Terahertz technology, bridging microwaves and infrared, shows promise in security and biomedical applications.
Monte Carlo simulations are crucial in physics for solving complex problems and studying particle interactions.
Scientists study gravitational waves from black hole mergers to test general relativity’s predictions and limitations.
Neutrinos oscillate and have mass; determining their hierarchy is essential for understanding particle physics.
Researchers are advancing inertial confinement fusion for clean energy using powerful laser technology.
Non-Hermitian photonics enables precise light control through exceptional points and PT-symmetric systems.
Researchers explore topological quantum materials in superconducting nanowires for Majorana modes and quantum computing.
Gravitational wave parameter estimation enhances understanding of neutron star mergers using Bayesian inference techniques.
Researchers explore extending AdS/CFT duality to flat space, aiming to understand quantum gravity better.
Scientists study high-energy collisions to explore quark-gluon plasma and the early universe’s evolution.