Quantum Harmonic Oscillator Concepts

Classical oscillators are based on Hooke's law, while quantum oscillators are not.

Quantum oscillators have no potential energy, unlike classical oscillators.

Classical oscillators deal with macroscopic systems, while quantum oscillators deal with subatomic particles.

Classical oscillators can only exist at absolute zero temperature.

The time evolution of a wavefunction

The position of a particle in a quantum system

The potential energy of a system

The velocity of a particle

Fourier series

Hermite polynomials

Laplace transforms

Taylor series

It would violate the conservation of energy.

It would imply negative probabilities.

It would make the wavefunction non-normalizable.

It would make the wavefunction non-differentiable.

They determine the time evolution of the system.

They are the solutions to the differential equation.

They provide the normalization factor.

They describe the potential energy curve.

It is negative, representing a bound state.

It is infinite, due to quantum fluctuations.

It is non-zero, indicating zero-point energy.

It is always zero, similar to classical systems.

Quantum eigenenergy is always higher.

Quantum eigenenergy is always lower.

Quantum eigenenergy is non-zero even at the ground state.

Quantum eigenenergy is zero at the ground state.

A state with maximum entropy

A state with undefined position

A state with a definite energy

A state with zero energy

It ensures the wavefunction is differentiable.

It ensures the wavefunction is integrable.

It ensures the total probability is one.

It ensures the wavefunction is continuous.

The ground state energy is directly proportional to mass.

The ground state energy is inversely proportional to mass.

The ground state energy is independent of mass.

The ground state energy is proportional to the square of the mass.