1,393 research outputs found
Design Parameters in Multimodal Games for Rehabilitation
Published under the Liebert "Open Option"Objectives: The repetitive and sometimes mundane nature of conventional rehabilitation therapy provides an ideal opportunity for development of interactive and challenging therapeutic games that have the potential to engage and motivate the players. Certain game design parameters that may encourage patients to actively participate by making the games more enjoyable have been identified. In this article, we describe a formative study in which we designed and evaluated some of these parameters with healthy subjects. Materials and Methods: The ‘‘operant conditioning’’ and ‘‘scoring’’ design parameters were incorporated in a remake of a classic labyrinth game, ‘‘Marble Maze.’’ A group of participants (n = 37) played the game twice: Once in the control condition without both modalities and then with either one of the parameters or with both. Measures of game duration and number of fails in the game were recorded along with survey questionnaires to measure player perceptions of intrinsic motivation on the game. Results: Longer playtimes, higher levels of interest/enjoyment, and effort to play the game were recorded with the introduction of these parameters. Conclusions: This study provides an understanding on how game design parameters can be used to motivate and encourage people to play longer. With these positive results, future aims are to test the parameters with stroke patients, providing much clearer insight as to what influences these parameters have on patients un- dergoing therapy. The ultimate goal is to utilize game design in order to maintain longer therapeutic interaction between a patient and his or her therapy medium.Peer reviewedFinal Published versio
Anyon Condensation and Continuous Topological Phase Transitions in Non-Abelian Fractional Quantum Hall States
We find a series of possible continuous quantum phase transitions between
fractional quantum Hall (FQH) states at the same filling fraction in
two-component quantum Hall systems. These can be driven by tuning the
interlayer tunneling and/or interlayer repulsion. One side of the transition is
the Halperin (p,p,p-3) Abelian two-component state while the other side is the
non-Abelian Z4 parafermion (Read-Rezayi) state. We predict that the transition
is a continuous transition in the 3D Ising class. The critical point is
described by a Z2 gauged Ginzburg-Landau theory. These results have
implications for experiments on two-component systems at \nu = 2/3 and
single-component systems at \nu = 8/3.Comment: 4 pages + ref
Non-linear Resistivity of a Two-Dimensional Electron Gas in a Magnetic Field
We develop a theory of nonlinear response to an electric field of a
two-dimensional electron gas (2DEG) placed in a classically strong magnetic
field. The latter leads to a non-linear current-voltage characteristic at a
relatively weak electric field. The origin of the non-linearity is two-fold:
the formation of a non-equilibrium electron distribution function, and the
geometrical resonance in the inter-Landau-levels transitions rates. We find the
dependence of the current-voltage characteristics on the electron relaxation
rates in the 2DEG.Comment: 4 pages, 2 figure
Enhancing the stability of a fractional Chern insulator against competing phases
We construct a two-band lattice model whose bands can carry the Chern numbers
C=0,pm1,pm2. By means of numerical exact diagonalization, we show that the most
favorable situation that selects fractional Chern insulators (FCIs) is not
necessarily the one that mimics Landau levels, namely a flat band with Chern
number 1. First, we find that the gap, measured in units of the on-site
electron-electron repulsion, can increase by almost two orders of magnitude
when the bands are flat and carry a Chern number C=2 instead of C=1. Second, we
show that giving a width to the bands can help to stabilize a FCI. Finally, we
put forward a tool to characterize the real-space density profile of the ground
state that is useful to distinguish FCI from other competing phases of matter
supporting charge density waves or phase separation.Comment: 10 pages, 6 figure
Imaging Transport Resonances in the Quantum Hall Effect
We use a scanning capacitance probe to image transport in the quantum Hall
system. Applying a DC bias voltage to the tip induces a ring-shaped
incompressible strip (IS) in the 2D electron system (2DES) that moves with the
tip. At certain tip positions, short-range disorder in the 2DES creates a
quantum dot island in the IS. These islands enable resonant tunneling across
the IS, enhancing its conductance by more than four orders of magnitude. The
images provide a quantitative measure of disorder and suggest resonant
tunneling as the primary mechanism for transport across ISs.Comment: 4 pages, 4 figures, submitted to PRL. For movies and additional
infomation, see http://electron.mit.edu/scanning/; Added scale bars to
images, revised discussion of figure 3, other minor change
Magnetic oscillations in planar systems with the Dirac-like spectrum of quasiparticle excitations II: transport properties
The quantum magnetic oscillations of electrical (Shubnikov de Haas effect)
and thermal conductivities are studied for graphene which represents a
distinctive example of planar systems with a linear, Dirac-like spectrum of
quasiparticle excitations. We show that if a utmost care was taken to separate
electron and phonon contributions in the thermal conductivity, the oscillations
of electron thermal conductivity, and the Lorenz number,
would be observable in the low field (less than a few Teslas) regime.Comment: 11 pages, RevTeX4, 6 EPS figures; 2 references, 1 figure and one more
section are added; final version published in PR
Fluctuation effects in disordered Peierls systems
We review the density of states and related quantities of quasi
one-dimensional disordered Peierls systems in which fluctuation effects of a
backscattering potential play a crucial role. The low-energy behavior of
non-interacting fermions which are subject to a static random backscattering
potential will be described by the fluctuating gap model (FGM). Recently, the
FGM has also been used to explain the pseudogap phenomenon in high-
superconductors. After an elementary introduction to the FGM in the context of
commensurate and incommensurate Peierls chains, we develop a non-perturbative
method which allows for a simultaneous calculation of the density of states
(DOS) and the inverse localization length. First, we recover all known results
in the limits of zero and infinite correlation lengths of the random potential.
Then, we attack the problem of finite correlation lengths. While a complex
order parameter, which describes incommensurate Peierls chains, leads to a
suppression of the DOS, i.e. a pseudogap, the DOS exhibits a singularity at the
Fermi energy if the order parameter is real and therefore refers to a
commensurate system. We confirm these results by calculating the DOS and the
inverse localization length for finite correlation lengths and Gaussian
statistics of the backscattering potential with unprecedented accuracy
numerically. Finally, we consider the case of classical phase fluctuations
which apply to low temperatures where amplitude fluctuations are frozen out. In
this physically important regime, which is also characterized by finite
correlation lengths, we present analytic results for the DOS, the inverse
localization length, the specific heat, and the Pauli susceptibility.Comment: 60 pages, 16 figure
Spinful Composite Fermions in a Negative Effective Field
In this paper we study fractional quantum Hall composite fermion
wavefunctions at filling fractions \nu = 2/3, 3/5, and 4/7. At each of these
filling fractions, there are several possible wavefunctions with different spin
polarizations, depending on how many spin-up or spin-down composite fermion
Landau levels are occupied. We calculate the energy of the possible composite
fermion wavefunctions and we predict transitions between ground states of
different spin polarizations as the ratio of Zeeman energy to Coulomb energy is
varied. Previously, several experiments have observed such transitions between
states of differing spin polarization and we make direct comparison of our
predictions to these experiments. For more detailed comparison between theory
and experiment, we also include finite-thickness effects in our calculations.
We find reasonable qualitative agreement between the experiments and composite
fermion theory. Finally, we consider composite fermion states at filling
factors \nu = 2+2/3, 2+3/5, and 2+4/7. The latter two cases we predict to be
spin polarized even at zero Zeeman energy.Comment: 17 pages, 5 figures, 4 tables. (revision: incorporated referee
suggestions, note added, updated references
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