This book presents a systematic and coherent approach to phase transitions and critical phenomena, namely the coherent-anomaly method (CAM theory) based on cluster mean-field approximations. The first part gives a brief review of the CAM theory and the second part a collection of reprints covering the CAM basic calculations, the Blume–Emery–Griffiths model, the extended Baxter model, the quantum Heisenberg model, zero-temperature phase transitions, the KT-transition, spin glasses, the self-avoiding walk, contact processes, branching processes, the gas–liquid transition and even non-equilibrium phase transitions.Contents: Introduction to Phase TransitionsBasic Scheme of the CAM TheoryExtensions of Mean-Field ApproximationsNon-Universal Critical PhenomenaSpin GlassesCAM in Quantum Spin SystemsPercolation, SAW and DLAStochastic ProcessesReadership: Graduate students in materials science, mathematical physics, statistical mechanics and statistical physics.Key Features:Explains the role of projects network as focal points of knowledge creation and integration and also in cross-related collaborationCovers the distinctive challenges of managing through dynamic projects network in high-tech companiesFocuses on knowledge creation through managing abrasion and conflict between projects in a large corporation