15 research outputs found

    PHOTOABSORPTION UV SPECTROSCOPY OF X-B TRANSITION IN XcCI EXCIMER MOLECULE

    No full text
    Author Institution: Quantum systems Lab., Institute for Energy Problems of Chemical Physics.The excitation spectrum owing to XeCI(X,vB,v)XeCI(X,v\to B,v'), photoabsorption, and Xe+CIXeCI(B,v)Xe +CI \to XeCI(B,v), photoassociation, transitions was obtained for the first time in a wide spectral range (276-315 nm). Having been irradiated by the XcCI-cxcimer laser, to obtain Cl atoms, the mixture of Xe (1-4 atm) and C12 (0.5.3 forr) was exposed to the pulse of tunable dye laser second harmonic. The following fluorescence on XcCI(C-A) transition (350 nm) as well as from triatomic Xc2CI excimer molecule (490 nm), formed in secondary, XcCI + 2Xe - Xe2CI + Xc, reaction has been observed. The spectrum consists of v-bands (up to v=22v=22) with v* structure and the peaks positions are well-assigned with that observed in emission spectra. For the upper v values a pronounced isotopic. CI-CI, structure is clearly seen. The spectrum red wing, 310-315 nm, behavior shows some evidences for Xe2CI direct photochemical formation. The attempt to divide the contributions of photoabsorption and photoassociation proccsses has been undertaken and the estimate for the rate constant of photon-assisted two-body atomic recombination reaction has been accomplished. The spectrum obtained seems to be of interest for Franck-Condon factors calculations (since the populations of the initial XcCl(B,v) state v.J-sublvels being in equilibrium are well-determined) and for elucidation of the tunable XcCI-Iaser perspectives

    UV SPECTROSCOPIC STUDIES OF PHOTOEXCITATION TO XeCl(B) AND XeF(B) STATES

    No full text
    Author Institution: Institute for Energy Problems Of Chemical PhysicsThe Xecl(B) excitation spectrum resulting from photoabsorption, XeCl(B,vX,vB,v^{\prime} \leftarrow X, v^{\prime}), and photoassociation, Xe + ClXeCl(B,v)Cl \rightarrow XeCl(B,v^{\prime}), processes as well as the XeF(B) excitation spectrum are obtained over the spectral ranges of 276..315 nm and 335360335\ldots360 ran respectively. The double-pulse technique was applied, when the dissociation of halogen molecules by the pulse of the excimer XeCl-laser was followed by the delayed excitation pulse of the tunable dye laser. By measuring the XeCl(B) excitation Intensity dependences on Xe pressure with a dissociating pulse and in the absence of that the contribution Of photoassociative free-bound transitions was determined experimentally. Thus the rate constant of photoassociation, treated as a termolecular (two colliding atoms and a photon) process was estimated to be as high as 1.102810^{-28} cm8s1cm^{8} s^{-1} at the wavelength of 308 nm. The method for excitation spectrum calculations taking properly into account bound-bound and free-bound transitions contributions is developed. The XeCl(B) and XeF(B) excitation spectra are computed and for XeCl the absolute values of the photoabsorption cross- section and the photoassociation rate constant are calculated with at maxima at λ308^\lambda \approx 308 nm these values being 41.2.1016cm241.2.10^{-16} cm^{2} and 4.31028cm6s14.3\cdot 10^{-28} cm^{6} s^{-1} respectively

    Insulin receptor-related receptor as an extracellular alkali sensor

    Get PDF
    17sireservedThe insulin receptor-related receptor (IRR), an orphan receptor tyrosine kinase of the insulin receptor family, can be activated by alkaline media both in vitro and in vivo at pH >7.9. The alkali-sensing property of IRR is conserved in frog, mouse, and human. IRR activation is specific, dose-dependent and quickly reversible and demonstrates positive cooperativity. It also triggers receptor conformational changes and elicits intracellular signaling. The pH sensitivity of IRR is primarily defined by its L1F extracellular domains. IRR is predominantly expressed in organs that come in contact with mildly alkaline media. In particular, IRR is expressed in the cell subsets of the kidney that secrete bicarbonate into urine. Disruption of IRR in mice impairs the renal response to alkali loading attested by development of metabolic alkalosis and decreased urinary bicarbonate excretion in response to this challenge. We therefore postulate that IRR is an alkali sensor that functions in the kidney to manage metabolic bicarbonate excess.mixedDeyev, Igor E; Sohet, Fabien; Vassilenko, Konstantin P; Serova, Oxana V; Popova, Nadezhda V; Zozulya, Sergey A; Burova, Elena B; Houillier, Pascal; Rzhevsky, Dmitry I; Berchatova, Anastasija A; Murashev, Arkady N; Chugunov, Anton O; Efremov, Roman G; Nikol'Sky, Nikolai N; Bertelli, Eugenio; Eladari, Dominique; Petrenko, Alexander G.Deyev, Igor E; Sohet, Fabien; Vassilenko, Konstantin P; Serova, Oxana V; Popova, Nadezhda V; Zozulya, Sergey A; Burova, Elena B; Houillier, Pascal; Rzhevsky, Dmitry I; Berchatova, Anastasija A; Murashev, Arkady N; Chugunov, Anton O; Efremov, Roman G; Nikol'Sky, Nikolai N; Bertelli, Eugenio; Eladari, Dominique; Petrenko, Alexander G
    corecore