Starship Asterisk*

This image is an artistic composition of images taken from the same location but at different sky positions, times and focal lengths respect to the final composition. This is not representing the real sky.

Both the foreground and background images were taken on the same evening by the same camera and from the same location.

Lorenzo Comolli wrote: ↑Tue Feb 14, 2023 9:10 pm Dear Donato, great to have you here.
Please can you reply to questions posed by others? They whould greatly help to understand how the image was made, than anyone can judge if it is ok or not.

1. Focal lenght of the two images (and eventual crop factor). Can you share 2 originals uncropped?
2. Location (Gornergrat?) How was imaging at night in shuch high altitude in winter?
3. Date time of the two images
4. Did you shot a reference image at the date time of the composition? I.e. at comet mars setting. Can you share?
5. Which processing steps caused the dark nebula stand in front of the mars glare?

Ciao,
Lorenzo

rcolombari wrote: ↑Wed Feb 15, 2023 10:16 am Hi Tom!
What you call a simple correction in the APOD description has a deep meaning IMHO and deserves some further toughts.

As we pointed out the comet is at the right place for the date and time declared by the author but there's a whole amount of sky that doesn't show up to the West. At the time the comet has been imaged, ZTF and Mars were around 50º-60º up in the sky while in the image they look pretty low.
Moreover, as Lorenzo highlighted, the glare of Mars is behind the dark nebula. How could it be possible?

All these considerations lead to just a conclusion: copy and past of 2 different images resulting in something that never happened. The sky simply wasn't in this configuration.
How can such an image be APOD worthy?
It's true that, besides what many out there think, APOD doesn't mean that the images are chosen by NASA or pass through a peer review before getting published or must have a specific scientific meaning (NASA is just the hosting as far as I know, nothing less or more than this). Nevertheless, since the APOD audience is really wide, I think that the images should at least meet some basic astroimaging criteria.

Chris Peterson wrote: ↑Tue Feb 14, 2023 9:09 pm

johnnydeep wrote: ↑Tue Feb 14, 2023 4:02 pm

Chris Peterson wrote: ↑Tue Feb 14, 2023 12:21 am

The 18 spikes on Mars are what you get with a nine-bladed iris on the camera lens, which is a very common number. Instead of a circular aperture you have a polygon with 9 sides (a nonagon). Each straight edge creates a pair of diffraction spikes. So you end up with 18.

Ion tails are often quite straight because they are driven by high speed solar wind and point directly away from the Sun. Dust tails are often much more diffuse because they diffuse evenly away from the comet and then their particles move at different speeds depending on whether they are inside or outside the parent body orbit. And they interact with solar radiation, not the solar wind, which results in a much more scattered direction for these large particles (as opposed to the gas molecules or atoms that make up the ion tail).

Thanks. I get the nonagon aperture explanation. As for dust -vs- ions/atoms being acted upon by radiation -vs- solar wind, does the radiation not affect ions/atoms simply because they are much smaller than (the vast majority) of the wavelengths hitting them? And why doesn't the solar wind exert a force on the dust? Or is it just that the force is tiny relative to the dust grains? [ Bonus question: what's the force of solar radiation compared to that of the solar wind on an aluminum foil square foot at the distance of Earth's orbit? (I assume the material making up that square foot matters a great deal as well?) ]

The solar wind consists of charged particles, which interact electromagnetically with the ion tail. Photon pressure is exerted when photons are reflected by a surface (or absorbed and re-emitted), with a partial transfer of momentum. A macroscopic particle is more likely to interact with a photon (or photons) than a small molecule. And the forces generated by the electromagnetic interaction are much larger. So the solar wind dominates the ion tail. As the dust tail is largely neutral, its interaction with the solar wind is much smaller.

johnnydeep wrote: ↑Tue Feb 14, 2023 4:02 pm

Chris Peterson wrote: ↑Tue Feb 14, 2023 12:21 am

johnnydeep wrote: ↑Mon Feb 13, 2023 8:55 pm So why are there 18 (I think) diffraction spikes on Mars? And why is the ion tail so thin and arrow-straight compared to the broad and curved dust trail? I guess this is a question about comet tails in general now that I think about it. Both tails are made of matter (ions/dust) in orbit while also being pushed by sunlight, so why don't they look roughly similar?

The 18 spikes on Mars are what you get with a nine-bladed iris on the camera lens, which is a very common number. Instead of a circular aperture you have a polygon with 9 sides (a nonagon). Each straight edge creates a pair of diffraction spikes. So you end up with 18.

Ion tails are often quite straight because they are driven by high speed solar wind and point directly away from the Sun. Dust tails are often much more diffuse because they diffuse evenly away from the comet and then their particles move at different speeds depending on whether they are inside or outside the parent body orbit. And they interact with solar radiation, not the solar wind, which results in a much more scattered direction for these large particles (as opposed to the gas molecules or atoms that make up the ion tail).

Thanks. I get the nonagon aperture explanation. As for dust -vs- ions/atoms being acted upon by radiation -vs- solar wind, does the radiation not affect ions/atoms simply because they are much smaller than (the vast majority) of the wavelengths hitting them? And why doesn't the solar wind exert a force on the dust? Or is it just that the force is tiny relative to the dust grains? [ Bonus question: what's the force of solar radiation compared to that of the solar wind on an aluminum foil square foot at the distance of Earth's orbit? (I assume the material making up that square foot matters a great deal as well?) ]

Chris Peterson wrote: ↑Tue Feb 14, 2023 12:21 am

johnnydeep wrote: ↑Mon Feb 13, 2023 8:55 pm So why are there 18 (I think) diffraction spikes on Mars? And why is the ion tail so thin and arrow-straight compared to the broad and curved dust trail? I guess this is a question about comet tails in general now that I think about it. Both tails are made of matter (ions/dust) in orbit while also being pushed by sunlight, so why don't they look roughly similar?

