Operators and Observables
Definition
Def Operator Operators are mathematical entities used to represent physical processes that result in the change of the state vector of the system, such as the evolution of these states with time.
Observable
An observable is a physical property or physical quantity that can be measured. Observables manifest as linear Hermitian operators in the quantum state space.
Expectation Value of Operator
Given some operator
, the expectation value is then given by
Hamiltonian Operator
The Hamiltonian operator is
Thus the TISE reduces to
Energy Eigenstate
An energy eigenstate is a quantum state where all observables (such as position, velocity, and spin) are independent of time. It is an eigenvector of the energy operator (Hamiltonian), meaning that it corresponds to a specific energy value (the eigenvalue) rather than a superposition of different energies. Formally,
is an energy eigenstate if
The Momentum Operator
Kinetic Energy Operator
The kinetic energy operator is
Momentum Operator
The momentum operator can be reduced from the kinetic energy operator:
Proposition
Prop The free particle has a definite momentum. Proof Let a free particle have
. Then yielding a definite momentum .
Time Dependent States
Def Energy Probability Amplitudes Energy probability amplitudes are the
Proposition
Prop The mean energy can be obtained by
Proof As , we can easily derive the above equation.
Ehrenfest’s Theorem
Ehrenfest's Theorem
Expectation or mean values of observables in quantum mechanics should obey the same relations as their classical counterparts.
e.g. We can easily prove that
Bohr's Correspondence Principle
Tending towards a Newtonian universe, one in which
. Like in Relativity where the scale is the speed of light, the scale in quantum mechanics is , so if , then every length scale is large and the universe is classical.