• The strength of the vibration is the amplitude.
• How often the vibration occurs is the frequency.
• The distance the wave has traveled between maximums is the wavelength.
• Since a given wave propagates at a set velocity through a material, if you increase the wave's frequency, the distance between crests drops (a decrease in wavelength). Mathematically, wave speed = frequency x wavelength , so for a constant wave speed, frequency and wavelength are inversely related.
• One of the most interesting property of waves is that when two waves pass through each other, their effects are added together. This is called interference.

There are many more wave properties we can't get into for lack of space.

It turns out that if you repeat the same experiment using a particle beam instead of a light source, you record a similar interference pattern. This means that all particles have wave properties. For example, here's a real interference pattern caused by an electrons scattering off gold foil:

It is a very strange concept that what we think of as solid matter particles are, in reality, wave-like because matter particles have frequency, wavelength, and can interfere with each other. It is important to note that sub-atomic particles' wavelengths are not due to the particles "jiggling" around; rather, the particles' properties phase in and out. For example, a light particle (the photon) is a wave because its electromagnetic field phases from one sign to the other.