The quantum kicked particle in a magnetic field is studied in a weak-chaos regime under realistic conditions, i.e., for {\em general} values of the conserved coordinate $x_{{\rm c}}$ of the cyclotron orbit center. The system exhibits spectral structures [``Hofstadter butterflies'' (HBs)] and quantum diffusion depending sensitively on $x_{{\rm c}}$. Most significant changes take place when $x_{{\rm c}}$ approaches the value at which quantum antiresonance (exactly periodic recurrences) can occur: the HB essentially ``doubles'' and the quantum-diffusion coefficient $D(x_{{\rm c}})$ is strongly reduced. An explanation of these phenomena, including an approximate formula for $D(x_{{\rm c}})$ in a class of wave packets, is given on the basis of an effective Hamiltonian which is derived as a power expansion in a small parameter. The global quantum diffusion of a two-dimensional wave packet for all $x_{{\rm c}}$ is briefly considered.

Publié le : 2005-04-13
Classification:  Nonlinear Sciences - Chaotic Dynamics,  Condensed Matter - Mesoscale and Nanoscale Physics,  Mathematical Physics,  Physics - Atomic Physics,  Quantum Physics

@article{0504030,
     author = {Dana, Itzhack and Dorofeev, Dmitry L.},
     title = {General Approach to the Quantum Kicked Particle in a Magnetic Field:
  Quantum-Antiresonance Transition},
     journal = {arXiv},
     volume = {2005},
     number = {0},
     year = {2005},
     language = {en},
     url = {http://dml.mathdoc.fr/item/0504030}
}

Dana, Itzhack; Dorofeev, Dmitry L. General Approach to the Quantum Kicked Particle in a Magnetic Field:
  Quantum-Antiresonance Transition. arXiv, Tome 2005 (2005) no. 0, . http://gdmltest.u-ga.fr/item/0504030/