The de Broglie hypothesis states that particles have wave-like properties, with a wavelength inversely proportional to their momentum.

The de Broglie hypothesis claims that all matter is made of waves.

The de Broglie hypothesis suggests that particles can exist in multiple places at once.

The de Broglie hypothesis states that light behaves like a particle only.

λ = h^2/p

λ = h/p

λ = p/h

λ = 2πh/p

λ = p / h

λ = h * p

λ = h + p

λ = h / p

Phase velocity is the speed of a single wave phase; group velocity is the speed of the wave packet's envelope.

Phase velocity and group velocity are the same and refer to the speed of light in a vacuum.

Phase velocity refers to the speed of sound in a medium; group velocity is irrelevant to wave motion.

Phase velocity is the speed of a wave packet; group velocity is the speed of a single wave phase.

Phase velocity is the same as group velocity.

Group velocity only applies to sound waves.

Phase velocity determines the energy of wave packets.

Phase velocity relates to individual wave components, while group velocity relates to the speed of wave packets.

The position of a particle can be known exactly without any uncertainty.

The product of the uncertainties in position and momentum of a particle is always greater than or equal to a constant (h/4π).

The uncertainties in position and momentum can be minimized to zero simultaneously.

The momentum of a particle is always constant regardless of its position.

Δx / Δp = h/4π

Δx * Δp ≥ h/4π

Δx * Δp = h

Δx + Δp = h/2π