Possibly. According to this article https://www.forbes.com/sites/startswithabang/2020/02/15/ask-ethan-could-gravitational-waves-ever-cause-damage-on-earth.

I want to add on to this question - would the answer to the above be different if the black hole had no accretion disk?

I did the math a while back- you have to be crazy close, like 100s of km, to a merger for the gravity waves to affect you directly. /u/StandardSudden1283 Even a 'cold' pair of BHs (no accretion disk) would kill you from tidal forces at a much greater distance.

The article/u/kanrith links to suggests the waves could cause earthquakes or something on the planet you're on, and so indirectly hurt you, but its not verry convincing.

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In an expanding universe things like distance and speed become ambiguous at large distances, with several sensible definitions that all give the same results under normal circumstances suddenly disagreeing. When it comes to distance, this is due to the expansion of space changing the scale of the universe while light is traveling towards us, so effectively changing things in the middle of our measurement. When it comes to speed, it is due to the difference between things moving apart because of their own motion, or things moving apart because new space appeared between them.

As a rough analogy for the former, imagine two ants separated by a piece of string they can walk along, but they're currently standing still. Now someone cuts the string and splices in a much longer piece of string between the ants. The ants didn't move, but now the distance between them (along the string = through space, in this analogy) is much longer. Does that mean the ants had a huge relative velocity when the splicing took place?

It's up to you, really, but I think most of us would prefer to factor out the expansion part and only include the moving part in the definition of velocity. In cosmology, this definition of speed is called peculiar velocity, and would not be particularly lage for two objects on opposite sides of the observable universe.

All of these complications go away if you only look at nearby objects. It's relative speed between two objects close to each other that's limited to 299792 km/s.

Firstly, 8±3 doesn't mean "it's definitely between 5 and 11". It just means "it's 68% likely that it's in that range", and then it's 95% likely that it's in the range [2:14] and 99.7% likely that it's in the range [-1:17] (really [0:17] in this case, since it can't be negative).

Secondly, why do I say that it's likely to be lower than 8% rather than higher, given that the error bars go both up and down? That's because we're looking at extreme value statistics. Put simply, we're not looking at a random data point, we're looking at the data point with the highest value. That means we're much more likely to see a positive noise fluctuation than a negative one, because a positive noise fluctuation makes a data point more likely to be the highest one while a negative noise fluctuation does the opposite.

Here's a concrete example. Let's say we have two sets of numbers, set A and set B, each with 1000 numbers in them. In set A, each number has a true value of 5 but ±1 in errors. In set B, each number has a true value of 0, but ±10 in errors. So in reality the numbers in set A are much bigger than in set B. But now look at what happens when we take errors into account. In set A, it's unlikely that we will see any numbers higher than around 8, since a +3 error has a likelihood of only 0.15%. Meanwhile, in set B we're almost guaranteed to see numbers higher than 20. So if we're not careful we will incorrectly conclude that B is really bigger than A.

Sorry, that didn't come out as clearly as I had hoped. If you know some simple programming, then I recommend just writing a 5-line program to test it out yourself.

This is the most mind bendy thing ever! Is it because of some reason we know or is it because, well, it is!!?!!

Also, at what speed does the non-additive-ness start?

I still don't understand why .6c plus .6c cannot equal 1.2c, I only know that it can't.

> Doesn't there have to be some reference frame whereby a body is not moving through space at all?

Relative to what? If you're measuring against the expansion of the universe, then you'd have to take VERY precise measurements against the most distant objects, and they're moving in all kinds of directions, but if you could, then sure, you could do that, somehow.

You'd just be moving at an insanely high velocity relative to anything local to you.

And because you're moving at that insane speed relative to, say, earth, you'd have to apply a massive force to actually get up to that insane speed.

> But if all speed is relative, both should see the other speed up, which feels paradoxical.

Welcome to relativity. Say you have 2 objects approaching Earth at 0.1c, relative to Earth. They'd see each other as moving less than 0.2c, because it's not additive, and if they could each see a clock on the other ship, they'd see that clock moving slower than their own.

> Under the laws of special relativity an observer in a space ship travelling at 0.1c will see Earth speed up, while an observer on Earth will see the ship slow down.

No they won't. They'll both see each other slow down, since motion is truly relative. From the perspective of the Earth, the ship is moving away. From the perspective of the ship, the Earth is moving away. Neither is right or wrong. Both see symmetrical time dilation.

The unintuitiveness of this fact is why the twin paradox is so famous, despite not really being a paradox: https://en.wikipedia.org/wiki/Twin_paradox

That's correct that the orbits within the extended galactic mass distribution resemble orbits about a point mass in two dimensions (or an infinite line mass in 3D). In both cases the gravitational potential is logarithmic with respect to distance. That's coincidental, and I'm not familiar with any mathematical tricks that take advantage of the correspondence.

