1,100 research outputs found

    New World of Gossamer Superconductivity

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    Since the discovery of the high-Tc_{c} cuprate superconductor La2āˆ’x_{2-x}BaCuO4_{4} in 1986 by Bednorz and M\"{u}ller, controversy regarding the nature or origin of this remarkable superconductivity has continued. However, d-wave superconductivity in the hole-doped cuprates, arising due to the anti-paramagnon exchange, was established around 1994. More recently we have shown that the mean field theory, like the BCS theory of superconductivity and Landau's Fermi liquid theory are adequate to describe the cuprates. The keys for this development are the facts that a)the pseudogap phase is d-wave density wave (dDW) and that the high-Tc_{c} cuprate superconductivity is gossamer (i.e. it exists in the presence of dDW).Comment: 6 pages, 4 figure

    Higher lying resonances in low-energy electron scattering with carbon monoxide

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    R-matrix calculations on electron collisions with CO are reported whose aim is to identify any higher-lying resonances above the well-reported and lowest 2Ī  resonance at about 1.6 eV. Extensive tests with respect to basis sets, target models and scattering models are performed. The final results are reported for the larger cc-pVTZ basis set using a 50 state close-coupling (CC) calculation. The Breit-Wigner eigenphase sum and the time-delay methods are used to detect and fit any resonances. Both these methods find a very narrow 2Ī£+ symmetry Feshbach-type resonance very close to the target excitation threshold of the b 3Ī£+ state which lies at 12.9 eV in the calculations. This resonance is seen in the CC calculation using cc-pVTZ basis set while a CC calculation using the cc-pVDZ basis set does not produce this feature. The electronic structure of COāˆ’ is analysed in the asymptotic region; 45 molecular states are found to correlate with states dissociating to an anion and an atom. Electronic structure calculations are used to study the behaviour of these states at large internuclear separation. Quantitative results for the total, elastic and electronic excitation cross sections are also presented. The significance of these results for models of the observed dissociative electron attachment of CO in the 10 eV region is discussed

    Aspects of unconventional density waves

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    Recently many people discuss unconventional density waves (i.e. unconventional charge density waves (UCDW) and unconventional spin density waves (USDW)). Unlike in conventional density waves, the quasiparticle spectrum in these systems is gapless. Also these systems remain metallic. Indeed it appears that there are many candidates for UDW. The low temperature phase of alpha-(BEDT-TTF)_2KHg(SCN)_4, the antiferromagnetic phase in URu_2Si_2, the CDW in transition metal dichalcogenite NbSe_2, the pseudogap phase in high T_c cuprate superconductors, the glassy phase in organic superconductor kappa-(BEDT-TTF)_2Cu[N(CN)_2]Br. After a brief introduction on UCDW and USDW, we shall discuss some of the above systems, where we believe we have evidence for unconventional density waves.Comment: 11 pages, 5 figure

    Protocol optimisation for a fluorescent nitric oxide indicator in rat mesenteric arteries ex vivo

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    Quenching through Dirac and semi-Dirac points in optical Lattices: Kibble-Zurek scaling for anisotropic Quantum-Critical systems

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    We propose that Kibble-Zurek scaling can be studied in optical lattices by creating geometries that support, Dirac, Semi-Dirac and Quadratic Band Crossings. On a Honeycomb lattice with fermions, as a staggered on-site potential is varied through zero, the system crosses the gapless Dirac points, and we show that the density of defects created scales as 1/Ļ„1/\tau, where Ļ„\tau is the inverse rate of change of the potential, in agreement with the Kibble-Zurek relation. We generalize the result for a passage through a semi-Dirac point in dd dimensions, in which spectrum is linear in mm parallel directions and quadratic in rest of the perpendicular (dāˆ’m)(d-m) directions. We find that the defect density is given by 1/Ļ„mĪ½āˆ£āˆ£zāˆ£āˆ£+(dāˆ’m)Ī½āŠ„zāŠ„ 1 /{\tau^{m\nu_{||}z_{||}+(d-m)\nu_{\perp}z_{\perp}}} where Ī½āˆ£āˆ£,zāˆ£āˆ£\nu_{||}, z_{||} and Ī½āŠ„,zāŠ„\nu_{\perp},z_{\perp} are the dynamical exponents and the correlation length exponents along the parallel and perpendicular directions, respectively. The scaling relations are also generalized to the case of non-linear quenching

    Integration v. Polarization Amongst Social Media Users: Perspectives through Social Capital Theory

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    There has been a growing debate about the extent to which social media has influenced the Arab Worldā€™s recent revolutions described as the ā€œArab Springā€. Despite difference in views concerning this issue, the role that social media played in enacting socio-political change is undeniable, a matter which attracted the interest of academia. Here, the power of social media in widening and strengthening relationships renovated and reinforced the concept of ā€œsocial capitalā€, which could lead to integration or acculturation amongst affected societies. Underpinned by a social capital theory and the acculturation process, this commentary article adopts a critical approach and draws on historical events from the 2011 Egyptian revolution and beyond. We claim that, social media lead to social capital creation and integration when some fundamental associated factors exist namely: the bonding, bridging and linking factors. Social media adoption lead to political integration when these factors existed during the Egyptian revolution and lead to polarisation when there was no contextual triggering factor before the revolution and no access to resources after the revolution. We provide some insightful perspectives on the role of social media in social-political change

    Electron-phonon interaction in a local region

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    The paper reports on a study of electron-phonon interaction within a limited nanosized region. We invoked the modified Fr\"{o}hlich's Hamiltonian to calculate the electron self-energy, as well as the elastic and inelastic scattering cross sections. New effects have been revealed, more specifically: a bound state forms within the limited nanosized region, electrons undergo resonant elastic scattering, with strong inelastic scattering being possible from this state even at low electron energies. The effect of scattering on the magnetic-field-independent dephasing time, in particular, in a diamond-decorated carbon nanotube, has been determined. The effect of strong inelastic electron scattering on thermal resistance at the metal-insulator interface is discussed.Comment: 13 pages, 2 figure

    Low energy inelastic electron scattering from carbon monoxide: I. Excitation of the aĀ³ Ī , a'Ā³ Ī£ āŗ and AĀ¹ Ī  electronic states

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    Differential scattering cross sections for electron excitation of the three lowest excited electron states of carbon monoxide are obtained experimentally using low-energy electron energy-loss spectroscopy and theoretically using the R-matrix method. The incident electron energies range from near-threshold of 6.3 eV to 20 eV. Experimental scattering angles range from 20Ā° to 120Ā°. The normalization of the experimental cross sections is made to available experimental elastic scattering data (Gibson et al 1996 J. Phys. B: At. Mol. Opt. Phys. 29 3197). The R-matrix calculations use three distinct close-coupling models and their results are compared to available experimental and theoretical cross sections. The overall comparison leads to significantly improved description of the excitation cross sections for this target
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