371 research outputs found
Dynamics of the collective modes of an inhomogeneous spin ensemble in a cavity
We study the excitation dynamics of an inhomogeneously broadened spin
ensemble coupled to a single cavity mode. The collective excitations of the
spin ensemble can be described in terms of generalized spin waves and, in the
absence of the cavity, the free evolution of the spin ensemble can be described
as a drift in the wave number without dispersion. In this article we show that
the dynamics in the presence of coupling to the cavity mode can be described
solely by a modified time evolution of the wave numbers. In particular, we show
that collective excitations with a well- defined wave number pass without
dispersion from negative to positive valued wave numbers without populating the
zero wave number spin wave mode. The results are relevant for multi-mode
collective quantum memories where qubits are encoded in different spin waves.Comment: Published version. Some small changes and correction
The field inside a random distribution of parallel dipoles
We determine the probability distribution for the field inside a random
uniform distribution of electric or magnetic dipoles.
For parallel dipoles, simulations and an analytical derivation show that
although the average contribution from any spherical shell around the probe
position vanishes, the Levy stable distribution of the field is symmetric
around a non-vanishing field amplitude.
In addition we show how omission of contributions from a small volume around
the probe leads to a field distribution with a vanishing mean, which, in the
limit of vanishing excluded volume, converges to the shifted distribution.Comment: RevTeX, 4 pages, 3 figures. Submitted to Phys. Rev. Let
Scalable designs for quantum computing with rare-earth-ion-doped crystals
Due to inhomogeneous broadening, the absorption lines of rare-earth-ion
dopands in crystals are many order of magnitudes wider than the homogeneous
linewidths. Several ways have been proposed to use ions with different
inhomogeneous shifts as qubit registers, and to perform gate operations between
such registers by means of the static dipole coupling between the ions.
In this paper we show that in order to implement high-fidelity quantum gate
operations by means of the static dipole interaction, we require the
participating ions to be strongly coupled, and that the density of such
strongly coupled registers in general scales poorly with register size.
Although this is critical to previous proposals which rely on a high density of
functional registers, we describe architectures and preparation strategies that
will allow scalable quantum computers based on rare-earth-ion doped crystals.Comment: Submitted to Phys. Rev.
Quantum simulation of the hexagonal Kitaev model with trapped ions
We present a detailed study of quantum simulations of coupled spin systems in
surface-electrode ion-trap arrays, and illustrate our findings with a proposed
implementation of the hexagonal Kitaev model [A. Kitaev, Annals of Physics
321,2 (2006)]. The effective (pseudo)spin interactions making up such quantum
simulators are found to be proportional to the dipole-dipole interaction
between the trapped ions, and are mediated by motion which can be driven by
state-dependent forces. The precise forms of the trapping potentials and the
interactions are derived in the presence of a surface electrode and a cover
electrode. These results are the starting point to derive an optimized
surface-electrode geometry for trapping ions in the desired honeycomb lattice
of Kitaev's model, where we design the dipole-dipole interactions in a way that
allows for coupling all three bond types of the model simultaneously, without
the need for time discretization. Finally we propose a simple wire structure
that can be incorporated in a microfabricated chip to generate localized
state-dependent forces which drive the couplings prescribed by this particular
model; such a wire structure should be adaptable to many other situations.Comment: 24 pages, 7 figures. v2: simplified the derivation of (28) without
changing conclusions; minor edits. v3: minor edit
Quantum computing with an electron spin ensemble
We propose to encode a register of quantum bits in different collective
electron spin wave excitations in a solid medium. Coupling to spins is enabled
by locating them in the vicinity of a superconducting transmission line cavity,
and making use of their strong collective coupling to the quantized radiation
field. The transformation between different spin waves is achieved by applying
gradient magnetic fields across the sample, while a Cooper Pair Box, resonant
with the cavity field, may be used to carry out one- and two-qubit gate
operations.Comment: Several small corrections and modifications. This version is
identical to the version published in Phys. Rev. Let
Transport and Spectroscopic Studies of the Effects of Fullerene Structure on the Efficiency and Lifetime of Polythiophene-based Solar Cells
Time-dependent measurements of both power conversion efficiency and
ultraviolet-visible absorption spectroscopy have been observed for solar cell
blends containing the polymer poly(3-hexylthiophene-2,5-diyl) (P3HT) with two
different functionalized C60 electron acceptor molecules: commercially
available [6,6]-phenyl C61 butyric acid methyl ester (PCBM) or [6,6]-phenyl C61
butyric acid octadecyl ester (PCBOD) produced in this laboratory. Efficiency
was found to decay with an exponential time dependence, while spectroscopic
features show saturating exponential behavior. Time constants extracted from
both types of measurements showed reasonable agreement for samples produced
from the same blend. In comparison to the PCBM samples, the stability of the
PCBOD blends was significantly enhanced, while both absorption and power
conversion efficiency were decreased.Comment: manuscript submitted to Solar Energy Materials and Solar Cell
Spectroscopic properties of inhomogeneously broadened spin ensembles in a cavity
In large ensembles of identical atoms or spins, the interaction with a mode
of the electromagnetic radiation field concentrates in a single superradiant
degree of freedom with a collectively enhanced coupling. Given a controllable
inhomogeneous broadening, such ensembles may be used for multi-mode storage of
quantum states of the radiation field with applications in quantum
communication networks and quantum computers. In this paper we analyze how the
width and shape of the inhomogeneous broadening influence the collective
enhancement and the dynamics of the cavity-ensemble system with focus on the
consequences for the ensemble's applicability for quantum information
processing tasks.Comment: 12 pages, 5 figure
Scalable ion traps for quantum information processing
We report on the design, fabrication, and preliminary testing of a 150 zone
array built in a `surface-electrode' geometry microfabricated on a single
substrate. We demonstrate transport of atomic ions between legs of a `Y'-type
junction and measure the in-situ heating rates for the ions. The trap design
demonstrates use of a basic component design library that can be quickly
assembled to form structures optimized for a particular experiment
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