CorrespondencePrinciple - crowlogic/arb4j GitHub Wiki
The correspondence principle is a fundamental concept that connects the realms of classical physics and quantum mechanics. It states that the behavior of quantum systems must reduce to classical physics in the limit of large quantum numbers or when quantum effects become negligible. This ensures that classical physics is not contradicted by quantum mechanics but is instead a special case of it.
Here's how the correspondence principle applies to quantum field theory (QFT) and classical mechanics:
Quantum Mechanics to Classical Mechanics
In quantum mechanics, the wave function $\psi(x)$ describes the probability amplitude of a particle being found at position $x$. The expectation value of an observable $O$ is given by:
$$ \langle O \rangle = \int \psi^*(x) O \psi(x) ,dx $$
In the classical limit, where the action is much larger than Planck's constant $\hbar$, the wave function becomes sharply peaked around the classical trajectory, and quantum averages approach classical averages.
Quantum Field Theory to Classical Field Theory
In quantum field theory, fields are treated as operator-valued distributions, and particles are excitations of these fields. The correspondence principle in QFT can be understood through the coherent state representation.
A coherent state is a special quantum state that resembles a classical state as closely as possible. For a field $\phi(x)$, a coherent state $| \alpha \rangle$ is defined as an eigenstate of the annihilation operator $a$:
$$ a | \alpha \rangle = \alpha | \alpha \rangle $$
Here, $\alpha$ is a complex number related to the classical amplitude of the field.
In the limit of large occupation numbers (i.e., many particles), the quantum field theory described by coherent states approaches the classical field theory. The quantum fluctuations around the mean field value become negligible, and the field's behavior can be described using classical equations of motion.
Summary
The correspondence principle ensures that quantum mechanics, including quantum field theory, reduces to classical physics under appropriate conditions. It provides a bridge between the two realms, showing that classical physics is not contradicted but is a limiting case of the more general quantum description. This principle is essential for the consistency and continuity of our understanding of the physical world across different scales and energy regimes.