1,612 research outputs found
Numerical Jordan-Wigner approach for two dimensional spin systems
We present a numerical self consistent variational approach based on the
Jordan-Wigner transformation for two dimensional spin systems. We apply it to
the study of the well known quantum (S=1/2) antiferromagnetic XXZ system as a
function of the easy-axis anisotropy \Delta on a periodic square lattice. For
the SU(2) case the method converges to a N\'eel ordered ground state
irrespectively of the input density profile used and in accordance with other
studies. This shows the potential utility of the proposed method to investigate
more complicated situations like frustrated or disordered systems.Comment: Revtex, 8 pages, 4 figure
High-resolution tracking in a GEM-Emulsion detector
SHiP (Search for Hidden Particles) is a beam dump experiment proposed at the
CERN SPS aiming at the observation of long lived particles very weakly coupled
with ordinary matter mostly produced in the decay of charmed hadrons. The beam
dump facility of SHiP is also a copious factory of neutrinos of all three kinds
and therefore a dedicated neutrino detector is foreseen in the SHiP apparatus.
The neutrino detector exploits the Emulsion Cloud Chamber technique with a
modular structure, alternating walls of target units and planes of electronic
detectors providing the time stamp to the event. GEM detectors are one of the
possible choices for this task. This paper reports the results of the first
exposure to a muon beam at CERN of a new hybrid chamber, obtained by coupling a
GEM chamber and an emulsion detector. Thanks to the micrometric accuracy of the
emulsion detector, the position resolution of the GEM chamber as a function of
the particle inclination was evaluated in two configurations, with and without
the magnetic fiel
Switching on the deep brain stimulation: Effects on cardiovascular regulation and respiration.
BACKGROUND: Objective of this study was to evaluate the acute cardiovascular and respiratory effects of switching on the deep brain stimulation in the follow up of nine Parkinson's disease patients with subthalamic nucleus stimulation and six cluster headache patients with posterior hypothalamic area stimulation.
METHODS: Systolic and diastolic blood pressure, heart rate, and respiratory rate were monitored continuously during supine rest in both groups. Each patient was assessed in two conditions: resting supine with stimulator off and with stimulator on.
RESULTS: In supine resting condition switching on the DBS induced no significant changes (p>0.05) in systolic and diastolic blood pressure as well as in heart rate and respiratory rate, in both groups of patients, either taking 1 min or 10 heartbeats as a sample for analysis.
CONCLUSIONS: Switching on the DBS does not modify heart rate, blood pressure nor respiratory rate in both Parkinson and cluster headache patients under resting conditions
The Continuous Motion Technique for a New Generation of Scanning Systems
In the present paper we report the development of the Continuous Motion scanning technique and its implementation for a new generation of scanning systems. The same hardware setup has demonstrated a significant boost in the scanning speed, reaching 190 cm2/h. The implementation of the Continuous Motion technique in the LASSO framework, as well as a number of new corrections introduced are described in details. The performance of the system, the results of an efficiency measurement and potential applications of the technique are discussed
Optimization of Gutzwiller Wavefunctions in Quantum Monte Carlo
Gutzwiller functions are popular variational wavefunctions for correlated
electrons in Hubbard models. Following the variational principle, we are
interested in the Gutzwiller parameters that minimize e.g. the expectation
value of the energy. Rewriting the expectation value as a rational function in
the Gutzwiller parameters, we find a very efficient way for performing that
minimization. The method can be used to optimize general Gutzwiller-type
wavefunctions both, in variational and in fixed-node diffusion Monte Carlo.Comment: 9 pages RevTeX with 10 eps figure
Specific heat and high-temperature series of lattice models: interpolation scheme and examples on quantum spin systems in one and two dimensions
We have developed a new method for evaluating the specific heat of lattice
spin systems. It is based on the knowledge of high-temperature series
expansions, the total entropy of the system and the low-temperature expected
behavior of the specific heat as well as the ground-state energy. By the choice
of an appropriate variable (entropy as a function of energy), a stable
interpolation scheme between low and high temperature is performed. Contrary to
previous methods, the constraint that the total entropy is log(2S+1) for a spin
S on each site is automatically satisfied. We present some applications to
quantum spin models on one- and two- dimensional lattices. Remarkably, in most
cases, a good accuracy is obtained down to zero temperature.Comment: 10 pages (RevTeX 4) including 11 eps figures. To appear in Phys. Rev.
Phase separation in the 2D Hubbard model: a fixed-node quantum Monte Carlo study
Fixed-node Green's function Monte Carlo calculations have been performed for
very large 16x6 2D Hubbard lattices, large interaction strengths U=10,20, and
40, and many (15-20) densities between empty and half filling. The nodes were
fixed by a simple Slater-Gutzwiller trial wavefunction. For each value of U we
obtained a sequence of ground-state energies which is consistent with the
possibility of a phase separation close to half-filling, with a hole density in
the hole-rich phase which is a decreasing function of U. The energies suffer,
however, from a fixed-node bias: more accurate nodes are needed to confirm this
picture. Our extensive numerical results and their test against size, shell,
shape and boundary condition effects also suggest that phase separation is
quite a delicate issue, on which simulations based on smaller lattices than
considered here are unlikely to give reliable predictions.Comment: 4 pages, 1 figure; revised version, more data point
How resistant are levodopa-resistant axial symptoms? Response of freezing, posture, and voice to increasing levodopa intestinal infusion rates in Parkinson disease
Background and purpose: Treatment of freezing of gait (FoG) and other Parkinson disease (PD) axial symptoms is challenging. Systematic assessments of axial symptoms at progressively increasing levodopa doses are lacking. We sought to analyze the resistance to high levodopa doses of FoG, posture, speech, and altered gait features presenting in daily-ON therapeutic condition. Methods: We performed a pre-/postinterventional study including patients treated with levodopa/carbidopa intestinal gel infusion (LCIG) with disabling FoG in daily-ON condition. Patients were evaluated at their usual LCIG infusion rate (T1), and 1 h after 1.5× (T2) and 2× (T3) increase of the LCIG infusion rate by quantitative outcome measures. The number of FoG episodes (primary outcome), posture, speech, and gait features were objectively quantified during a standardized test by a blinded rater. Changes in motor symptoms, dyskinesia, and plasma levodopa concentrations were also analyzed. Results: We evaluated 16 patients with a mean age of 69 ± 9.4 years and treated with LCIG for a mean of 2.2 ± 2.1 years. FoG improved in 83.3% of patients by increasing the levodopa doses. The number of FoG episodes significantly decreased (mean = 2.3 at T1, 1.7 at T2, 1.2 at T3; p = 0.013). Posture and speech features did not show significant changes, whereas stride length (p = 0.049), turn duration (p = 0.001), and turn velocity (p = 0.024) significantly improved on doubling the levodopa infusion rate. Conclusions: In a short-term evaluation, the increase of LCIG dose can improve "dopa-resistant" FoG and gait issues in most advanced PD patients with overall good control of motor symptoms in the absence of clinically significant dyskinesia
Charge fluctuations close to phase separation in the two dimensional t-J model
We have studied the t-J model using the Green Function Monte Carlo technique.
We have obtained accurate energies well converged in the thermodynamic limit,
by performing simulations up to 242 lattice sites. By studying the energy as a
function of hole doping we conclude that there is no phase separation in the
physical region, relevant for HTc superconductors. This finding is further
supported by the hole-hole correlation function calculation. Remarkably, by
approaching the phase separation instability, for ,this function
displays enhanced fluctuations at incommensurate wavevectors, scaling linearly
with the doping, in agreement with experimental findings.Comment: To appear on Phys. Rev. Let
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