S. I. Shevchenko scite author profile

A microscopic theory of a non-dissipative drag in a two-component superfluid Bose gas is developed. The expression for the drag current in the system with the components of different atomic masses, densities and scattering lengths is derived. It is shown that the drag current is proportional to the square root of the gas parameter. The temperature dependence of the drag current is studied and it is shown that at temperature of order or smaller than the interaction energy the temperature reduction of the drag current is rather small. A possible way of measuring the drag factor is proposed. A toroidal system with the drag component confined in two half-ring wells separated by two Josephson barriers is considered. Under certain condition such a system can be treated as a Bose-Einstein counterpart of the Josephson charge qubit in an external magnetic field. It is shown that the measurement of the difference of number of atoms in two wells under a controlled evolution of the state of the qubit allows to determine the drag factor.

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Phase diagram of systems with pairing of spatially separated electrons and holes

Shevchenko

1994

Phys. Rev. Lett.

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Josephson vortex motion as a source for dissipation of superflow of e–h pairs in bilayers

Fil

Shevchenko

2009

J. Phys.: Condens. Matter

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It is shown that in a bilayer excitonic superconductor dissipative losses emerge under transmission of the current from the source to the load. These losses are proportional to the square of the interlayer tunneling amplitude and are independent of the value of the input current. The case of a quantum Hall bilayer is considered. The bilayer may work as a transmission line if the input current exceeds a certain critical value. An input current higher than the critical one induces Josephson vortices in the bilayer. The difference in electrochemical potentials is required to feed the load and it forces Josephson vortices to move. The state becomes non-stationary which leads to dissipation.

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S. I. Shevchenko

Nondissipative drag of superflow in a two-component Bose gas

Phase diagram of systems with pairing of spatially separated electrons and holes

Josephson vortex motion as a source for dissipation of superflow of e–h pairs in bilayers

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