APOD: Star Size Comparisons (2011 Feb 22)

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Expand view Topic review: APOD: Star Size Comparisons (2011 Feb 22)

Re: APOD: Star Size Comparisons (2011 Feb 22)

by e-jit » Mon Jan 16, 2012 2:17 pm

Sandgirl wrote:I just wondered - it would take 1100 years for jet plane to orbit that giant star - but how long would it take the Earth to orbit that star if it was at the same distance from it as it is from our Sun?
Well, at 1.4 Tm in radius (one tera-metre is almost a light hour), it's about ten times as big as Earth's orbit around the Sun - but you did say "distance from it" rather than orbital radius, so you're asking for the orbital period of a body about 1.5 Tm from the centre of VY Canis Majoris. (The Wikipedia entry for it says it's bigger than the orbit of Saturn; or, even accepting the lower estimates of its size that some use, bigger than the orbit of Mars.) It's between 30 and 40 solar masses, so using G.M = w^2.R^3 for our Sun of (turn/year)^2 (AU)^3, its is 30~40 times that and we're using an 11ish AU orbit, so its w^2 is (30~40).(turn/year)^2/(11ish)^3 = ((30~40)/11ish).(turn/(11ish years))^2, so its period is 11ish years divided by the square root of (30 to 40)/11ish, so (very) roughly seven years, if I managed to not goof any of the sums there.

Which, of course, means that an airplane (or, rather, the droplet of molten debris it'd rapidly become) going at 900 km/hr isn't actually a feasible object in that environment; that's below orbital speed, so it'd be losing to gravity. Then again, local gravitational field strength is about 1/500 of that at Earth's surface, so it wouldn't need much force to keep it up. Looking to aerodynamics to model that is fairly hopeless, though: the star's average density is 5 to 10 millionths that of air at STP, so I'm guessing it's tiny even by comparison to that of our stratosphere; and that's an average, so I must guess the surface is even thinner still. It'd be a tiny spec immersed in a magnetohydrodynamic maelstrom, whose matter aspect it'd barely notice; and I don't know enough to guesstimate the strength of the electromagnetic field, much less how that'd affect a droplet of dirty (there used to be a pilot, some furniture and some fuel in there) mostly non-ferrous (iron is too heavy for aircraft) metal.
But I think that's an unfair point on which to criticise the video: they wanted to convey how far the distance is, so used the fastest speed at which audience members are familiar with travelling to show how long it'd take to travel that distance; they could as easily say that a jet plane flying round our equator at 900 km/hr and refueling continuously in flight would need to keep doing so for 1115 years before it'd have clocked up a distance as big as VY Canis Majoris's circumference.

Not that I think that's a particularly good way to communicate the enormity of astronomical distances. I find the travel time of light to be more useful: one foot is a light nanosecond, a mile is several light microseconds, an air journey East or West that involves a one hour change in time-zone covers several light milliseconds (depending rather on latitude and the politics of time-zone boundaries), the moon is a light second and a quarter away, the Sun is eight and a bit light minutes away, each year the Earth circles the Sun along a path whose length is the distance light travels in 50 minutes and 20 seconds; VY Canis Majoris's diameter is a bit longer than the distance light travels in two and a half hours.
The human brain doesn't deal well with big numbers, but that progression leads from familiar distances matching small quantifiers, through intelligible (if big) distances matching intelligible (if small) times to cast astronomical distances in terms I hope can begin to be grasped.

As for the "centre of the universe", as usual, people misunderstand the idea of an expanding universe. If I insert a fine needle into a drop of soapy water and blow in some air, the drop becomes a bubble that expands and expands; distances within the universe are like distance measured along the surface of the bubble, getting bigger, yet no point in the universe is "the" point from which it is all expanding "away"; a small patch of dye in the surface will expand as the surface expands, outwards from the patch's centre, yet this is no more the centre than that of another small patch of dye elsewhere in the surface. The only centre the universe has is the whole of it at its beginning, before its parts started expanding away from one another.

