In the second half a thorough understanding of quantum mechanics is assumed with the Schrödinger equation being treated with scattering and bound state conditions. The time-dependent Schrödinger equation is also solved. A thorough introduction to the solution of the quantum-mechanical bound state with variational and Monte Carlo Green's function is given, with two examples being the solution of the bound state nuclear helium 4 and the energy of atomic liquid helium 4 at zero temperature. The exact solution of the low energy scattering problem is presented. Algorithms for the Borel and Pade methods for the summation of divergent series are studied. In the final chapter, methods for the solution of hadronic scattering from nuclei are treated including single, double and multiple scattering as well as the derivation and calculation of multiple scattering through fundamental optical models.

The first half of the book will be suitable for a general course in computational methods while the second half can serve as a second semester course for Physics majors intending to do work in hadronic physics or scattering.

Contents:

• Integration
• Introduction to Monte Carlo
• Differential Methods
• Computers for Physicists
• Linear Algebra
• Exercises in Monte Carlo
• Finite Element Methods
• Digital Signal Processing
• Chaos
• The Schrödinger Equation
• The N-Body Ground State
• Divergent Series
• Scattering in the N-Body System

"Computation in Modern Physics is a good reference ... for students of computational physics ... valuable as an update to advanced quantum-mechanics texts or for advanced projects in a computational physics course."