Physics - High Energy Physics - Phenomenology

Scientists investigate surprising findings suggesting potential new physics beyond the Standard Model.

ATLAS is set to measure high-energy neutrinos from supernova explosions.

Research on neutrinos at the LHC opens new insights in particle physics.

NFLikelihood enables unsupervised learning of likelihoods, enhancing data analysis in physics.

New imaging techniques shed light on quantum behaviors in nuclear particle interactions.

A look into the unique properties of neutron stars and their internal composition.

Researchers investigate Asymptotic Grand Unification Theories for fundamental physics.

Examining GW scalar interactions and their effects on RS model phase transitions.

Scientists seek to understand the fate of magnetic monopoles in the Universe.

Research investigates CP violation in charmed decays to understand matter-antimatter imbalance.

Examining the journey of particle physics and future research directions.

A look at how quarks gain mass in Quantum Chromodynamics.

Examining Q-balls and their implications in the Friedberg-Lee-Sirlin model using effective field theory.

Researchers improve predictions for heavy quarkonium production in particle collisions.

A guide to improving accuracy in Monte Carlo integration methods.

Innovative AI methods improve analysis of scalar field theories in physics.

Examining how correlation functions help understand the universe's early phases.

Exploring Higgs inflation and its impact on cosmic understanding through particle interactions.

Research reveals how tilted disks change our view of black holes.

Research reveals how dark matter interacts with crystal structures, providing new detection strategies.

A look into particle physics and new methods for studying fundamental interactions.

Exploring a model for lepton-flavored dark matter interactions via the Higgs boson.

Exploring how new models reshape our understanding of fundamental particles.

Investigating neutrinos at the LHC offers insights into fundamental forces and cosmic happenings.

This article examines quintuplet dark matter and its potential signals in the universe.

A look into heavy neutral leptons and their implications in particle physics.

Investigating rare particle decays with the Future Circular Collider offers new insights.

The EIC promises new data to improve our understanding of partons and nuclear structures.

Researchers aim to detect low-mass particles influencing decay processes.

Introducing an auxiliary group method to refine flavon models for particle mass.

This article explores decaying sterile neutrinos and their role in our universe.

Scientists investigate dark neutrinos using the International Linear Collider.

Muon colliders may enhance the search for dark matter through advanced techniques.

New research focuses on neutrinoless double beta decay and neutrino mass models.

Charm quark behavior in extreme conditions sheds light on fundamental particle interactions.

Investigation of neutrino mass hierarchy and the impact of scalar non-standard interactions.

Exploring how strong electric fields create electron-positron pairs from empty space.

Examining the link between gravitational waves and particle physics models.

Researchers use gravitational lensing to validate general relativity on a larger scale.

Examining the roles of partons and soft gluons in quantum chromodynamics.