We are, of course, at the centre of the observed universe: the inevitable consequence of observing it from here.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Terry P-B » Sat Oct 01, 2011 5:52 am

I come to this a bit late (just working my way through the archives of this marvelous site), but i have basic issue with the video: size. In the video, Jupiter's diameter appears 14 times as great as Earth's, where in reality, the ratio is more like 11:1. The ratio of the Sun's diameter to Jupiter's is almost exactly correct--to within 1%, as near as I could measure it.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Guest » Tue Jul 12, 2011 3:52 am

my favourite video on my least favourite day... February 22nd which was the day i was in an earthquake that destroyed my home and everything :evil: :(

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Chris Peterson » Wed Mar 30, 2011 2:39 pm

trevor.ockenden wrote:I believe the most glaring inaccuracy is that it would take approximately 1,100,000 years to fly around this hypergiant at 900 km/hr given that the suns diameter is stated to be 2,800,000,000 km. This figure stood out as too small as soon as I saw it.
You might want to try that calculation again.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by trevor.ockenden » Wed Mar 30, 2011 11:01 am

I believe the most glaring inaccuracy is that it would take approximately 1,100,000 years to fly around this hypergiant at 900 km/hr given that the suns diameter is stated to be 2,800,000,000 km. This figure stood out as too small as soon as I saw it.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Belmont5 » Tue Mar 15, 2011 2:57 pm

Surely the "centre of the universe" is totally dependant upon there being a discernible boundary?

Re: APOD: Star Size Comparisons (2011 Feb 22)

by NoelC » Sun Mar 06, 2011 1:02 am

Just Some Guy wrote:It would take you much longer than 1100 years to circle that star.
It would take you at least half that time to get through the TSA.
Ya, we wouldn't want something like a dirty bomb to be brought on board. :)

-Noel

Re: APOD: Star Size Comparisons (2011 Feb 22)

by guest » Fri Mar 04, 2011 11:48 pm

RBolzen wrote:We are the center of the observable univers, arent we.
So is everybody else, whereever he may be in the universe.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by neufer » Mon Feb 28, 2011 11:15 pm

chad2424 wrote:
I would love to see you add in some smaller stars like red dwarfs and white dwarfs for comparison.
Brown dwarfs are a little bit bigger than Jupiter.
White dwarfs are a little bit bigger than the Earth.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by chad2424 » Mon Feb 28, 2011 4:27 pm

I would love to see you add in some smaller stars like red dwarfs and white drawfs for comparison.

That would be cool

Re: APOD: Star Size Comparisons (2011 Feb 22)

by neufer » Sun Feb 27, 2011 4:48 pm

EarthBoy wrote:
While it's understandable to start with the planets of our solar system, and our star, "The Sun", this size list,by sequence, there by implies that our Sun is the smallest star – which is also not true

So I would suggest including smallest, or smaller stars, in the list too…

Of course that brings it's own set of confusions…

It would also be interesting to list the 'smallest planet' (definition: must be spherical), (largest planet), 'smallest neutron star', 'largest neutron star', 'smallest black hole', largest ' (currently known) black hole, and size of our milky-way galaxy, as a basis of comparison.
Well, one could reasonably have left out black hole event horizons all together.

However, relative to the sun neutron stars are 100,000 times smaller
whereas the largest stars are only 2,000 times larger than the sun.

The emphasis on how big stars can get vis-a-vis the earth & sun
would have gotten lost by going in the other direction.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by EarthBoy » Sun Feb 27, 2011 3:56 pm

While it's understandable to start with the planets of our solar system, and our star, "The Sun", this size list,by sequence, there by implies that our Sun is the smallest star – which is also not true

So I would suggest including smallest, or smaller stars, in the list too…

Of course that brings it's own set of confusions…

It would also be interesting to list the 'smallest planet' (definition: must be spherical), (largest planet), 'smallest neutron star', 'largest neutron star', 'smallest black hole', largest ' (currently known) black hole, and size of our milky-way galaxy, as a basis of comparison.

As for the other discussion, I can't see why our Universe should not be semi-spherical…
of course we are lost way inside it somewhere… (reasonably nice)…

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Indigo_Sunrise » Fri Feb 25, 2011 6:12 pm

owlice wrote:If it's going to contract everywhere, can it start on my hips, please?



:lol:

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Chris Peterson » Fri Feb 25, 2011 3:23 pm

alphachap wrote:
Chris Peterson wrote:That's not the case. Matter is not contracting. Atoms are the same size they always were. Space is expanding, except where there are fields strong enough to hold it together- gravitational fields, nuclear force fields, etc. The distance between pieces of matter is what is increasing.
How do we know? What if matter is contracting everywhere? The distance between pieces of matter would appear to increase.
Contracting matter is inconsistent with both theory and observation. For instance, if spacetime were of fixed size and matter shrinking, we'd not see cosmological redshift, which is caused by the expansion of space as light travels through it.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by owlice » Fri Feb 25, 2011 2:13 pm

alphachap wrote:What if matter is contracting everywhere?
If it's going to contract everywhere, can it start on my hips, please?

