1+1=3
Hypothesize there’s an extra 1 out there we don’t know about yet
Relentlessly test hypothesis for decades
Every test lines up with hypothesis
Relentlessly move humanity’s understanding of physics forward in a search for more information
Get made fun of by dumb fucks who struggle with division
Let’s pretend that you have a basket with 100 apples. You know apples are about 100g each, because you weighed 10 of the them and all of the apples seem about the same size. You know that basket weighs 1000g. You put the whole thing on a scale and find it weighs 500,000g. You know something else is in that basket. You aren’t sure what, and frankly it doesn’t make sense, but trying different scales and remeasuring more individual apples gives the same result. So you decide that there must be something you can’t see but must exist. That’s dark matter/energy.
Why isn’t it called “cold matter”?
Don’t we just not see it because it’s not burning?
Couldn’t the unseen mass be clouds, planets and black wholes?
No, because those would also interact with other things like electromagnetic radiation, light, etc. Dark matter only interacts with normal matter via gravity.
Dark matter is admittedly a bit of a misnomer but that’s what everyone’s been using for years 🤷🏻♂️
As far as we’re aware, dark matter only interacts with the universe gravitationally. It doesn’t even interact with itself, which is why we don’t see dark planets/stars/galaxies popping into existence. It only follows normal matter around.
As for why it’s not called cold, is for two reasons:
- Cold gases of normal matter can condense to form stars. Dark matter doesn’t interact with itself, which implies it cannot condense into more concentrated forms of itself the way a gas cloud can eventually form a star.
- We just don’t know what the stuff is, it could be clouds, planets, black holes, neutron stars, brown dwarfs, etc. But our best observations of dark matter are from very large distances away where we can measure the distortion of spacetime due to dark matter. We can’t see these smaller objects at these distances. But we should be able to see other clues that would indicate it’s normal matter.
If it happened to be clouds of gas and dust that overall had a net gravitational effect on the background galaxies, we’d be able to detect the spectral lines of these clouds. Same for just about all the other objects in that list. In some cases we do detect intergalactic gas clouds. But in places where there’s very clearly unaccounted for gravitational lensing, there isn’t any sign of this. So far the only things we can match up to the observations is a mathematical model of the stuff.
This is the most-tested, best-proven scientific theory humanity has known. For some reason, it completely breaks if you remove these Wingdings characters we added to the code.
Is this how dark matter works? (That’s the joke, right?)
Although we haven’t observed dark matter on a microscopic scale, we have been measuring the effects of dark matter on a macro level for decades.
