Convection is
a macroscopic phenomena.
Microscopes are splendid devices, but they work by making the original
macroscopic phenomenon invisible.
Not exact matches
Colloidal suspensions fall into the category of materials known as «soft matter», and the softness of the rotational device is shown to lead to new transmission
phenomena not observed in
macroscopic machines.
Our findings provide a new understanding of jamming - related
phenomena across a wide range of both microscopic and
macroscopic systems.»
The coordinated
phenomenon of «schooling» is the
macroscopic result of a complex transmission of signals within the shoal, in which fish tend to maintain uniform polarization and cohesion in nearly crystallized swimming formations [1], [12].
Current research includes spin relaxation and decoherence in quantum dots due to spin - orbit and hyperfine interaction; non-Markovian spin dynamics in bosonic and nuclear spin environments; generation and characterization of non-local entanglement with quantum dots, superconductors, Luttinger liquids or Coulomb scattering in interacting 2DEGs; spin currents in magnetic insulators and in semiconductors; spin Hall effect in disordered systems; spin orbit effects in transport and noise; asymmetric quantum shot noise in quantum dots; entanglement transfer from electron spins to photons; QIP with spin qubits in quantum dots and molecular magnets;
macroscopic quantum
phenomena (spin tunneling and coherence) in molecular and nanoscale magnetism.
His group has research activities in fundamental optical and magnetic interactions in semiconductor quantum structures, spin dynamics and coherence in condensed matter systems,
macroscopic quantum
phenomena in nanometer - scale magnets, and implementations of quantum information processing in the solid state.
Soffer has been investigating various natural
phenomena from the microscopic to the
macroscopic, from geological, biological to cosmological.
• The union of microscopic (atomic level) Hamiltonian dynamical models with
macroscopic (system level) thermodynamical models, succeeds extraordinarily well at predicting a vast range of physical
phenomena (including heat conductivity, heat capacity, sound velocities, viscosity, thermal expansion, solubility / insolubility, etc..)
A key objective of work in the program is to develop a knowledge foundation of structure - function relationships for photoelectrochemical layers that allows for prediction and control of transport
phenomena in
macroscopic solar - fuel generation systems.