Re: APOD: Star Size Comparisons (2011 Feb 22)

by alphachap » Fri Feb 25, 2011 1:39 pm

Chris Peterson wrote:
alphachap wrote:When we talk about the expansion of the universe, we are really talking about contraction of matter. Looking from another point of view is often helpful. Those 2 points of view are probably equivalent, but maybe they are not, in which case it would be nice to know which is more correct.
That's not the case. Matter is not contracting. Atoms are the same size they always were. Space is expanding, except where there are fields strong enough to hold it together- gravitational fields, nuclear force fields, etc. The distance between pieces of matter is what is increasing.
How do we know? What if matter is contracting everywhere? The distance between pieces of matter would appear to increase.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Just Some Guy » Fri Feb 25, 2011 6:28 am

It would take you much longer than 1100 years to circle that star.
It would take you at least half that time to get through the TSA.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by astrocycle » Fri Feb 25, 2011 5:25 am

There were a number of points made about supergiant stars being aspherical, but we do know that the planets aren't. At the scale shown, Saturn's oblateness would be easily seen:
http://en.wikipedia.org/wiki/File:Satur ... ope%29.jpg

And, despite the perspective view from the observer, to me the video shows Venus to be smaller than the earth. At the scale shown, the difference in sizes would be imperceptible.

The rest , except for that inane comment at the end could be chalked up to artistic license.

Saturn is oblate Re: APOD: Star Size Comparisons (2011 Feb 2

by ultradeep » Fri Feb 25, 2011 5:22 am

Saturn is depicted as a sphere, about as spherical as the other objects listed. However, it is a quite oblate spheroid; its equatorial diameter is about 10% greater than its axial diameter.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Chris Peterson » Fri Feb 25, 2011 1:56 am

xcjorr wrote:If we back 4D time out and acknowledge the fact that the universe is becoming spatially, wouldn't it still be possible to identify at least the region of 3D space at the center of the 3D universe?
No. First of all, the Universe isn't "becoming"; it is expanding. In the 3D universe, there is simply no center. Any point can be considered the center of 3D expansion, and the actual point of expansion of the entire Universe is at t=0, which is in a direction we can't look. Go back to the balloon analogy, which is very good. In that case, the surface of the balloon is the spatial universe, but the expansion is from a point inside the balloon. If you are a 2D being living on the surface of the balloon, there is no way you can see the center. But on your surface, everything is moving away from you. You are a center of expansion, even if you are not the center of the 3D universe. There is nothing special about any place on the balloon surface.

Our inability to see the true center of expansion is not a technological limitation.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Chris Peterson » Fri Feb 25, 2011 1:51 am

alphachap wrote:When we talk about the expansion of the universe, we are really talking about contraction of matter. Looking from another point of view is often helpful. Those 2 points of view are probably equivalent, but maybe they are not, in which case it would be nice to know which is more correct.
That's not the case. Matter is not contracting. Atoms are the same size they always were. Space is expanding, except where there are fields strong enough to hold it together- gravitational fields, nuclear force fields, etc. The distance between pieces of matter is what is increasing.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by jr chaffer » Fri Feb 25, 2011 1:35 am

This is a nice show - but just one more of many such entertaining depictions. It is pretty enlightening to those who are completely unfamiliar with astronomy and astrophysics.

BUT - there is no need at all for the superfluous, unjustified, in fact rather silly, philosophical statement at the end. There is simply no evidence to justify such a claim - real or otherwise.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Beta Lyrae » Thu Feb 24, 2011 6:59 pm

In order for something to orbit VY Canis Majoris near its surface:

mass_solar = 1.989e30 kg
radius_vy = 2.8e9 km = 2.8e12 m
mass_vy = 35 * M_solar = 6.962e31 kg
G = 6.674e-11
specific force = G * mass / (radius^2) = 5.93e-4 N/kg
specific centripetal force = velocity^2 / radius
velocity = sqrt(specific_centripetal_force * radius) = 4.07e4 m/s.

About 40.7 km/second or 147,000 km/hour, according to my calculations. This would make it travelling 164 times faster. The pull of gravity near the star's surface is only 0.000064 gee.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by ascet » Thu Feb 24, 2011 6:51 pm

at the end of the video, instead of zooming in on the largest star and show a tiny dot in place of planet earth i would like to see the largest
star be placed in our solar system and see how much place it will occupy if placed there.

Re: APOD: Star Size Comparisons (2011 Feb 22)

by Guest » Thu Feb 24, 2011 6:09 pm

Should have shown a couple of brown dwarfs, since they are intermediate in size, and some red dwarfs, since they are by far the most common type of star.

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