Review Category: Computational Methods in Radiation Physics Introduction: Computational methods have revolutionized the field of radiation physics by providing accurate and efficient ways to simulate complex phenomena. Monte Carlo (MC) techniques are one such method that has gained significant attention due to their ability to model particle transport accurately. In this review, we will discuss various MC methods for particle transport in radiation physics, including their applications and limitations. Monte Carlo Methods for Particle Transport: The most common application of MC methods is in the simulation of particle transport. These methods use random sampling techniques to simulate the motion of particles through a medium. Monte Carlo simulations can be used to model various types of radiation, such as neutrons, photons, and electrons. The accuracy of these simulations depends on several factors, including the size and shape of the medium, the type of radiation being simulated, and the number of particles used in the simulation. Monte Carlo Methods for Radiation Transport: Fundamentals and Advanced Topics (Biological and Medical Physics, Biomedical Engineering): This book provides a comprehensive overview of MC methods for radiation transport. It covers both fundamental concepts and advanced topics related to particle transport in biological and medical systems. The book includes chapters on various types of radiation, including neutrons, photons, and electrons, as well as their interactions with matter. Additionally, the book discusses applications of MC simulations in biomedical engineering, such as in the design of radiation therapy devices. Monte Carlo Particle Transport Methods: Neutron and Photon Calculations: This book focuses specifically on neutron and photon transport using MC methods. It covers both fundamental concepts and advanced topics related to particle transport in various media, including water, air, and tissue. The book includes chapters on radiation detection and measurement techniques, as well as applications of MC simulations in nuclear reactor design and safety analysis. Monte Carlo Particle Transport Methods: This book provides an introduction to MC methods for particle transport. It covers both fundamental concepts and practical applications of these methods. The book includes chapters on various types of radiation, including neutrons, photons, and electrons, as well as their interactions with matter. Additionally, the book discusses applications of MC simulations in materials science and engineering. Monte Carlo Techniques in Radiation Therapy (Imaging in Medical Diagnosis and Therapy): This book focuses specifically on the application of MC methods in radiation therapy. It covers both fundamental concepts and advanced topics related to particle transport in biological systems, including tumor modeling and treatment planning. The book includes chapters on various types of radiation, including photons and electrons, as well as their interactions with matter. Additionally, the book discusses applications of MC simulations in imaging techniques for medical diagnosis and therapy. The Wigner Monte Carlo Method for Nanoelectronic Devices: A Particle Description of Quantum Transport and Decoherence: This book provides an introduction to the Wigner Monte Carlo method for simulating quantum transport in nanoelectronic devices. The method is based on the concept of wave-particle duality, which allows for a particle description of quantum transport while also accounting for the effects of decoherence and other environmental factors. The book includes chapters on various types of nanoelectronic devices, including semiconductors and superconducting circuits, as well as applications of MC simulations in device design and optimization. A Monte Carlo Primer: A Practical Approach to Radiation Transport: This book provides a practical introduction to MC methods for radiation transport. It covers both fundamental concepts and advanced topics related to particle transport in various media, including water, air, and tissue. The book includes chapters on radiation detection and measurement techniques, as well as applications of MC simulations in nuclear reactor design and safety analysis. Additionally, the book provides practical guidance on how to implement MC simulations using software packages such as GEANT4 and MCNP. Particle-Transport Simulation With the Monte Carlo Method (Erda Critical Review Series): This book provides a comprehensive overview of particle transport simulation using MC methods. It covers both fundamental concepts and advanced topics related to particle transport in various media, including water, air, and tissue. The book includes chapters on radiation detection and measurement techniques, as well as applications of MC simulations in nuclear reactor design and safety analysis. Additionally, the book discusses recent developments in MC simulation techniques, such as hybrid methods that combine MC with other computational approaches. Computational Methods for Two-Phase Flow and Particle Transport: This book provides an introduction to computational methods for simulating two-phase flow and particle transport. It covers both fundamental concepts and practical applications of these methods in various industries, including oil and gas, mining, and chemical processing. The book includes chapters on various types of fluids, including water, air, and gases, as well as their interactions with particles and other solid objects. Additionally, the book discusses recent developments in computational fluid dynamics (CFD) techniques for simulating two-phase flow. Advanced Monte Carlo for Radiation Physics: This book provides an advanced treatment of MC methods for radiation physics. It covers both fundamental concepts and advanced topics related to particle transport in various media, including water, air, and tissue. The book includes chapters on radiation detection and measurement techniques, as well as applications of MC simulations in nuclear reactor design and safety analysis. Additionally, the book discusses recent developments in MC simulation techniques, such as hybrid methods that combine MC with other computational approaches. Particle Transport Simulation and Applications: Proceedings of the Monte Carlo 2000 Conference, Lisbon, 23–26 October 2000: This book provides a collection of papers presented at the Monte Carlo 2000 conference on particle transport simulation. The conference covered various topics related to MC methods for radiation physics, including applications in nuclear reactor design and safety analysis, as well as recent developments in MC simulation techniques. The book includes chapters on both fundamental concepts and advanced topics related to particle transport in various media, including water, air, and tissue. Conclusion: MC methods have revolutionized the field of radiation physics by providing accurate and efficient ways to simulate complex phenomena. These methods can be used to model various types of radiation, such as neutrons, photons, and electrons, and their interactions with matter. The accuracy of these simulations depends on several factors, including the size and shape of the medium, the type of radiation being simulated, and the number of particles used in the simulation. MC methods have numerous applications in various industries, including nuclear reactor design and safety analysis, as well as biomedical engineering and materials science.