Starship Asterisk*

neufer wrote: ↑Mon Dec 23, 2019 10:11 am

BDanielMayfield wrote: ↑Mon Dec 23, 2019 2:33 am
Awesome analysis and graphics! Thanks alter-ego.

Indeed, and thanks alter-ego for the correction with the actual size of the neutron star.

Apparently, I struggle with the simplest of math of relating 15 mile wide neutron stars with 2.95 kilometer radius solar mass black holes.

BDanielMayfield wrote: ↑Mon Dec 23, 2019 2:33 am
Awesome analysis and graphics! Thanks alter-ego.

alter-ego wrote: ↑Sun Dec 22, 2019 11:34 pm After some thought, I decided that some might be interested a graphic showing surface visibility evaluation details.
Art - I pursued a hybrid empirical evaluation using both the YouTube wireframe and an accurate, family of ray-trajectories. The two approaches agreed very well, only because the wireframe has a 1.3M_☉ example and the actual mass is estimated at 1.35M_☉.

• Fraction of surface area visible = 68% to 70%

The left panel shows a large collection of parallel light-ray trajectories originating at right from infinity interacting with a Schwarzschild black hole. The right panel a screenshot from the video showing the actual and apparent size of a 1.3M_☉ NS. The two panels are scaled so that the NS actual sizes are equal.
 
 

Visible Surface Fraction Evaluation_2.JPG

→ The blue rays show a family of "plunge orbits", i.e. all rays that are captured by the black hole.
→ The red rays show trajectories that aren't captured
→ The smaller black circle is the BH event horizon of mass M, and
     radius = 1 Schwarzschild radius, R_S
→ The larger green circle represents the NS actual size = 3.25 R_S
→ Green shaded area represents visible NS surface.
→ The 2 black trajectory rays leave the NS from their tangent point
(furthest visible point on surface) and propagate to infinity

Note:The X and Y distance units in the left pane Are normalized by the quantity G/c² . The Schwarzschild radius = 2M in GR-convenient units.
 

• The indicator lines connecting the two panels show the very good agreement for the predicted apparent NS sizes.
  The apparent size difference between and 1.3M_☉ and1.35_☉are within the accuracy of the evaluation techniques. (I was pleasantly surprised the agreement as this good)

• Fraction of surface area visible = 68% to 70%

• The indicator lines connecting the two panels show the very good agreement for the predicted apparent NS sizes.
  The apparent size difference between and 1.3M_☉ and1.35_☉are within the accuracy of the evaluation techniques. (I was pleasantly surprised the agreement as this good)

neufer wrote: ↑Wed Dec 18, 2019 8:04 pm
In this case the actual radius of this neutron star is ~1.8 times its Schwarzschild radius so perhaps ~10% of the neutron star's surface is unseen.

neufer wrote: ↑Thu Dec 19, 2019 3:03 pm

BDanielMayfield wrote: ↑Thu Dec 19, 2019 1:18 pm
My errors arose because the radii I used were too small. How does one correctly calculate NS radius for given mass?

One could ask a bystander:

https://asterisk.apod.com/viewtopic.php?t=40100 wrote:
<<Through very careful analysis of the X-ray variations from this neutron star, the NICER data
show that J0030+0451 is 40 percent more massive than the Sun, but only about 15 miles wide.>>

The equation of state for a neutron star is not yet known. It is assumed that it differs significantly from that of a white dwarf, whose equation of state is that of a degenerate gas that can be described in close agreement with special relativity. However, with a neutron star the increased effects of general relativity can no longer be ignored. Several equations of state have been proposed (FPS, UU, APR, L, SLy, and others) and current research is still attempting to constrain the theories to make predictions of neutron star matter.[10][41] This means that the relation between density and mass is not fully known, and this causes uncertainties in radius estimates. For example, a 1.5 M☉ neutron star could have a radius of 10.7, 11.1, 12.1 or 15.1 kilometers (for EOS FPS, UU, APR or L respectively).[41]

It is probably better to think visually in terms of photon spheres
rather than mathematically in terms of escape velocities:

https://en.wikipedia.org/wiki/Photon_sphere

Chris Peterson wrote: ↑Thu Dec 19, 2019 2:30 pm

neufer wrote: ↑Thu Dec 19, 2019 4:04 am
For a solar mass black hole to evaporate by Hawking radiation would require at least 10⁶⁴ years.

