jrrship said:has thermodyamics been unified with QM?
i thought that thermodyanimcs arises because of things that happen on the quantum level.
for instance, as time's arrow been unified with QM or SR or GR? What does ST or LQG say about time's arrow?
Nancarrow said:I think you may be pining for http://en.wikipedia.org/wiki/Statistical_mechanics" . AFAIRemember, the increase of entropy is explained as a movement from a low-probability state to a higher-probability state.
So imagine a gas in a box, and think about the positions and momenta of all the particles at any given moment - this is a certain state, a point in a hugely-dimensional 'phase space', and the point wanders around exploring this phase space in a seemingly random walk. Within the phase space, there's a tiny volume corresponding to having all the particles in one half of the box, and a huge volume corresponding to having the particles evenly distributed throughout the entire box.
So if the box starts off partitioned, with all of the gas in one half, and we then release the partition, the gas spreads out because that's the overwhelmingly most probable thing for it to do.
hope that helps
The main goal of unifying thermodynamics with quantum mechanics is to develop a theory that can explain the behavior of both macroscopic and microscopic systems. Thermodynamics deals with the macroscopic behavior of systems, while quantum mechanics deals with the microscopic behavior. By combining these two theories, scientists hope to gain a better understanding of the fundamental laws that govern the behavior of matter and energy.
Quantum mechanics has a significant impact on thermodynamics because it allows for a more detailed understanding of the behavior of matter and energy at the microscopic level. It provides a more accurate description of the behavior of individual particles, which can then be applied to larger systems described by thermodynamics.
One of the main challenges in unifying thermodynamics with quantum mechanics is reconciling the different scales and levels of description that these two theories operate on. Thermodynamics deals with large numbers of particles and macroscopic behavior, while quantum mechanics deals with individual particles and microscopic behavior. Finding a way to bridge these two scales is a major challenge for scientists.
The unification of thermodynamics and quantum mechanics has the potential to significantly advance our understanding of energy. It can provide a more comprehensive understanding of how energy is transferred, transformed, and conserved in different systems. It could also lead to new technologies and applications related to energy production and storage.
The potential applications of combining thermodynamics with quantum mechanics are vast and far-reaching. It could lead to the development of more efficient energy systems, improved materials design, and a better understanding of complex systems such as living organisms. It could also have implications for fields such as cryptography, computation, and information theory.