Statistical physics is one of the fundamental theories of physics, and uses methods of statistics in solving physical problems. It can describe a wide variety of fields with an inherently stochastic nature. Examples include problems involving nuclear reactions, and topics in the fields of biology, chemistry, neurology and even some social sciences such as sociology.
The term "statistical physics" encompasses probabilistic and statistical approaches to classical mechanics and quantum mechanics. Statistical mechanics is then often used as a synonym. When the context requires a distinction, one uses the terms classical statistical mechanics and quantum statistical mechanics.
A statistical approach can work well in classical systems when the number of degrees of freedom (and so the number of variables) is so large that exact solution is not possible, or not really useful. Statistical mechanics can also describe work in non-linear dynamics, chaos theory, thermal physics, fluid dynamics (particularly at high Knudsen numbers), or plasma physics.
Although some problems in statistical physics can be solved analytically using approximations and expansions, most current research utilizes the large processing power of modern computers to simulate or approximate solutions. A common approach to statistical problems is to use a Monte Carlo simulation to yield insight into the dynamics of a complex system.
New Statistical Physics Study Findings Have Been Reported from Memorial Sloan-Kettering Cancer Center.(Report)
Aug 30, 2011; "The emergent spatial patterns generated by growing bacterial colonies have been the focus of intense study in physics during the...