Solar mass neutrons stars may well have evaporated by other methods long before solar mass black holes disappear:

https://en.wikipedia.org/wiki/Proton_decay wrote:
<<According to the Standard Model, protons, a type of baryon, are stable because baryon number (quark number) is conserved. Therefore, protons will not decay into other particles on their own, because they are the lightest (and therefore least energetic) baryon. Some beyond-the-Standard Model grand unified theories (GUTs) explicitly break the baryon number symmetry, allowing protons to decay via the Higgs particle, magnetic monopoles, or new X bosons with a half-life of 10³¹ to 10³⁶ years. The proton decay hypothesis was first formulated by Andrei Sakharov in 1967. Although the phenomenon is referred to as "proton decay", the effect would also be seen in neutrons bound inside atomic nuclei. Despite significant experimental effort, proton decay has never been observed. If it does decay via a positron, the proton's half-life is constrained to be at least 1.67×10³⁴ years.>>

I wouldn't say "may well have evaporated", but rather, "there's a remote chance that neutrons decay, and that would result in evaporation on a much shorter timescale than that of the evaporation of small black holes".

Chris Peterson wrote: ↑Thu Dec 19, 2019 2:30 pm
(FWIW, I calculate that a neutron star contains about 1.8 x 10⁵⁷ neutrons, or about 2¹⁹⁰, so if neutrons decay with a half-life of 10³⁴ years, that suggests a lifetime of about 10³⁶ years.)

BDanielMayfield wrote: ↑Thu Dec 19, 2019 1:18 pm
My errors arose because the radii I used where too small. How does one correctly calculate NS radius for given mass?

https://asterisk.apod.com/viewtopic.php?t=40100 wrote:
<<Through very careful analysis of the X-ray variations from this neutron star, the NICER data
show that J0030+0451 is 40 percent more massive than the Sun, but only about 15 miles wide.>>

neufer wrote: ↑Thu Dec 19, 2019 4:04 am

Chris Peterson wrote: ↑Thu Dec 19, 2019 1:45 am

TheOtherBruce wrote: ↑Thu Dec 19, 2019 1:42 am
Can you get Hawking radiation if there isn't an actual event horizon?

No.

For a solar mass black hole to evaporate by Hawking radiation would require at least 10⁶⁴ years.

Solar mass neutrons stars may well have evaporated by other methods long before solar mass black holes disappear:

https://en.wikipedia.org/wiki/Proton_decay wrote:
<<According to the Standard Model, protons, a type of baryon, are stable because baryon number (quark number) is conserved. Therefore, protons will not decay into other particles on their own, because they are the lightest (and therefore least energetic) baryon. Some beyond-the-Standard Model grand unified theories (GUTs) explicitly break the baryon number symmetry, allowing protons to decay via the Higgs particle, magnetic monopoles, or new X bosons with a half-life of 10³¹ to 10³⁶ years. The proton decay hypothesis was first formulated by Andrei Sakharov in 1967. Although the phenomenon is referred to as "proton decay", the effect would also be seen in neutrons bound inside atomic nuclei. Despite significant experimental effort, proton decay has never been observed. If it does decay via a positron, the proton's half-life is constrained to be at least 1.67×10³⁴ years.>>

One measure of such immense gravity is the fact that neutron stars have an escape velocity ranging from 100,000 km/s to 150,000 km/s, that is, from a third to half the speed of light.

neufer wrote: ↑Wed Dec 18, 2019 8:04 pm

This artist's impression depicts the paths of photons in the vicinity of a black hole.

---

BDanielMayfield wrote: ↑Wed Dec 18, 2019 7:36 pm

Because the gravitational lensing effect of neutron stars is so strong, J0300 displays more than half of its surface toward the Earth.

So photon paths are bent around the normal horizon of NSs, letting us see more than half of their surfaces!

I number crunched some stats to estimate the escape velocity for NSs in the mass range of 1.1 to 2.14 Solar masses and came up with a range of .54 to .73 c.

So, what percentage of a neutron star's surface are we able to see?

If the radius were 1.5 times its Schwarzschild radius then one would be able to see all of the neutron star's surface.

In this case the actual radius of this neutron star is ~1.8 times its Schwarzschild radius so perhaps ~10% of the neutron star's surface is unseen.

Chris Peterson wrote: ↑Thu Dec 19, 2019 1:45 am

TheOtherBruce wrote: ↑Thu Dec 19, 2019 1:42 am

MarkBour wrote: ↑Wed Dec 18, 2019 8:01 pm
Wouldn't Hawking radiation apply to these bodies just as well as it would to a black hole?

Can you get Hawking radiation if there isn't an actual event horizon?

