Momentum.

Normally we think of momentum as a property of mass. For low speed objects, momentum is the m*v, the mass times the velocity.

Which makes sense. A larger object going the same speed will hit harder. But also, the same object going faster will hit harder.

Momentum.

Whatever the momentum of the striking object, that gets transferred to the object being struck.

So if 2 kg of air molecules hits the ship sail going at 5 m/s, they give the ship 10 momentum units.

However, momentum gets weird when you get things going at or near the speed of light, or when things get smaller than atoms. (Technically the weirdness was always there, just too small to matter; but these are the situations where it does matter).

Now, let’s talk photons.

A photon has two properties – energy, and spin. Spin doesn’t matter for this, so we’ll ignore it. Energy determines everything else about the photon – with just the energy, you can calculate the momentum, the frequency, and the wavelength, each with a different formula.

For momentum, it’s e/c, the energy divided by the speed of light. The speed of light is 299,792,458 m/s, so a photon with 299,792,458 Joules of energy has 1 momentum unit.

To recap, that means a photon with 299,792,458 Joules will hit as hard as a 1 kg ball moving at 1 m/s.

This has the property that it adds nicely. Meaning if you hit an object with two 1-Joule photons, it’s the same as hitting with one 2-Joule photon. Meaning if you have all this energy you want to use to send photons, it’ll be the same whether you send as 1, or 1 million, or 1 googolplex photons, the effect is the same.

As to the energy photons have, well, they can have almost any energy. A red photon has 3*10^-19 Joules, and a blue photon has about 6*10^-19 Joules. The invisible ones flying through space (known as the CMB) have even less; meanwhile, x-rays have more, and some photons have even more. There’s not much to constrain what they can be other than “more than 0, less than infinity”.