterns in particle movement after heavy-ion collisions.

This article examines the impact of quantum effects on transversity operators in particle physics.

New simulations shed light on how neutrinos interact with dark matter.

New method traps tiny particles using specialized light patterns.

Exploring how neutron stars emit neutrinos and what this means for astrophysics.

Exploring Majorana particles and their implications for future quantum technologies.

This study examines inflation driven by a complex scalar field with diverse implications.

Analyzing how top and bottom quark masses influence Higgs boson production.

New insights into how black holes capture charged particles.

Research at the Pierre Auger Observatory seeks to understand dark matter through gamma rays.

Researchers investigate minimal dark matter and vector particles to uncover dark matter's nature.

New methods improve intensity in particle accelerators through beam stacking.

This article explores the behavior of particle densities in fermionic and bosonic systems.

Understanding wave interactions in the E-region enhances communication and weather predictions.

Researchers tighten constraints on neutrino masses, raising intriguing questions about their role in the universe.

Explore the world of electric and magnetic charges and their interactions.