Basic tools of econophysics are
probabilistic and
statistical methods often taken from statistical physics. Physics models that have been applied in economics include the
kinetic theory of gas (called the
kinetic exchange models of markets),
percolation models,
chaotic models developed to study cardiac arrest, and models with
self-organizing criticality as well as other models developed for
earthquake prediction. Moreover, there have been attempts to use the mathematical theory of
complexity and
information theory, as developed by many scientists among whom are
Murray Gell-Mann and
Claude E. Shannon, respectively. For
potential games, it has been shown that an emergence-producing equilibrium based on information via Shannon information entropy produces the same equilibrium measure (
Gibbs measure from statistical mechanics) as a stochastic dynamical equation which represents noisy decisions, both of which are based on
bounded rationality models used by economists. The
fluctuation-dissipation theorem connects the two to establish a concrete correspondence of "temperature", "entropy", "free potential/energy", and other physics notions to an economics system. The statistical mechanics model is not constructed a-priori - it is a result of a boundedly rational assumption and modeling on existing neoclassical models. It has been used to prove the "inevitability of collusion" result of
Huw Dixon in a case for which the neoclassical version of the model does not predict collusion. Here the demand is increasing, as with
Veblen goods, stock buyers with the
"hot hand" fallacy preferring to buy more successful stocks and sell those that are less successful, or among short traders during a
short squeeze as occurred with the
WallStreetBets group's collusion to
drive up GameStop stock price in 2021. Nobel laureate and founder of experimental economics
Vernon L. Smith has used econophysics to model sociability via implementation of ideas in Humanomics. There, noisy decision making and interaction parameters that facilitate the social action responses of reward and punishment result in
spin glass models identical to those in physics. Quantifiers derived from
information theory were used in several papers by econophysicist Aurelio F. Bariviera and coauthors in order to assess the degree in the informational efficiency of stock markets. Zunino et al. use an innovative statistical tool in the financial literature: the complexity-entropy causality plane. This Cartesian representation establish an efficiency ranking of different markets and distinguish different bond market dynamics. It was found that more developed countries have stock markets with higher entropy and lower complexity, while those markets from emerging countries have lower entropy and higher complexity. Moreover, the authors conclude that the classification derived from the complexity-entropy causality plane is consistent with the qualifications assigned by major rating companies to the sovereign instruments. A similar study developed by Bariviera et al. explore the relationship between credit ratings and informational efficiency of a sample of corporate bonds of US oil and energy companies using also the complexity–entropy causality plane. They find that this classification agrees with the credit ratings assigned by Moody's. Another good example is
random matrix theory, which can be used to identify the noise in financial correlation matrices. One paper has argued that this technique can improve the performance of portfolios, e.g., in applied in
portfolio optimization. The ideology of econophysics is embodied in the probabilistic economic theory and, on its basis, in the unified market theory. There are also analogies between finance theory and
diffusion theory. For instance, the
Black–Scholes equation for
option pricing is a
diffusion-
advection equation (see however for a critique of the Black–Scholes methodology). The Black–Scholes theory can be extended to provide an analytical theory of main factors in economic activities. The majority of the population (approx. 97%) follows a Boltzmann-Gibbs exponential distribution, characteristic of thermodynamic equilibrium where wealth is conserved. In contrast, the top tier (approx. 3%) follows a Pareto power law, driven by multiplicative capital returns. This distinction suggests that different mechanisms govern the wealth accumulation of the working class (additive) versus the wealthy (multiplicative). == Subfields ==