- Quantum stirring, ratchets, and pumping
A pump is an AC driven device that generates a DC current. In the simplest configuration a pump has two leads connected to two reservoirs. In such open geometry the pump takes particles from one reservoir and emits them into the other. Accordingly a current is produced even if the reservoirs have the same temperature and chemical potential.Stirring is the operation of inducing a circulating current with a non-vanishing DC component in a closed system. The simplest geometry is obtained by integrating a pump in a closed circuit. More generally we can consider any type of stirring mechanism such as moving a spoon in a cup of coffee.
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] The latter are defined in this context as AC driven spatially periodic arrays, where DC current is induced. Dissipation is essential for the operation of a conventional Ratchet system, but there are also non-dissipative Hamiltonian Ratchet systems that can be regarded as an "unfolded" version of "quantum stirring in a ring".Strictly speaking stirring is a non-linear effect, because in linear response theory (LRT) an AC driving induces an AC current with the same frequency. Still an adaptation of the LRT Kubo formalism allows the analysis of stirring. The quantum pumping problem (where we have an open geometry) can be regarded as a special limit of the quantum stirring problem (where we have a closed geometry). Optionally the latter can be analyzed within the framework of scattering theory.
It is possible to induce a DC current by applying a bias, or if the particles are charged then by applying an electro-motive-force. In contrast to that a quantum pumping mechanism produces a DC current in response to a cyclic deformation of the confining potential. In order to have a DC current from an AC driving, time reversal symmetry (TRS) should be broken. In the absence of magnetic field and dissipation it is the driving itself that can break TRS. Accordingly the typical pump operation is based on varying more than one parameter. The best known example is the peristaltic mechanism that combines a cyclic squeezing operation with on/off switching of entrance/exit valves.
The studies of quantum pumping and of quantum stirring emphasize the role of quantum interference in the analysis of the induced current. A major objective is to calculate the amount of transported particles per a driving cycle. There are circumstances in which is an integer number due to the topology of parameter space. More generally is affected by inter-particle interactions, disorder, chaos, noise and dissipation.
The Kubo approach to quantum stirring
Consider a closed system which is described by a Hamiltonian that depends on some control parameters . If is an Aharonov Bohm magnetic flux through the ring, then by Farady law is the electro motive force. If linear response theory applies we have the proportionality , where is the called the Ohmic conductance. In complete analogy if we change the current is , and if we change the current is , where and are elements of a conductance matrix. Accordingly for a full pumping cycle:
The conductance can be calculated and analyzed using the Kubo formula approach to quantum pumping [D. Cohen, Phys. Rev. B 68, 155303 (2003).] , which is based on the theory of adiabatic processes.D. J. Thouless, Phys. Rev. B 27, 6083 (1983).
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] Here we write the expression that applies in the case of low frequency "quasi static" driving process (the popular terms "DC driving" and "adiabatic driving" turn out to be misleading so we do not use them):where is the current operator, and is the generalized force that is associated with the control parameter . Though this formula is written using quantum mechanical notations it holds also classically if the commutator is replaced by Poisson brackets. In general can be written as a sum of two terms: one has to do with dissipation, while the other, denoted as has to do with geometry. The dissipative part vanishes in the strict quantum adiabatic limit, while the geometrical part might be non-zero. It turns out that in the strict adiabatic limit is the "
Berry curvature " (mathematically known as ``two-form"). Using the notations and we can rewrite the formula for the amount of pumped particles aswhere we define the normal vector as illustrated. The advantage of this point of view is in the intuition that it gives for the result: is related to the flux of a field which is created (so to say) by ``magnetic charges" in space. In practice the calculation of is done using the following formula:
This furmula can be regarded as the quantum adiabatic limit of the Kubo formula. The eigenstates of the system are labeled by the index . These are in general many body states, and the energies are in general many body energies. At finite temperatures a thermal average over is implicit. The field can be regarded as the rotor of "vector potential" (mathematically known as the ``one-form"). Namely, . The ``
Berry phase " which is acquired by a wavefunction at the end of a closed cycle isAccordingly one can argue that the "magnetic charge" that generates (so to say) the field consists of quantized "Dirac monopoles". It follows from gauge invariance that the degeneracies of the system are arranged as vertical Dirac chains. The "Dirac monopoles" are situated at points where has a degeneracy with another level. The Dirac monopoles picture [D. Cohen, arXiv:cond-mat/0208233 (2002).] is useful for charge transport analysis: the amount of transported charge is determined by the number of the Dirac chains encircled by the pumping cycle. Optionally it is possible to evaluate the transported charge per pumping cycle from the Berry phase by differentiating it with respect to the Aharonov-Bohm flux through the device. [M. Aunola and J. J. Toppari, Phys. Rev. B 68, 020502 (2003).]
Ratchet systems
The term Ratchet refers to directed transport in a driven spatially periodic system. The operation of a Ratchet involves one parameter driving. It is assumed that the system is unbiased, i.e. the average driving force is zero. The directed transport in a conventional Ratchet system is the outcome of an interplay between broken spatial inversion symmetry of the driving force, and broken time reversal symmetry due to dissipation. Another type of paradigm is the Hamiltonian ratchet, where the induced directed transport in the chaotic region of phase space is complementary to the opposite ballistic motion in the excluded islands.
The scattering approach to quantum pumping
The Ohmic conductance of a mesoscopic device that is connected by leads to reservoirs is given by the Landauer formula: in dimensionless units the Ohmic conductance of an open channel equals its transmission. The extension of this scattering point of view in the context of quantum pumping leads to the Brouwer-Buttiker-Pretre-Thomas (BPT) formula which relates the geometric conductance to the matrix of the pump:
Here is a projector that restrict the trace operations to the open channels of the lead where the current is measured. This BPT formula has been originally derived using a scattering approach [M. Buttiker, H. Thomas and A Pretre, Z. Phys. B Condens. Mat. 94, 133 (1994).] , but later its relation to the Kubo formula has been worked out. [D. Cohen, Phys. Rev. B 68, 201303(R) (2003).]
The effect of Interactions
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