Deducind thermodynamics from Quantum Physics and S>k

Thread starter Garrulo
Start date Jan 3, 2015
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Physics Quantum Quantum physics Thermodynamics

In summary, the relationship between thermodynamics and quantum physics is complex and involves deriving thermodynamic principles from underlying quantum mechanical principles. Quantum physics plays a crucial role in deducing thermodynamics by providing a deeper understanding of the behavior of matter and energy. The S>k principle, also known as the Second Law of Thermodynamics, can be deduced from quantum mechanics and states that entropy always increases over time. Statistical mechanics is used to bridge the gap between the microscopic and macroscopic scales in deducing thermodynamics from quantum physics. The concept of energy is central to both fields and understanding its relationship allows for a deeper understanding of energy transfer and conversion in thermodynamic processes.

Jan 3, 2015

Garrulo

How can deduced the four principles of thermodynamics from Quantum Physics and that the law that thermodynamics of a system is always greather than Boltzmann Constant K

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Jan 3, 2015

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You really are going to have to restate your question.

Garrulo said:

and that the law that thermodynamics of a system is always greather than Boltzmann Constant K

Some of it just does not make any sense in English.

Related to Deducind thermodynamics from Quantum Physics and S>k

1. What is the relationship between thermodynamics and quantum physics?

The relationship between thermodynamics and quantum physics is complex and still not fully understood. However, it is generally accepted that thermodynamic principles, such as the laws of thermodynamics, can be derived from the underlying quantum mechanical principles. This means that the behavior of macroscopic systems, such as heat transfer and energy conversion, can be explained by the microscopic behavior of particles at the quantum level.

2. How does quantum physics play a role in deducing thermodynamics?

Quantum physics plays a crucial role in deducing thermodynamics by providing a more fundamental understanding of the behavior of matter and energy. The laws of thermodynamics, which govern the behavior of macroscopic systems, can be derived from the principles of quantum mechanics. This allows for a deeper understanding of the underlying mechanisms behind thermodynamic processes.

3. What is the S>k principle in deducing thermodynamics from quantum physics?

The S>k principle, also known as the Second Law of Thermodynamics, states that in any natural process, the total entropy of a closed system will never decrease. In other words, the disorder or randomness of a system will always increase over time. This principle can be deduced from quantum mechanics, where entropy is related to the probability of a particular quantum state of a system.

4. What is the role of statistical mechanics in deducing thermodynamics from quantum physics?

Statistical mechanics is the branch of physics that deals with the behavior of large collections of particles. In deducing thermodynamics from quantum physics, statistical mechanics is used to bridge the gap between the microscopic and macroscopic scales. It provides a framework for understanding the relationship between the statistical behavior of particles at the quantum level and the overall thermodynamic behavior of a system.

5. How does the concept of energy relate to the deducing of thermodynamics from quantum physics?

The concept of energy is central to both thermodynamics and quantum physics. In thermodynamics, energy is a fundamental quantity that is conserved and can be converted between different forms. In quantum physics, energy is quantized and described in terms of discrete energy levels. The relationship between these two concepts is crucial in deducing thermodynamic principles from quantum mechanics, as it allows for a deeper understanding of energy transfer and conversion in thermodynamic processes.