If you have a closed box with just a hand hole and you reach inside and what you feel there is just liquid at room temperature, can you say for sure that it is not solid steel? If you CAN say that (and I sure as heck can), HOW can you say that? After all you don't know for sure what's in the box, so what would you base any statement on?zuz said:Neil deGrasse Tyson states that "dark matter exerts gravity according to the same rules that ordinary matters follows" How do we know this? If we have no idea what dark matter is, how can we say how it behaves? How do we know that a single "molecule" of the stuff doesn't weigh as much as the sun? Or vise versa? Also, if it makes up 85% of the matter in the universe, shouldn't it be called "ordinary?"
Even if a single molecule of this "stuff" weighed as much as the Sun (effectively making it a black hole). The gravity it produces would be the same as the Sun. What he meant was that it's gravity would fall off by the square of the distance (not by the cube or some other value). It would still obey General relativity, etc.zuz said:Neil deGrasse Tyson states that "dark matter exerts gravity according to the same rules that ordinary matters follows" How do we know this? If we have no idea what dark matter is, how can we say how it behaves? How do we know that a single "molecule" of the stuff doesn't weigh as much as the sun? Or vise versa? Also, if it makes up 85% of the matter in the universe, shouldn't it be called "ordinary?"
I'm not sure this addresses the OP's question though.Janus said:Or put another way, if you were to squeeze the Sun down to the size of a single molecule, you would not be able to distinguish it gravitationally from a single particle of dark matter.
You have this backwards. We know where it is because of how its gravity falls off.zuz said:How do you know it's gravity would fall off at the square of it's distance when you don't know where it is or what form it takes?
When examining the idea of dark matter, there are two things to consider, Its effect on the orbits of the stars in the galaxy, and its effect on itself. When we assume that it behaves just like other matter gravitationally, everything "fits together". We can work out how it would naturally tend to form around the galaxy due gravity, and we can calculate what type of gravitational effect that distribution would have on the stars. Then we check this prediction against what we see the stars actually behaving.zuz said:How do you know it's gravity would fall off at the square of it's distance when you don't know where it is or what form it takes? Could it be somewhere else and actually be repulsive?
zuz said:Thank you. That almost makes sense to a layman like me. And please understand, I am just a layman. I'm just trying to understand what makes no sense to me
It isn’t a hidden premise. It is an up front very clear premise that everything (including dark matter) gravitates according to the normal laws of gravitation.Dr_Nate said:I think @zuz has an insightful question. We should ask ourselves: what hidden premises are we assuming when we make our models?
Yes, regular matter, including anti-matter, and dark matter all have gravity.alanpennock said:So..."if it walks like a duck and quacks like a duck ...it is a duck...If it looks like gravity and acts like gravity..it's gravity...OK so where does gravity come from? ...Matter...Oh and then there's antimatter...both matter ...does that mean both have gravity? Maybe so...I don't know!
Except gravitationally.alanpennock said:dark matter does not interact with matter and therefore does not? & cannot be detected.
I believe that Neil deGrasse Tyson's hidden premise in that statement would be something like: the observations that we label as being due to dark matter are due to matter particles. Thus the models he considers exclude things like modified Newtonian dynamics (MOND).Dale said:It isn’t a hidden premise. It is an up front very clear premise that everything (including dark matter) gravitates according to the normal laws of gravitation.
There are many detectors around the world trying to detect dark matter particles directly via some other assumed non-gravitational interaction. So far the evidence points to dark matter particles interacting only via gravity.alanpennock said:I would think so. anti-matter combines with matter and gives off gamma radiation, et. al. and can then be detected...dark matter does not interact with matter and therefore does not? & cannot be detected.
And you call that a “hidden premise”? Uh, ok.Dr_Nate said:the observations that we label as being due to dark matter are due to matter particles
Dark matter is a hypothetical type of matter that does not interact with light or other forms of electromagnetic radiation. It is believed to make up about 85% of the total matter in the universe. While its exact nature is still unknown, scientists believe that dark matter interacts with gravity, which is why it is often referred to as "dark matter gravity."
Scientists have observed the effects of dark matter through its gravitational influence on visible matter, such as stars and galaxies. They have also measured the rotation curves of galaxies and found that they cannot be explained by the amount of visible matter present, indicating the presence of an invisible mass, which is believed to be dark matter.
Dark matter cannot be directly detected because it does not interact with light. However, scientists are using various methods, such as gravitational lensing and particle accelerators, to indirectly detect and study dark matter.
Dark matter plays a crucial role in the expansion of the universe. It provides the necessary gravitational pull to counteract the expansion caused by dark energy, allowing galaxies and other structures to form and maintain their shape.
While scientists have observed the effects of dark matter gravity, its exact nature is still a subject of ongoing research and debate. Some theories suggest that dark matter is made up of particles that interact with gravity, while others propose modifications to the laws of gravity to explain the observed effects. Further research and observations are needed to fully understand the role of dark matter gravity in the universe.