Your search keyword '"Efremov, Maxim A."' showing total 5 results

1. Three-Body Bound States in Atomic Mixtures With Resonant p-Wave Interaction.

Author

Efremov, Maxim A., Plimak, Lev, Ivanov, Misha Yu., and Schleich, Wolfgang P.

Subjects

*BORN-Oppenheimer approximation, *PARTICLES, *RESONANCE, *ANGULAR momentum (Nuclear physics), *SCATTERING amplitude (Physics)

Abstract

We employ the Born-Oppenheimer approximation to find the effective potential in a three-body system consisting of a light particle and two heavy ones when the heavy-light short-range interaction potential has a resonance corresponding to a nonzero orbital angular momentum. In the case of an exact resonance in the p-wave scattering amplitude, the effective potential is attractive and long range; namely, it decreases as the third power of the interatomic distance. Moreover, we show that the range and power of the potential, as well as the number of bound states, are determined by the mass ratio of the particles and the parameters of the heavy-light short-range potential. [ABSTRACT FROM AUTHOR]

Published

2013

2. Atom lens without chromatic aberrations.

Author

Efremov, Maxim A., Mironova, Polina V., and Schleich, Wolfgang P.

Subjects

*LENSES, *ACHROMATISM, *ATOMS, *NUMERICAL calculations, *THEORY of wave motion, *STANDING waves

Abstract

We propose a lens for atoms with reduced chromatic aberrations and calculate its focal length and spot size. In our scheme a two-level atom interacts with a near-resonant standing light wave formed by two running waves of slightly different wave vectors, and a far-detuned running wave propagating perpendicularly to the standing wave. We show that within the Raman-Nath approximation and for an adiabatically slow atom-light interaction, the phase acquired by the atom is independent of the incident atomic velocity. [ABSTRACT FROM AUTHOR]

Published

2013

3. Berry phase in atom optics.

Author

Mironova, Polina V., Efremov, Maxim A., and Schleich, Wolfgang P.

Subjects

*GEOMETRIC quantum phases, *CENTER of mass, *ADIABATIC processes, *SCATTERING (Physics), *APPROXIMATION theory, *PHASE transitions, *OPTICS, *INTERFEROMETRY

Abstract

We consider the scattering of an atom by a sequence of two near-resonant standing light waves, each formed by two running waves with slightly different wave vectors. Due to opposite detunings of the two standing waves, within the rotating wave approximation, the adiabatic approximation applied to the atomic center-of-mass motion, and a smooth turning on and off of the interaction, the dynamical phase cancels out and the final state of the atom differs from the initial one only by the sum of the two Berry phases accumulated in the two interaction regions. This phase depends on the position of the atom in a way such that the wave packet emerging from the scattering region will focus, which constitutes a method to observe the Berry phase without resorting to interferometric methods. [ABSTRACT FROM AUTHOR]

Published

2013

4. Amplitude and Phase of Wave Packets in a Linear Potential.

Author

Rozenman, Georgi Gary, Zimmermann, Matthias, Efremov, Maxim A., Schleich, Wolfgang P., Shemer, Lev, and Arie, Ady

Subjects

*GRAVITY waves, *WATER waves, *WAVE packets, *WATER pumps, *WATER, *PSEUDOPOTENTIAL method

Abstract

We theoretically study and successfully observe the evolution of Gaussian and Airy surface gravity water wave packets propagating in an effective linear potential. This potential results from a homogeneous and time-dependent flow created by a computer-controlled water pump. For both wave packets we measure the amplitudes and the cubic phases appearing due to the linear potential. Furthermore, we demonstrate that the self-acceleration of the Airy surface gravity water wave packets can be completely canceled by a linear potential. [ABSTRACT FROM AUTHOR]

Published

2019

5. Diffractive Guiding of Waves by a Periodic Array of Slits.

Author

Weisman D, Carmesin CM, Rozenman GG, Efremov MA, Shemer L, Schleich WP, and Arie A

Abstract

We show that in order to guide waves, it is sufficient to periodically truncate their edges. The modes supported by this type of wave guide propagate freely between the slits, and the propagation pattern repeats itself. We experimentally demonstrate this general wave phenomenon for two types of waves: (i) plasmonic waves propagating on a metal-air interface that are periodically blocked by nanometric metallic walls, and (ii) surface gravity water waves whose evolution is recorded, the packet is truncated, and generated again to show repeated patterns. This guiding concept is applicable for a wide variety of waves.

Published

2021