Physics - Mesoscale and Nanoscale Physics

Research reveals how moving electrons affect light interaction in graphene.

Exploring the unique optical properties of bilayer graphene and their applications.

Research reveals methods to control charged localized excitons with strain tuning in two-dimensional materials.

Researchers optimize spin qubit movement, reducing errors for scalable quantum computers.

Exploring Majorana bound states and their significance in quantum computing within planar Josephson junctions.

Research into Josephson junctions reveals new insights into topological superconductivity and Majorana modes.

New method improves imaging of tiny structures using Coherent Diffraction Imaging.

A look into energy patterns and surface states in stacked chains under magnetic fields.

Exploring the potential of silicon nanowires in technology and their behavior at low temperatures.

Research reveals new insights into ferroelectric properties in transition metal dichalcogenides.

Exploring how liquid droplets move on solid surfaces and the effects of temperature and friction.

Exploring how ferrimagnetic Weyl semimetals control electron spins for future technology.

A look into magnetic skyrmions and their applications in future technology.

Research highlights the role of quantum geometry in electron interactions.

Discover how light influences magnetization in Rydberg atoms and doped semiconductors.

Cobalt monosilicide exhibits unique electrical and thermal behaviors influenced by its structure.

Research reveals electronic properties of twisted MoSe2 and WSe2 lattices.

Exploring magnetic domain walls and skyrmions for future memory technologies.

Altermagnets offer insights into spintronics through unique conductivity and N eel vector properties.

Examining electric current behavior in two-dimensional fermionic systems and their future technological impacts.

A new optimization method improves performance of spin-torque oscillators in computing.

Exploring the unique features of the 6/13 state in quantum physics.

A new method offers deeper insights into how light interacts with materials.

Exploring heat flow in insulating states of graphene under unique conditions.

An examination of the fascinating Domain-Wall Skyrmion phase in Quantum Chromodynamics.

Bilayer graphene shows promise for valleytronics, enabling new electronic technologies.

Research sheds light on anyon behavior in fractional quantum Hall states.

Quantum batteries aim to improve charging efficiency and capacity using quantum mechanics.

Exploring quasiparticles reveals insights into complex systems and quantum behavior.

Exploring the effects of THz pulses on ferrimagnetic materials.

Research reveals unique properties of spinor pairing in superconductors, advancing material understanding.

Research reveals the key role of hydrodynamics in polyelectrolyte solutions.

Study reveals unique properties of HgTe films and their quantum Hall effect.

Research shows strain boosts light emission in TMDs and InSe layers.

Researchers create controllable 2D quantum dot arrays for quantum computing applications.

Researchers achieve high-fidelity operations with spin qubits in silicon.

Research reveals efficient control of NV centers using magnetoelastic waves.

Time crystals could change the landscape of quantum computing.

Researchers examine shot noise to unlock secrets of heavy-fermion compounds.

Research reveals quantized energy levels in a diamond acoustic lattice.