1,354,161 research outputs found

    On the nitrogen-induced far-infrared absorption spectra

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    The rototranslational absorption spectrum of gaseous N2 is analyzed, considering quadrupolar and hexadecapolar induction mechanisms. The available experimental data are accounted for by using a line-shape analysis in which empirical profiles describe the single-line translational profiles. We thus derive the simple procedure that allows one to predict the N2 spectrum at any temperature. On the basis of the results obtained for the pure gas, we also propose a procedure to compute the far-infrared spectrum of the N2–Ar gaseous mixture. The good agreement between computed and experimental N2–Ar data indicates that it is possible to predict the far-infrared absorption induced by N2 on the isotropic polarizability of any interacting partner

    Far infrared absorption of the gaseous CH4–Ar mixture

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    We present the first measurements of the rototranslational absorption spectrum of the CH4cm –Ar gaseous system in the far infrared region 40–600−1K at densities as low as possible; the binary absorption spectrum of the CH . Measurements were made at 296, 243, and 1954–Ar pair was then obtained. We performed a line-shape analysis of these spectra following the procedure previously introduced for pure methane. We find that the experimental data can be described at high frequencies by using ab initio values of the octopole and hexadecapole multipole moments and anisotropic overlap intensities very close to those used for pure methane. At low frequencies, the computed spectrum is significantly lower than the experimental data at any temperature. We thus include in our analysis a low-frequency spectral contribution associated with the isotropic overlap induction mechanism. Good fits of the experimental data are then obtain at each temperature over all the spectral range

    Enhancing the performances of a resonance detector spectrometer for deep inelastic neutron scattering measurements

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    The possibility is explored to sum up neutron Compton profiles at different scattering angles in deep inelastic neutron scattering measurements within the Resonance Detector (RD) configuration to enhance the statistics for a more reliable extraction of the momentum distribution of the constituents in the target. The RD configuration allows to select the energy of the scattered neutrons up to several tens of electron Volt, thus accessing energy and wave vector transfers well above 1 eV and 30 ˚A 1, respectively. In the high-q/o regime, the final state effects could be considered as negligible, as shown in a series of simulations using a Monte Carlo method with different inverse geometry instrument setups. The simulations show that it could be possible to conceive an instrument set up where the RD configuration allows the proper summation of several spectra at different scattering angles, providing a good separation of the proton recoil signal from that of the heavier atoms, thus avoiding the cell subtraction by fitting procedure

    New determination of the He-Xe gas-gas demixing surface in the high Xe concentration region

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    By analysing the results of a previous experimental work it has been found that the transition changes from a liquid-gas type at low pressure to a liquid-liquid one at high pressure. However, not much experimental data are available in the literature at high Xe concentrations, and some criticism can be applied to them. Therefore, new measurements of the isobaric coexistence curves for He-Xe mixtures at three pressures (80, 132, 200 atm) have been performed, with the use of a more precise technique, based on energy resolved neutron transmission measurements. A qualitative agreement with the previous data has been found, while a disagreement is present in the behaviour of T c versus p c, thus confirming our picture of a change in the nature of the transition as the pressure increase

    Temperature dependence of the dynamics of superoxide dismutase by quasi-elastic neutron scattering

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    The atomic dynamics of the enzyme Cu, Zn superoxide dismutase has been investigated by means of quasi-elastic neutron scattering in the temperature range 4-320 K and in an extended momentum range up to 8.5 Angstrom(-1). Below 200 K the integrated elastic scattering intensity can be well described by a quasi-harmonic model, while above this temperature a pronounced decrease of the elastic intensity is observed, together with the onset of a small quasi-elastic component. This behaviour, which is similar to that already observed in other globular proteins, can be attributed to the onset of torsional degrees of freedom which give rise to transitions between slightly different conformational substates of the protein tertiary structure

    A new precise determination of the liquid bromine structure by means of neutron diffraction

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    In this, paper we report a new accurate neutron diffraction measurement of the structure factor S(Q) of liquid,bromine at room temperature. A comparison has been made with molecular dynamics (MD) simulation data obtained by using a recent intermolecular potential. The agreement between the present data and the MD results turn out to be quite good, which is a strong indication that this is a satisfactory Potential model for liquid Br2 near the melting point, at least as far as the microscopic structure is concerned

    Quantum effects in the single particle kinetic energy of high density fluid <sup>4</sup>He

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    Deep inelastic neutron-scattering measurements have been performed in dense fluid 4He along three isochores at number densities 33, 38, and 45 nm-3 and temperatures ranging from 4.35 to 56 K. Data have been analyzed in the plane-wave impulse-approximation framework to obtain the root-mean-square values of the single-particle momentum along a given direction px. The density and temperature behavior of the derived mean kinetic energies is discussed in comparison with a simple harmonic model for the fluid and with quantum simulations performed using a path-integral Monte Carlo code. The comparison with the harmonic models sheds light on the density dependence of the zero-point kinetic energy of the particles and points out the inadequacy of a single-frequency Einstein-oscillator model in describing its temperature dependence. The quantum simulation results are in substantial agreement with the experimental data although systematic deviations are found as the density is increased

    Collision induced fundamental band of N2and N2-Ar mixtures

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    The roto-vibrational absorption band of N2 and N2-Ar mixtures at low density have been measured and the induced spectrum of the N2-Ar pairs has been obtained. The detailed analysis of this spectrum shows that the isotropic overlap contribution is negligible, while the quadrupolar one accounts for 80 per cent of the total intensity; the remaining 20 per cent of the intensity is attributed to anisotropic induction mechanisms with a shorter range than the quadrupolar one. In order to fit the experimental line-shape it has been necessary to take the dependence of the quadrupole transition moment on the rotational quantum numbers in account

    Deep inelastic neutron scattering off D<sub>2</sub> and H<sub>2</sub> and momentum distributions of nuclei in diatomic molecules

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    A quanto-mechanicla calculation for the description of neutron scattering at very high momentum transfer off both homonuclear and heteronuclear diatomic molecules
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