University of Würzburg

About: University of Würzburg is a education organization based out in Wurzburg, Bayern, Germany. It is known for research contribution in the topics: Population & Gene. The organization has 31437 authors who have published 62203 publications receiving 2337033 citations. The organization is also known as: Julius-Maximilians-Universität Würzburg & Würzburg University.

Temperature dependence of the exciton homogeneous linewidth in In 0.60 Ga 0.40 As/GaAs self-assembled quantum dots

Abstract: Single dot photoluminescence spectroscopy was used to study the homogeneous linewidth $\ensuremath{\Gamma}$ of the ground-state exciton in ${\mathrm{In}}_{0.60}{\mathrm{Ga}}_{0.40}\mathrm{As}/\mathrm{GaAs}$ quantum dots as function of temperature T. In high resolution experiments at 2 K, we find a linewidth that is limited by the excitonic lifetime corresponding to a dephasing time of almost a ns. The approximately linear increase of \ensuremath{\Gamma} with temperature up to $\ensuremath{\sim}30 \ensuremath{\mu}\mathrm{eV}$ at 60 K is considerably weaker than in structures of higher dimensionality. For higher T we observe a strong enhancement of the linewidth reaching eventually a few meV at room temperature that depends on the confined electronic shell structure.

Metallosupramolecular squares: from structure to function

Abstract: Metallosupramolecular squares have been successfully evolved over the past years as versatile substitutes of the conventional organic macrocycles owing to the development of reliable synthetic protocols and abundant structural variability (metals and ligands). In this review we have presented the fundamental aspects of metallosupramolecular squares such as the strategies for their construction (self-assembly vs. kinetically controlled macrocyclization) and characterization. The major emphasis of this tutorial review lies on the function of metallosupramolecular squares. Thus, the introduction of functionality into these systems has been discussed in detail by highlighting the recent progress toward application in various fields, including molecular recognition, enantioselective sensing, photoluminescence, redox activity and electrochemical sensing, and homogeneous catalysis.

Modulation of Associative Human Motor Cortical Plasticity by Attention

Abstract: The role of attention in generating motor memories remains controversial principally because it is difficult to separate the effects of attention from changes in kinematics of motor performance. We attempted to disentangle attention from performance effects by varying attention while plasticity was induced in human primary motor cortex by external stimulation in the absence of voluntary movement. A paired associative stimulation (PAS) protocol was employed consisting of repetitive application of single afferent electric stimuli, delivered to the right median nerve, paired with single-pulse transcranial magnetic stimulation (TMS) over the optimal site for activation of the right abductor pollicis brevis muscle (APB) to generate near-synchronous events in the left primary motor cortex. In experiment 1, the spatial location of attention was varied. PAS failed to induce plasticity when the subject's attention was directed to their left hand, away from the right target hand the cortical representation of which was being stimulated by PAS. In experiment 2, the grade of attention to the target hand was manipulated. PAS-induced plasticity was maximal when the subject viewed their target hand, and its magnitude was slightly reduced when the subject could only feel their hand. Conversely, plasticity was completely blocked when the subject's attention was diverted from the target hand by a competing cognitive task. A similar modulation by attention was observed for PAS-induced changes in the duration of the silent period evoked by TMS in voluntarily contracted muscle. Associative plasticity in the human motor cortex depends decisively on attention.

Measurement of the millisecond activation switch of G protein-coupled receptors in living cells.

Abstract: Hormones and neurotransmitters transduce signals through G protein-coupled receptors (GPCR). Despite their common signaling pathways, however, the responses they elicit have different temporal patterns. To reveal the molecular basis for these differences we have developed a generally applicable fluorescence-based technique for real-time monitoring of the activation switch of GPCRs in living cells. We used such direct measurements to investigate the activation of the alpha(2A)-adrenergic receptor (alpha(2A)AR; neurotransmitter) and the parathyroid hormone receptor (PTHR; hormone) and observed much faster kinetics than expected: approximately 40 ms for the alpha(2A)AR and approximately 1 s for the PTHR. The different switch times are in agreement with the different receptors' biological functions. Agonists and antagonists could rapidly switch the receptors on or off, whereas a partial agonist caused only a partial signal. This approach allows the comparison of agonist and partial agonist intrinsic activities at the receptor level and provides evidence for millisecond activation times of GPCRs.