Starship Asterisk*

Chris Peterson wrote:

neufer wrote:

Chris Peterson wrote:
A Pluto at 118 AU most certainly alters the orbits of all the inner planets over a million years!

I assumed that you meant detectable with current technology over no more than a few hundred years.

Then you didn't read what I wrote carefully enough. The question had to do with the consequences to the Solar System of having nearby stars moving by (as in a globular cluster). Such interactions will occur on time scales of hundreds of thousands of years, so that's the time scale of the perturbations.

https://en.wikipedia.org/wiki/Apsidal_precession wrote:
<<In celestial mechanics, perihelion precession, apsidal precession or orbital precession is the precession (rotation) of the orbit of a celestial body. More precisely, it is the gradual rotation of the line joining the apsides of an orbit, which are the points of closest and farthest approach. Perihelion is the closest point to the Sun.

There are a variety of factors which can lead to periastron precession, such as general relativity, stellar quadrupole moments, mutual star–planet tidal deformations, and perturbations from other planets.

• ω_total = ω_tide + ω_{General Relativity} + ω_quadrupole + ω_{perturbations}

For Mercury, the precession due to perturbations from all the other planets in the Solar System is 532″ per century. The perihelion precession rate due to general relativistic effects is 43″ per century.

Chris Peterson wrote:
Of course, if a solar mass star simply materialized one light year from the Sun, we would be able to detect its effect on planetary orbits within a pretty short time- a few years at most, I would think. (Just as we'd detect the effect of Pluto disappearing instantly.)

neufer wrote:

Chris Peterson wrote:

neufer wrote: The gravitational tidal forces of a star out at 1 light year are equivalent
to the gravitational tidal forces of "a Pluto" out at 118 AU.

Can't be done :!:

A Pluto at 118 AU most certainly alters the orbits of all the inner planets over a million years!

I assumed that you meant detectable with current technology over no more than a few hundred years.

Chris Peterson wrote:

neufer wrote:

Chris Peterson wrote:
I think you underestimate the number of decimal places of precision we deal with in modeling planetary orbits. We can detect relativistic effects in orbital parameters of planets.

The gravitational tidal forces of a star out at 1 light year are equivalent
to the gravitational tidal forces of "a Pluto" out at 118 AU.

Can't be done

A Pluto at 118 AU most certainly alters the orbits of all the inner planets over a million years!

neufer wrote:

Chris Peterson wrote:

neufer wrote: Whoa thar Rusty :!: Let's rethink that whole planets thing.

Voyager 1 is out at 139 AU (~0.002 lyr) where the Solar System escape velocity is ~3.6 km/s.

Voyager 1 is traveling at 17.043 km/s and is slowly
slowing down to 16.66 km/s = sqrt[(17.043)²-(3.6)²].

A star out at 1 lyr will generate only (0.002)² of the solar acceleration
that is slowly slowing Voyager 1 by just 0.383 km/s [= (17.043 - 16.66)].

Furthermore...the star is accelerating the Sun by
practically the same amount in the same direction :!:

Hence... the relative motion of Voyager 1 vs-a-vis the Sun
should be undetectable even with radar tracking.

Ergo: the relative motion of the planets vs-a-vis the Sun
would definitely be undetectable by passing stellar tidal forces.

I think you underestimate the number of decimal places of precision we deal with in modeling planetary orbits. We can detect relativistic effects in orbital parameters of planets. I'm pretty sure that a rapidly moving star a light year away will measurably- even significantly alter the orbits of our planets. That is, the positions of the planets after the million year passage will be distinctly different than if the star had not passed at all.

The gravitational tidal forces of a star out at 1 light year are equivalent
to the gravitational tidal forces of "a Pluto" out at 118 AU.

Can't be done :!:

Chris Peterson wrote:

neufer wrote:

Chris Peterson wrote:
If another star passed within a light year of the Sun, it would greatly disrupt the Oort cloud (sending a barrage of comets into the inner system) and measurably perturb the orbits of the outer planets.

Whoa thar Rusty Let's rethink that whole planets thing.

Voyager 1 is out at 139 AU (~0.002 lyr) where the Solar System escape velocity is ~3.6 km/s.

Voyager 1 is traveling at 17.043 km/s and is slowly
slowing down to 16.66 km/s = sqrt[(17.043)²-(3.6)²].

A star out at 1 lyr will generate only (0.002)² of the solar acceleration
that is slowly slowing Voyager 1 by just 0.383 km/s [= (17.043 - 16.66)].

Furthermore...the star is accelerating the Sun by
practically the same amount in the same direction

Hence... the relative motion of Voyager 1 vs-a-vis the Sun
should be undetectable even with radar tracking.

Ergo: the relative motion of the planets vs-a-vis the Sun
would definitely be undetectable by passing stellar tidal forces.

I think you underestimate the number of decimal places of precision we deal with in modeling planetary orbits. We can detect relativistic effects in orbital parameters of planets. I'm pretty sure that a rapidly moving star a light year away will measurably- even significantly alter the orbits of our planets. That is, the positions of the planets after the million year passage will be distinctly different than if the star had not passed at all.

BillT wrote:

MikeODay wrote:A deep look at Omega Centauri ( NGC 5139 )

Capture:
9 sets of sub-images with exposure duration for each set doubling ( 1s to 240s ) all at ISO800.

Processing:.
Calibration: master bias, master flat and no darks.
Integration in 9 sets.
HDR combination.
Pixinsight

May 2017

Hi Mike,

Great image. I'm curious as why why you didn't use darks?

