One-dimensional p-wave superconductor toy-model for Majorana fermions in multiband semiconductor nanowires

Majorana fermions are particles identical to their antiparticles proposed theoretically in 1937 by Ettore Majorana as real solutions of the Dirac equation. Alexei Kitaev suggested that Majorana particles should emerge in condensed matter systems as zero mode excitations in one-dimensional p-wave superconductors, with possible applications in quantum computation due to their non-abelian statistics. The search for Majorana zero modes in condensed matter systems led to one of the first realistic models based in a semiconductor nanowire with high spin-orbit coupling, induced superconducting s-wave pairing and Zeeman splitting. Soon, it was realized that size-quantization effects should generate subbands in these systems that could even allow the emergence of more than one Majorana mode at each edge, resulting in a zero bias peak on the differential conductance with a different shape from the predicted by simplified theoretical models. In this work, we provide a connection between a finite-size nanowire with two occupied subbands and a 2-band Kitaev chain and discuss the advantage of an one-dimensional model to understand the phenomenology of the system, including the presence of a hidden chiral symmetry and its similarity with a spinfull Kitaev chain under a magnetic field.Comment: 4 pages, 2 figures. IEEE Transactions on Applied Superconductivity accepted versio

Interest rates and inflation

Monetary policy ; Interest rates ; Inflation (Finance)

Measuring the temperature and heating rate of a single ion by imaging

We present a technique based on high resolution imaging to measure the absolute temperature and the heating rate of a single ion trapped at the focus of a deep parabolic mirror. We collect the fluorescence light scattered by the ion during laser cooling and image it onto a camera. Accounting for the size of the point-spread function and the magnification of the imaging system, we determine the spatial extent of the ion, from which we infer the mean phonon occupation number in the trap. Repeating such measurements and varying the power or the detuning of the cooling laser, we determine the anomalous heating rate. In contrast to other established schemes for measuring the heating rate, one does not have to switch off the cooling but the ion is always maintained in a state of thermal equilibrium at temperatures close to the Doppler limit

Assessment of model based (input) impedance, pulse wave velocity, and wave reflection in the Asklepios Cohort

Objectives : Arterial stiffness and wave reflection parameters assessed from both invasive and non-invasive pressure and flow readings are used as surrogates for ventricular and vascular load. They have been reported to predict adverse cardiovascular events, but clinical assessment is laborious and may limit widespread use. This study aims to investigate measures of arterial stiffness and central hemodynamics provided by arterial tonometry alone and in combination with aortic root flows derived by echocardiography against surrogates derived by a mathematical pressure and flow model in a healthy middle-aged cohort. Methods : Measurements of carotid artery tonometry and echocardiography were performed on 2226 ASKLEPIOS study participants and parameters of systemic hemodynamics, arterial stiffness and wave reflection based on pressure and flow were measured. In a second step, the analysis was repeated but echocardiography derived flows were substituted by flows provided by a novel mathematical model. This was followed by a quantitative method comparison. Results : All investigated parameters showed a significant association between the methods. Overall agreement was acceptable for all parameters (mean differences: -0.0102 (0.033 SD) mmHg*s/ml for characteristic impedance, 0.36 (4.21 SD) mmHg for forward pressure amplitude, 2.26 (3.51 SD) mmHg for backward pressure amplitude and 0.717 (1.25 SD) m/s for pulse wave velocity). Conclusion : The results indicate that the use of model-based surrogates in a healthy middle aged cohort is feasible and deserves further attention

Green synthesis of novel chalcone and coumarin derivatives via Suzuki coupling reaction

AbstractChalcones and coumarins are important naturally occurring plant constituents and display a wide range of pharmacological and biological activities. In an environmentally benign approach, synthesis of biphenyl chalcone and coumarin derivatives was successfully accomplished via Suzuki coupling by using PEG-400 as a solvent under microwave irradiation. Salient feature of this methodology includes: short reaction time, good to excellent yields, and prominent tolerance of different functional groups

Ebselen Improves Ischemia-Reperfusion Injury After Rat Lung Transplantation

The heterocyclic organic compound ebselen (2-phenyl-1,2-benizsoselenazol-3(2H)-one) is a glutathione peroxidase mimick with protective properties against oxidative injury. Ebselen also has anti-inflammatory activity, including attenuation of tumor necrosis factor release and increase of interleukin-10, as shown invivo, in inflammatory and ischemia-reperfusion injuries, including those of the lung. This study was designed to assess its effect on severe ischemia-reperfusion injury in a model of left-sided rat lung isotransplantation. Orthotopic single left-sided lung allotransplantation (Wistar to Wistar) was performed in female rats after a total ischemic time of 18h. In nine recipients given 500mg/kg oral ebselen 1h before transplantation, graft PaO2/FiO2 was improved 24h after transplantation, as evidenced with a mean (standard deviation) PaO2 of 139 (61) mmHg vs. eight controls with 65 (33) mmHg (p=0.009). Bronchoalveolar PMN count was reduced to approximately 50% in the ebselen group compared with controls, whereas no difference in the tumor necrosis factor content was found. We conclude that the improvement of lung function in ebselen-treated transplanted rats is mainly the result of the anti-inflammatory activity of the drug during reperfusio