A three-dimensional tunnel model for calculation of train-induced ground vibration

Vibration of a surface of a two-dimensional (2D) elastic layer generated by a point load moving uniformly along a beam, which is located inside the layer is investigated theoretically. It is supposed that the layer possesses a small viscosity, is "xed along the bottom, and has a traction-free surfac

This paper presents a validation of EnVib-01, an empirical model to predict train-induced ground vibrations in a preliminary design phase. The model is simple to use and gives a quick assessment of the magnitude and the distribution of the ground motion that can be expected in the vicinity of the tr

A semiclassical method is used to treat proton tunneling in a planar model of malonaldehyde. Classical trajectories were calculated on a realistic potential-energy surface and WKB tunneling probabilities were calculated at turning points on the barrier separating the two equivalent potential wells.

## 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.