Latest Articles for Phonons

Examining the causes and implications of Low Energy Excess in low threshold calorimeters.

Scientists propose a novel way to create single mid-infrared photons for advanced applications.

This article examines how rough surfaces affect phonon behavior in graphene.

Exploring exciton dissociation for better solar cells and LEDs.

New strategies enhance cooling efficiency in optomechanical systems.

Mechanical qubits show potential for faster processing and new applications in quantum technology.

Researchers combine diamond and piezoelectric materials for better phonon control in quantum computing.

Research reveals complexities of deconfined quantum critical points in materials.

New designs reduce thermal noise, enhancing quantum information transfer.

Study reveals how temperature and layers impact graphene phonon behavior.

A new method improves charge transport simulations in organic semiconductors, aiding device design.

Research reveals complex interactions in spin relaxation and their implications.

Research reveals key phonon contributions to superconductivity in twisted bilayer graphene.

New methods improve predictions of material behavior under varying conditions.

Insights into how heat moves through thin films, enhancing electronic devices.

Investigating how magnetic fields impact phonon dynamics in Kitaev materials.

Research reveals how quantum wires interact with mechanical motion and Lorentz invariance.

A new machine learning method speeds up phonon calculations for material properties.

Examining the potential of the Kekulé Valence Bond Solid state in graphene.

Exploring non-local heating and cooling effects in thermoelectric materials at the nanoscale.

Research reveals exciting interactions between magnons, phonons, and light for future technologies.

Research unveils key factors influencing single-photon emission in quantum technologies.

Study reveals insights into heat and electricity movement in 2D materials.

Bichromatic driving improves thermometry in trapped ion systems for quantum computing.

Research reveals fascinating interactions between excitons and phonons in layered materials.

Researchers are investigating ways to reduce light speed for better quantum technologies.

Research on interlayer excitons reveals new opportunities in electronics and optics.

Sapphire exhibits unique heat conduction properties even with impurities.

Bi Rh Se demonstrates unique properties with charge density waves and superconductivity.

Examining how atomic arrangements affect phonons and heat storage in materials.

Research reveals how defects in MoS2 affect its heat conductivity, enhancing device performance.

BaCo(AsO) shows remarkable heat conduction linked to magnetic properties.

Ba K BiO reveals unique properties critical for understanding superconductivity.

Exploring high-frequency spin waves in antiferromagnetic materials for advanced data processing.

This study investigates how heat moves in Mott insulators, focusing on spins and phonons.

Recent research sheds light on electron movement in quantum dot arrays.

Research tackles phonon-induced errors in spin qubits for better quantum computing.

Exploring the transition between fluid-like and structured electron states in two-dimensional materials.

Exploring new waveguide designs to reduce energy loss in phononic systems.

A new technique generates squeezed light using excitons and phonons at room temperature.