Particles-on-a-sphere method for computing the rotational-vibrational spectrum of H2O

## Abstract A finite element method approach for solving the three‐dimensional Schrödinger equation expressed in hyperspherical coordinates is applied to the calculation of rovibrational states of H~2~O and D~2~O. Comparisons to experimental values and other theoretical calculations are offered.

We report accurate vibrational energy levels of H 2 O( X 1 A ) up to the dissociation limit on a recent ab initio potential energy surface of Partridge and Schwenke. Eigenvalues of the exact vibrational Hamiltonian in the Radau coordinates were obtained using the Lanczos algorithm. To improve comput

A previously dcveloprd method for generating the moments of the frequency spectra df cdbichtliozs is extended to amorphoos substimes. The extension invokes little approximation and allows one to calculate the moments in terms of the interatomic potent&4 function and low-order atomic distribution fu

The electoehemical behaviour for H,O, reduction at iron protoporphyrin modified pyrolytic graphite (FePP/PG) electrode has been studied by cyclic voltammetry and rotating disc electrode (rde). The peak potential (E,) of the catalytic wave at FePP/PG electrode in the presence of H,03 is more positive