Bill

heehaw wrote:"...try to reproduce as best I can the "true colours" of the objects" - reminds me of the tour of a deep underground cave with the guide shining UV light on some of the rocks to bring out dramatic colors. One tourist objected that that was fake! Not true colors! So the guide said, OK, true colors !! and he turned off all the lights!

MikeODay wrote:A deep look at Omega Centauri ( NGC 5139 )

Capture:
9 sets of sub-images with exposure duration for each set doubling ( 1s to 240s ) all at ISO800.

Processing:.
Calibration: master bias, master flat and no darks.
Integration in 9 sets.
HDR combination.
Pixinsight

May 2017

neufer wrote:

Chris Peterson wrote:

zendae1 wrote:As a follow up question, how close can two of these stars be, on average, before starting to interact with each other? Are they sufficiently far apart to not interact?

Depends what you mean by "interact". There is no distance limit on gravity, so the Sun and Alpha Centauri interact. Luckily, they're moving more or less together, so not much is changing. If another star passed within a light year of the Sun, it would greatly disrupt the Oort cloud (sending a barrage of comets into the inner system) and measurably perturb the orbits of the outer planets.

Whoa thar Rusty :!: Let's rethink that whole planets thing.

Voyager 1 is out at 139 AU (~0.002 lyr) where the Solar System escape velocity is ~3.6 km/s.

Voyager 1 is traveling at 17.043 km/s and is slowly
slowing down to 16.66 km/s = sqrt[(17.043)²-(3.6)²].

A star out at 1 lyr will generate only (0.002)² of the solar acceleration
that is slowly slowing Voyager 1 by just 0.383 km/s [= (17.043 - 16.66)].

Furthermore...the star is accelerating the Sun by
practically the same amount in the same direction :!:

Hence... the relative motion of Voyager 1 vs-a-vis the Sun
should be undetectable even with radar tracking.

Ergo: the relative motion of the planets vs-a-vis the Sun
would definitely be undetectable by passing stellar tidal forces.

Chris Peterson wrote:

zendae1 wrote:As a follow up question, how close can two of these stars be, on average, before starting to interact with each other? Are they sufficiently far apart to not interact?

Depends what you mean by "interact". There is no distance limit on gravity, so the Sun and Alpha Centauri interact. Luckily, they're moving more or less together, so not much is changing. If another star passed within a light year of the Sun, it would greatly disrupt the Oort cloud (sending a barrage of comets into the inner system) and measurably perturb the orbits of the outer planets.

zendae1 wrote:As a follow up question, how close can two of these stars be, on average, before starting to interact with each other? Are they sufficiently far apart to not interact?

pinguwin wrote:Mike Oday, I get the same math of .18 cubic l.y. but this would mean that each star is .56 l.y. away from each other. That is assuming equal distribution but of course it's not.

Does anyone have what it might look like inside such a globular cluster? My searching skills failed me. The only thing I can find is an apod that uses a bird flock (https://apod.nasa.gov/apod/ap080906.html). Any good artistic renderings or simulations?

Ann wrote:Looking at today's APOD, I'm reminded of the only time I have ever looked at a globular cluster through a telescope. As a Color Commentator who gets a huge kick out of the colors of the universe, especially the tints of blue, I was very disappointed at the sight of M13. It was all white, with the faintest tinge of sickly green. I've never wanted to look at a globular cluster through a telescope again.

At first I thought that today's APOD looked much like that, but after I've looked at the full size image I have changed my mind. The stars in today's APOD do have colors, at least some of them. (And it is absolutely right that some of them should look colorless, because many stars in Omega Centauri are similar to the Sun in their temperature, and they are therefore white to our eyes.)

...

I like the subtle colors of the blue stars of Omega Centauri, and I believe that this is the "true color" of them. They are "blue horizontal branch stars", and while they are blue, they are not all that bright. The blue horizontal branch stars are no brighter than RR Lyrae stars, and some of them are fainter. And the RR Lyrae stars are typically no brighter than 30-50 times that of the Sun.

...

So I appreciate the pale, subtle colors of the stars of today's APOD.

Ann

rstevenson wrote:

joyfaith wrote:Isaac Asimov's short story Nightfall is a powerful piece about what life might look like in a globular cluster.

Not quite. From its Wikipedia article...

The fictional planet Lagash (Kalgash in the novel adaptation) is located in a stellar system containing six suns ..., which keep the whole planet continuously illuminated; total darkness is unknown, and as a result, so are all the stars outside the planet's stellar system.

Rob

Lagash was in the center of a giant cluster. Thirty thousand mighty suns shone down...

rstevenson wrote:If I've run the numbers correctly, .5 ly is about 800 times the radius of Pluto's orbit.

LMMT wrote:Would a planet inside the cluster show a night sky similar to ours or would it be incredibly full of stars?

pinguwin wrote:Does anyone have what it might look like inside such a globular cluster?

Ann wrote:

[url=http://io9.gizmodo.com/what-the-night-sky-would-look-like-from-inside-a-globul-1589324556]Life inside a globular cluster? Image copyright: William Harris and Jeremy Webb.[/url]

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joyfaith wrote:Isaac Asimov's short story Nightfall is a powerful piece about what life might look like in a globular cluster.

The fictional planet Lagash (Kalgash in the novel adaptation) is located in a stellar system containing six suns ..., which keep the whole planet continuously illuminated; total darkness is unknown, and as a result, so are all the stars outside the planet's stellar system.