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- Temperature dependence of IR exciton emission spectra in Müller cell intermediate filamentsPublication . Khmelinskii, Igor; Makarov, Vladimir I.Temperature dependences of IR exciton properties in Muller cell (MC) intermediate filaments (IFs) isolated from porcine retina were studied. It was found that the widths of the spectral emission bands in the 2500 cm-1 and 5000 cm-1 energy ranges grow with temperature. It was found that temperature effects on the bandwidth may be described by thermal activation of the low-frequency vibrational modes of the IFs. The average activation energies for the two IR bands were estimated. Considering the dynamics of IR emission, its buildup time was independent on the sample temperature, while its decay time decreased with temperature. Thus, the emission decay rate increased exponentially with the sample temperature. The mechanisms explaining the observed temperature effects were proposed and discussed. Taking into account that MC IFs are capable of transmitting ATP hydrolysis energy within and between cells, with these properties being apparently common for all IFs, these IFs may be used by cells for physical energy transport and communications. As presently reported, temperature effects upon IR exciton spectra should not affect these proposed physiological functions to any significant extent. Therefore, the currently reported data are important for improving our understanding of the physical communication mechanisms operating within and between cells.
- Quantum confinement in multi-nanolayer sandwich systemsPublication . Khmelinskii, Igor; Makarov, Vladimir I.Presently we explored quantum confinement (QC) in three-nanolayer sandwich systems, composed of Au-SnO2-Fe, Au-SnO2-Si and Au-SnO2-Ag layers. We recorded the absorption spectra of these sandwich systems, all with discrete structure. We recorded the action spectra of the photocurrent for the Au-SnO2-Fe sandwich system, with the photocurrent quantum yields increasing with the photon energy, achieving 3.1 at 4.7 x 10(4) cm(-1). The photocurrent action spectra correlate with high accuracy with optical absorption spectra. We discuss the mechanisms determining the absorption bandwidth value, including surface imperfections, thermal distribution of the vibrational level populations in the electronic ground state, and the diabatic coupling of levels of the excited state to those of a "dark" state. Volt-Ampere (V/A) characteristics were recorded for all three of the sandwich systems, quite similar to those of a Schottky diode. We report the parameter values of the V/A characteristics, found by fitting the experimental data with a theoretical curve. We also report charge density changes in the SnO2 layer caused by low constant voltage applied to the sandwich structure, observed as changes in the absorption band intensity.
- Superluminescence and macroscopic exciton propagation in freestanding ZnO thin filmsPublication . Khmelinskii, Igor; Makarov, Vladimir, IRecently we have reported properties of ZnO semiconductor films attached to CaF2 substrate. Presently we characterized absorption, emission and superluminescence of freestanding ZnO films, comparing these to the attached films with the same thickness values. The absorption spectra of the freestanding films had resolved bands, with the band density increasing with the nanofilm thickness. Additionally, the spectral transitions in these films were blue-shifted as compared to attached films. The absorption and emission spectra of freestanding films were resolved better than those of attached films, with the difference traceable to the surface roughness of the substrate used for deposition. We also explored exciton dynamics and propagation over macroscopic distances in freestanding films. The excitons lived longer and propagated further in freestanding films as compared to attached films. The superluminescence yield in freestanding 9.3 nm film of 0.43 +/- 0.05 was significantly larger than 0.17 +/- 0.03 in an equivalent attached film. We provided a detailed analysis of the results obtained. The reported data are unique, demonstrating significant difference in the optical properties of attached and freestanding ZnO thin films. Freestanding ZnO films are promising for optoelectmnic applications.