No.

https://en.wikipedia.org/wiki/Proton_decay wrote:
<<According to the Standard Model, protons, a type of baryon, are stable because baryon number (quark number) is conserved. Therefore, protons will not decay into other particles on their own, because they are the lightest (and therefore least energetic) baryon. Some beyond-the-Standard Model grand unified theories (GUTs) explicitly break the baryon number symmetry, allowing protons to decay via the Higgs particle, magnetic monopoles, or new X bosons with a half-life of 10³¹ to 10³⁶ years. The proton decay hypothesis was first formulated by Andrei Sakharov in 1967. Although the phenomenon is referred to as "proton decay", the effect would also be seen in neutrons bound inside atomic nuclei. Despite significant experimental effort, proton decay has never been observed. If it does decay via a positron, the proton's half-life is constrained to be at least 1.67×10³⁴ years.>>

TheOtherBruce wrote: ↑Thu Dec 19, 2019 1:42 am

MarkBour wrote: ↑Wed Dec 18, 2019 8:01 pm Wouldn't Hawking radiation apply to these bodies just as well as it would to a black hole?

Can you get Hawking radiation if there isn't an actual event horizon?

MarkBour wrote: ↑Wed Dec 18, 2019 8:01 pm Wouldn't Hawking radiation apply to these bodies just as well as it would to a black hole?

neufer wrote: ↑Wed Dec 18, 2019 8:04 pm

This artist's impression depicts the paths of photons in the vicinity of a black hole.

---

BDanielMayfield wrote: ↑Wed Dec 18, 2019 7:36 pm

Because the gravitational lensing effect of neutron stars is so strong, J0300 displays more than half of its surface toward the Earth.

So photon paths are bent around the normal horizon of NSs, letting us see more than half of their surfaces!

I number crunched some stats to estimate the escape velocity for NSs in the mass range of 1.1 to 2.14 Solar masses and came up with a range of .54 to .73 c.

So, what percentage of a neutron star's surface are we able to see?

If the radius were 1.5 times its Schwarzschild radius then one would be able to see all of the neutron star's surface.

In this case the actual radius of this neutron star is ~1.8 times its Schwarzschild radius so perhaps ~10% of the neutron star's surface is unseen.

BDanielMayfield wrote: ↑Wed Dec 18, 2019 7:36 pm

Because the gravitational lensing effect of neutron stars is so strong, J0300 displays more than half of its surface toward the Earth.

So photon paths are bent around the normal horizon of NSs, letting us see more than half of their surfaces!

I number crunched some stats to estimate the escape velocity for NSs in the mass range of 1.1 to 2.14 Solar masses and came up with a range of .54 to .73 c.

So, what percentage of a neutron star's surface are we able to see?

neufer wrote: ↑Wed Dec 18, 2019 6:56 pm

DL MARTIN wrote: ↑Wed Dec 18, 2019 6:45 pm
What is being considered took place a thousand years ago. Shouldn't this qualifier be included in the discussion?

DL MARTIN made his comment an hour ago. Shouldn't this qualifier be included in the discussion?

Because the gravitational lensing effect of neutron stars is so strong, J0300 displays more than half of its surface toward the Earth.

Chris Peterson wrote: ↑Wed Dec 18, 2019 2:42 pm

JohnD wrote: ↑Wed Dec 18, 2019 10:53 am We get discussions here about the way that colours are interpreted in astronomical photos, and it often seems to be either an aesthetic argument, or one of interpretation, using false colours to make the image clearer. But here, there is a clear misinterpretation, if not an aim to mislead the viewer.

in the small print we read, "the rest of the star's surface filled in with a false patchy blue". If the rest of the disc had been a plain, unmarked colour, that would be a true picture of this remarkable acheivement in imaging. To insert apparent markings is incorrect, with no evidence to substantiate it.

If you look at the published papers, they show the star in wireframe with the hotspots overlain. But the video really requires a structured background in order to see how the model handles rotation. They could have used something like a fine checkerboard, but that might have been distracting. So a low contrast, low spatial frequency map consistent with small temperature variations that are almost certainly present seems like a reasonable choice, along with a clear statement that this background is synthesized, not derived from the data. To me that's the very opposite of misleading.

DL MARTIN wrote: ↑Wed Dec 18, 2019 6:45 pm
What is being considered took place a thousand years ago. Shouldn't this qualifier be included in the discussion?

TheOtherBruce wrote: ↑Wed Dec 18, 2019 4:18 pm

Ralphbolt wrote: ↑Wed Dec 18, 2019 3:59 pm
12,000 RPM!! Amazing. Where did the energy to spin them up come from?

The rotational energy was already there, in the star that existed before the supernova. When the neutron star formed, this energy was concentrated....