Your search keyword '"H-2-at-C-60"' showing total 2 results

1. ENDOR Evidence of Electron–H2 Interaction in a Fulleride Embedding H2

Author

Marco Ruzzi, Marilena Di Valentin, Alfonso Zoleo, Nicholas J. Turro, Yasujiro Murata, Ronald G. Lawler, Koichi Komatsu, Xuegong Lei, and Yongjun Li

Subjects

Electron density, Fullerene, Chemistry, fullerene anions, General Chemistry, Electron, ENDOR spectroscopy, Biochemistry, Catalysis, Ion, Paramagnetism, Delocalized electron, Crystallography, Colloid and Surface Chemistry, Computational chemistry, ortho-H-2/para-H-2 interconversion, Physics::Atomic and Molecular Clusters, hyperfine coupling, Diamagnetism, Physics::Chemical Physics, H-2-at-C-60, Hyperfine structure

Abstract

An endofulleropyrrolidine, with H2 as a guest, has been reduced to a paramagnetic endofulleride radical anion. The magnetic interaction between the electron delocalized on the fullerene cage and the guest H2 has been probed by pulsed ENDOR. The experimental hyperfine couplings between the electron and the H2 guest were measured, and their values agree very well with DFT calculations. This agreement provides clear evidence of magnetic communication between the electron density of the fullerene host cage and H2 guest. The ortho-H2/para-H2 interconversion is revealed by temperature-dependent ENDOR measurements at low temperature. The conversion of the paramagnetic ortho-H2 to the diamagnetic para-H2 causes the ENDOR signal to decrease as the temperature is lowered due to the spin catalysis by the paramagnetic fullerene cage of the radical anion fulleride.

Published

2012

2. Nitroxide paramagnet-induced para-ortho conversion and nuclear spin relaxation of H2 in organic solvents

Author

Nicholas J. Turro, Ronald G. Lawler, Elena Sartori, and Marco Ruzzi

Subjects

Nitroxide mediated radical polymerization, Chemistry, para hydrogen conversion, Kinetics, Relaxation (NMR), pair correlation functions, exchange, free radicals, General Chemistry, Biochemistry, Catalysis, translation diffusion, solution NMR, H-2-at-C-60, Paramagnetism, Colloid and Surface Chemistry, Reaction rate constant, Nuclear magnetic resonance, Molecule, Physical chemistry, Physics::Chemical Physics, Spin (physics)

Abstract

The kinetics of para-ortho conversion and nuclear spin relaxation of H 2 in chloroform- d 1 were investigated in the presence of nitroxides as paramagnetic catalysts. The back conversion from para-hydrogen ( p-H 2) to ortho-hydrogen ( o-H 2) was followed by NMR by recording the increase in the intensity of the signal of o-H 2 at regular intervals of time. The nitroxides proved to be hundreds of times more effective at inducing relaxation among the spin levels of o-H 2 than they are in bringing about transitions between p-H 2 and the levels of o-H 2. The value of the encounter distance d between H 2 and the paramagnetic molecule, calculated from the experimental bimolecular conversion rate constant k 0, using the Wigner theory of para-ortho conversion, agrees perfectly with that calculated from the experimental relaxivity R 1 using the force free diffusion theory of spin-lattice relaxation.

Published

2008