The 18 spikes on Mars are what you get with a nine-bladed iris on the camera lens, which is a very common number. Instead of a circular aperture you have a polygon with 9 sides (a nonagon). Each straight edge creates a pair of diffraction spikes. So you end up with 18.

Ion tails are often quite straight because they are driven by high speed solar wind and point directly away from the Sun. Dust tails are often much more diffuse because they diffuse evenly away from the comet and then their particles move at different speeds depending on whether they are inside or outside the parent body orbit. And they interact with solar radiation, not the solar wind, which results in a much more scattered direction for these large particles (as opposed to the gas molecules or atoms that make up the ion tail).

Roberto Colombari wrote: ↑Tue Feb 14, 2023 2:37 pm There remain few points that are really a little bit confusing at least for me.
You shot the Comet-Mars conjunction from sunset 'till 22:45, local time approximately.
At this time there's still a good amount of sky (Jupiter, Cetus, etc...) between them and the horizon where they'll set later one. Why can't we see them in the image?

Cheers

What I did was to take the foreground exposure after sunset during the blue hour pointing the camera north west where, as planned with Stellarium, the comet would set early in the morning of the 11. Then, from the exact same tripod position, I tilted the camera up and framed the comet with mars (and part of the dark nebula). I then took a series of exposures until 30 minutes more or less after moonrise…
[...]
Then I combined blended the sky with the foreground.

Donato wrote: ↑Tue Feb 14, 2023 8:05 am Dear @Jfgout and @Ann,

Thanks for your review even though frankly I believe you are a bit too strong in your words and frankly, especially from professionals or anyway experts, I would expect a bit less aggressive/offensive tones and more constructive words… anyway let me please try again

I clearly mentioned that this is a composite image. Please check yourself my IG page… so the whole presumed root cause of hiding things etc is a bit difficult to understand for me as from the very beginning I have not hidden it is indeed a composite image.
Please check yourself in stellarium (I hope to find a way to paste a screenshot) and you will see that the sky is aligned using celestial/equatorial coordinates. I could have used azimuthal coordinates but I preferred to use celestial ones when taking the sky… shall I be killed for this ? Not sure frankly
Indeed I augmented the saturation in post processing as already explained: it is my personal opinion (and as such I might be totally wrong) that in 100% of astro photography pictures the saturation is increased in post…maybe I could have done it better but, once again, shall I be killed for this ? Not sure


Bottom line is at least for me: as a non professional who is indeed prone to errors (even though I giorni was able to explain myself and how I imaged the picture), I would have expected a significant more constructive criticisms and not attacks like I have read… or at least this is what I do in my profession/hobbies when I see some opportunity for improvements

Please check yourself in stellarium (I hope to find a way to paste a screenshot) and you will see that the sky is aligned using celestial/equatorial coordinates. I could have used azimuthal coordinates but I preferred to use celestial ones when taking the sky…

Roberto Colombari wrote: ↑Tue Feb 14, 2023 12:53 pm From Gornergrat you spot Monte Cervino a few degrees South when looking to straight to West; let it be, as you said, azimuth between 260º and 265º.
Now, reading what they guy wrote ("I shot Mars and the Comet till the Moon rise" [i.e., ~22:45 local time]), it's not so unlikely to have Mars on that side of Monte Cervino.

Roberto Colombari wrote: ↑Tue Feb 14, 2023 12:37 pm > can you please tell me how can I attach an image when posting a reply so that i can attach my screen shot

You have to upload the screenshot on postimage.org, for instance, get the direct link to the image and put it here.

> you rotated the celestial coordinates by ~180-45=135 degrees instead of rotating by 45 degrees

I've simply aligned the sky of your picture with Stellarium. If you look at it both the screenshots have the same position angle, more or less.
The point that I have probably missed is that you shot the comet the night between 10 and 11 of February, right? When it really had further north declinations than Mars. I thought you shot it the next night when it got southern.

jfgout wrote: ↑Tue Feb 14, 2023 2:40 am
2) I have strong doubts about the location the sky relative to the mountain. This one is tricky to check without knowing the exact location of where the picture was taken. I'm going to assume that it was taken from the Gornergrat observatory area. This would put the summit of Matterhorn at a 265 degrees heading. When Mars was ~5 degrees above the horizon on that day, its azimuth was 300 degrees. So (assuming that I did not mess up too much my guess about the location from where the photo was taken), not only is the orientation of the sky not correct, it is also not placed correctly relative to the foreground. Mars should be on the other side of the Matterhorn.

jf

Ann wrote: ↑Mon Feb 13, 2023 7:25 am
Well, what do you think? It's the same dark nebula, isn't it?

And isn't it interesting that the photographer has managed to bring out this nebula? It sure isn't often that we see dark nebulas showing up in images that are meant to show us something else entirely. I'm not talking about iconic dark nebulas like the Coalsack Nebula or the Pipe Nebula, but anonymous and unfamiliar dark nebulas like Barnard 22.

This certainly says something about how the photographer created his image. But I'll leave that to the many photo experts (Chris?) at Starship Asterisk* to explain.

Ann