Quantum dynamics of a particle with a spin-dependent velocity

We study the dynamics of a particle in continuous time and space, the displacement of which is governed by an internal degree of freedom (spin). In one definite limit, the so-called quantum random walk is recovered but, although quite simple, the model possesses a rich variety of dynamics and goes far beyond this problem. Generally speaking, our framework can describe the motion of an electron in a magnetic sea near the Fermi level when linearization of the dispersion law is possible, coupled to a transverse magnetic field. Quite unexpected behaviours are obtained. In particular, we find that when the initial wave packet is fully localized in space, the Jz angular momentum component is frozen; this is an interesting example of an observable which, although it is not a constant of motion, has a constant expectation value. For a non-completely localized wave packet, the effect still occurs although less pronounced, and the spin keeps for ever memory of its initial state. Generally speaking, as time goes on, the spatial density profile looks rather complex, as a consequence of the competition between drift and precession, and displays various shapes according to the ratio between the Larmor period and the characteristic time of flight. The density profile gradually changes from a multimodal quickly moving distribution when the scattering rate is small, to a unimodal standing but flattening distribution in the opposite case.

[1]  P. D. Gennes,et al.  Superconductivity of metals and alloys , 1966 .

[2]  Jijun Zhao,et al.  Magnetism of transition-metal/carbon-nanotube hybrid structures. , 2003, Physical review letters.

[3]  Klaus Völker Dynamics of the Dissipative Two-State System , 1998 .

[4]  E. Sudarshan,et al.  Zeno's paradox in quantum theory , 1976 .

[5]  J. C. Wyant,et al.  Report to The American Physical Society of the study group on science and technology of directed energy weapons , 1987 .

[6]  A. Leggett,et al.  Dynamics of the dissipative two-state system , 1987 .

[7]  Ph Blanchard,et al.  Quantum random walks and piecewise deterministic evolutions. , 2004, Physical review letters.

[8]  Aharonov,et al.  Quantum random walks. , 1993, Physical review. A, Atomic, molecular, and optical physics.

[9]  J. Likforman,et al.  Selective excitation through multiphonon emission of ZnCdTe quantum dots embedded in Zn-rich ZnCdTe quantum wells , 2004 .

[10]  C. Gardiner Handbook of Stochastic Methods , 1983 .

[11]  W. Dur,et al.  Quantum walks in optical lattices , 2002, quant-ph/0207137.

[12]  Nuclear spintronics: quantum Hall and nano-systems , 2004, cond-mat/0403087.

[13]  Svante Janson,et al.  Weak limits for quantum random walks. , 2004, Physical review. E, Statistical, nonlinear, and soft matter physics.

[14]  H. Takayama,et al.  Continuum model for solitons in polyacetylene , 1980 .

[15]  Julia Kempe,et al.  Quantum random walks: An introductory overview , 2003, quant-ph/0303081.

[16]  Nayak Ashwin,et al.  Quantum Walk on the Line , 2000 .

[17]  L. Levitov,et al.  Dynamical spin-electric coupling in a quantum dot , 2002, cond-mat/0209507.

[18]  Norio Konno,et al.  Quantum Random Walks in One Dimension , 2002, Quantum Inf. Process..

[19]  J. M. Luttinger An Exactly Soluble Model of a Many‐Fermion System , 1963 .

[20]  Andris Ambainis,et al.  One-dimensional quantum walks , 2001, STOC '01.

[21]  Kazama,et al.  Exact operator quantization of a model of two-dimensional dilaton gravity. , 1993, Physical review. D, Particles and fields.

[22]  Wineland,et al.  Quantum Zeno effect. , 1990, Physical review. A, Atomic, molecular, and optical physics.

[23]  C. Aslangul,et al.  Time behavior of the correlation functions in a simple dissipative quantum model , 1985 .

[24]  Julia Kempe,et al.  Quantum Random Walks Hit Exponentially Faster , 2002, ArXiv.

[25]  Norio Konno,et al.  A new type of limit theorems for the one-dimensional quantum random walk , 2002, quant-ph/0206103.