Yes, you have to speed up to get to a higher orbit -- and paradoxically, that still results in you moving slower, on average! This is an extremely interesting feature of gravitational systems; for example, it means they have a negative heat capacity (adding energy cools them).

Nope, orbital speed goes down as you get farther away. The equation is:

v = sqrt(G * M / R)

Larger R, smaller v.

In order to REACH a higher orbit, you need to do work to move the mass to a higher gravitation potential. That type of work requires thrust, but once you're at the larger orbit, the speed is slower.

Conversely, to move CLOSER to the sun, you need "anti-thrust" to move lower in the gravitational potential.

Yes you have to speed up to get to a higher orbit but then your orbital speed is slower.

Suppose we were at exactly zero motion relative to the CMB. If we underwent any gravitational interaction with another body, each would undergo some acceleration. That would leave each body with a non-zero motion relative to the CMB. So any local gravitational interaction would take us away from zero-CMB-motion.

Barring some sort of speculative restorative effect that brings us back to zero-CMB-motion, you'll be left with non-zero motion relative to the CMB.

So local interactions later on would be enough to create some motion.

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I think the bit you're missing is that when you move in a particular direction, light from that direction becomes slightly bluer and light behind you becomes slightly red.

If you assume the "expanding balloon" is expanding everywhere at the same rate, by looking at the colour of the expanding balloon you can determine a speed relative to you where the balloon will have the same colour everywhere.

Yes, it would have been more logical if we'd have been stationary relative to the global frame, but it turns out we're not. Science is more interesting when it gives you answers you don't expect.

(It could be that the "bubble" is not expanding at a uniform rate everywhere, but we (currently) have no way of distinguishing that. And it seems the weaker assumption that we're simply moving than some fancy new physics.)

In special relativity, simultaneity depends on your reference frame. In one reference frame, event A can occur before event B, but in another, event A can occur after event B. There is no absolute ordering of events that are separated in space time, unless the events are causally connected.

>But if the bullets looked at each other they would only see themselves moving apart at the speed of light.

Additionally, the reference frame of the bullet (photon) is not defined. There is no reference frame where a photon is at rest, so you cannot use special relativity to consider the perspective of the "bullet."

If the bullets were traveling at almost c, each bullet would regard the other bullet as traveling at almost c. You may observe the bullets moving away from each other at almost 2c from your reference frame and hitting the walls simultaneously, but the bullets would not. See closing speeds and other examples of apparent superluminal speeds.

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I'm pretty sure "relativity of simultaneity" describes what you're talking about.

There’s more thorough explanations here already, but quite simply- one bullet would not perceive the other hitting its wall at the same time as itself. Remember that to see the bullet hit the wall, the light from the event has to travel to your eyes. You are equidistant. If the bullet had eyes, that light has to travel that extra distance- wall to wall. It would hit the wall, and slightly later would see it’s companion hit it’s wall.

A more mind bending “paradox” is the ladder paradox in which a ladder contracts to fit in a barn too small for it. I can’t explain it better than wiki here.

Nope! Let’s say each neutrino is going 51% the speed of light, in opposite directions. If neutrino A were to look at neutrino B, it would only see B traveling at about 81% the speed of light. B would see A going the same speed, but in the other direction.

Now, if you’re on the ground watching these particles fly, you would see them move apart with the gap between them growing at 102% the speed of light. However, the individual objects would only move at 51% C, so nothing is violating physics

They would be moving away at the speed of light from any reference point. One neutrino would "see" the other moving away at the speed of light.

If you stood between them they would both be moving away at the speed of light from you. If you shot one away and then accelerated to the speed of light in the other direction then that neutrino would still be moving away at the speed of light.

Yeah, with those speeds, your pattern recognition of what you would expect to happen breaks down, there’s a reason relativity is so confusing to most people

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You can't see the photons going away from you. The only way to measure the speed of light is by round-trip -- ie. stick a mirror out there and let the photons come back, and measure round-trip time.

... but I'm sure you see where this is going -- if the speed outward was faster, the return trip will be slower, canceling out the difference.

Now, you could stick an observer out there to try and measure the transit time in one direction... but how do you synchronize your watches without relying on the speed of light? Well, you could sync them before moving apart, but the act of traveling apart will make time pass at different rates for you, so your watches instantly become un-synchronized. The equations you might use to cancel out this desyncing all rely on... the speed of light :-D

There's a fun video on it, lemme find it.

EDIT: found it! Veritasium

The laws of physics do not specify an absolute velocity, and the speed of light is a maximum that any observer can measure any object going, no matter how fast the observer is going relative to some reference point.

The important context here is that velocities do not compose by simple addition, but by a Lorentz transform. If I see two objects moving away from me in opposite directions at half the speed of light, those two objects will see each other moving away at less than the speed of light. This is where you also see phenomena such as time dilation, length contraction, etc... come from.