Gabriela Hoffman scite author profile

The self-diffusion coefficients D of compressed supercritical water have been measured as a function of pressure in the temperature range 400 to 700 °C using the NMR spin–echo technique. The experimental diffusion data were compared to theoretical predictions based on a dilute polar gas model using a Stockmayer potential for the evaluation of collision integrals and a temperature dependent hard sphere diameter. The empirical expression ρDαTn, where n = 0.76, fits the experimental data to within±10% over the entire density and temperature region studied. The value of the exponent n = 0.76 agrees favorably with the n values found for diffusion of other gases. The product ρD is density independent under isothermal conditions which indicates that two-body collisions dominate the diffusion behavior. This finding is in agreement with our earlier results for proton relaxation in compressed supercritical water which were analyzed using a binary collision approximation and a collision modulated spin–rotation interaction described by a single correlation function which is an exponential function of time. The hydrodynanic Stokes–Einstein equation appears to hold at densities above ρc. As expected, the diffusion data cannot be described in terms of a hard sphere model but an empirical fit to lnρD = (A/T)+B, where A and B are constants, represents the experimental data well over the range of temperatures and densities studied.

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A Solid‐State Intramolecular Wittig Reaction Enables Efficient Synthesis of Endofullerenes Including Ne@C₆₀, ³He@C₆₀, and HD@C₆₀

Hoffman

Walkey

Gräsvik

et al. 2021

Angew Chem Int Ed

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An open-cage fullerene incorporating phosphorous ylid and carbonyl group moieties on the rim of the orifice can be filled with gases (H 2 ,He, Ne) in the solid state,and the cage opening then contracted in situ by raising the temperature to complete an intramolecular Wittig reaction, trapping the atom or molecule inside.K nown transformations complete conversion of the product fullerene to C 60 containing the endohedral species.A sw ell as providing an improved synthesis of large quantities of 4 He@C 60 ,H 2 @C 60 ,and D 2 @C 60 ,the method allows the efficient incorporation of expensive gases such as HD and 3 He,t op repare HD@C 60 and 3 He@C 60 .T he method also enables the first synthesis of Ne@C 60 by molecular surgery,and its characterization by crystallography and 13 CNMR spectroscopy.

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Experimental determination of the interaction potential between a helium atom and the interior surface of a C60 fullerene molecule

Bacanu

Jafari

Aouane

et al. 2021

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The interactions between atoms and molecules may be described by a potential energy function of the nuclear coordinates. Nonbonded interactions between neutral atoms or molecules are dominated by repulsive forces at a short range and attractive dispersion forces at a medium range. Experimental data on the detailed interaction potentials for nonbonded interatomic and intermolecular forces are scarce. Here, we use terahertz spectroscopy and inelastic neutron scattering to determine the potential energy function for the nonbonded interaction between single He atoms and encapsulating C 60 fullerene cages in the helium endofullerenes 3 He@C 60 and 4 He@C 60 , synthesized by molecular surgery techniques. The experimentally derived potential is compared to estimates from quantum chemistry calculations and from sums of empirical two-body potentials.

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Synthesis of Ar@C₆₀ using molecular surgery

et al. 2020

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