Imagine taking the distance that light travels in an entire year. Now turn that distance into a cube, each side one light-year across. How much "stuff" would be in there? And how empty would it be? It all depends on where you put your massive cube.

Top image: Messier 15, an ancient globular cluster.

Even though the name is a little confusing, you probably already know that a light year is the distance that light travels in a full year. At speeds of almost 300,000 kilometers per second, that gets you pretty far from home.

So take that distance and turn it into a cube, each side one light year in length. Imagine that giant volume of space; it's a little challenging for some of us to get our heads around. How much "stuff" would be in there, and not just "stuff"â€¦ how much nothing is in there? There is an answer, but it all depends on the location of the giant cube.

Measure it at the core of the galaxy, and there are stars buzzing around all over the place. Perhaps in the heart of a globular cluster? In a star forming nebula? Or maybe out in the suburbs of the Milky Way? There's also great voids that exist between galaxies, where there's almost nothing.

The space between the galaxies is actually quite empty. Credit: ESO.

There's no getting around the math in this one. First, let's figure out an average density for the Milky Way and then go from there. Its about 100,000 light-years across and 1000 light-years thick. According to my buddy Phil Plait, the total volume of the Milky Way is about 8 trillion cubic light-years. And the total mass of the Milky Way is 6 x 10 to the power of 42 kilograms.

Divide those together and you get 8 x 10 to the power of 29 kilograms per light year. That's an 8 followed by 29 zeros. Is that a lot? It sounds like a lot.

Millions of glowing stars from the brightest part of the Milky Way â€” a region so dense with stars that barely any dark sky is seen across the picture. Credit: ESO.

Actually, that's about 40% of the mass of the Sun. In other words, on average, across the Milky Way, there's about 40% the mass of the Sun in every cubic light year. But in an average cubic meter, there's only about 950 attograms. Almost a femtogram; a quadrillionth of a gram of matter. Which is pretty close to nothing. Seriously, air has more than a kilogram of mass per cubic meter.