Starship Asterisk*

MarkBour wrote:Although the four planets are clearly the lead characters in this, I'm also intrigued by the goings-on closer in to the star. There is so much activity there. If our own Sun were imaged similarly, I doubt it would be showing that much activity that far out. Indeed, there are a couple of spots that appear at the end just to the left of HR 8799. I suppose they could even be planets, though that seems pretty unlikely. But then what is all of this stuff? Prominences? Mass ejections? Simply a huge undulating corona? It seems the "inner seething activity" shown here has a radius of about 15-20 AU.

MarkBour wrote:Whoa. Is this the first-ever movie of a solar system? (Given a few appropriate qualifiers.) How about that, Mr. Kubrick !?

WangMaroisKeck20160505.JPG

Although the four planets are clearly the lead characters in this, I'm also intrigued by the goings-on closer in to the star. There is so much activity there. If our own Sun were imaged similarly, I doubt it would be showing that much activity that far out. Indeed, there are a couple of spots that appear at the end just to the left of HR 8799. I suppose they could even be planets, though that seems pretty unlikely. But then what is all of this stuff? Prominences? Mass ejections? Simply a huge undulating corona? It seems the "inner seething activity" shown here has a radius of about 15-20 AU.

DavidLeodis wrote:I am uncertain as to where the 4 planets are in the video. In information from one of the links in the explanation it states "The forth HR 8799 planet was found after further observations in 2009–2010. That planet orbits inside the first three planets”. I wonder therefore if the very faint object to the upper left of the star is one of the 4 or not, as there are 3 bright objects that I assume to be planets on the right of the star. If that on the left is one of the 4 planets I wonder why it was spotted before the 4th planet as that seems likely to be one of the 3 bright ones. Am I correct in that the faint object on the left is one of the 4 planets?

Ann wrote:Today's APOD, by the way, was taken by the Earth-based Keck telescope. Since neither ultraviolet nor infrared light penetrates the Earth's atmosphere very well, we should assume that today's APOD was taken at a visible wavelength.

SaraBiga wrote:Were the images featured in the animation resolved from reflected light in the ultraviolet range like the examples in the article that Ann linked to? Or am I misreading it? If so, is there a reason for reflected light from exoplanets to be best captured in the ultraviolet?
Also, I think that the method used for getting the images (reflected light, wavelength range) should have been included in the caption, as I genuinely believed we could only 'infer' exoplanets, not 'see' them (of course if you know where to look for from some other method, as it was sensibly pointed out in another comment), but also as a general good rule for educating us 'profanes'...

SaraBiga wrote:
Were the images featured in the animation resolved from reflected light in the ultraviolet range like the examples in the article that Ann linked to? Or am I misreading it? If so, is there a reason for reflected light from exoplanets to be best captured in the ultraviolet?
Also, I think that the method used for getting the images (reflected light, wavelength range) should have been included in the caption,

Chris Peterson wrote:

neufer wrote:

Chris Peterson wrote:
In some cases, perhaps. However, the IR band used with ground-based adaptive optics only slightly enhances thermal IR emissions, which are largely blocked by the Earth's atmosphere. In this case (HR 8799) we are seeing the planets by the reflected light of the star, not by their own IR emission.

Did you miss the part about HR 8799's 4 planets still glowing red hot due to their young age.

No. Did you miss the discussions in the linked references that explain that we can these planets by the reflected light of the star, and that they have also been imaged in visible light using small telescopes without adaptive optics? (I understand that the highest resolution images, made with the GPI, do record some thermal emissions. But this system is visible by reflected light as well.)

neufer wrote:

Chris Peterson wrote:In some cases, perhaps. However, the IR band used with ground-based adaptive optics only slightly enhances thermal IR emissions, which are largely blocked by the Earth's atmosphere. In this case (HR 8799) we are seeing the planets by the reflected light of the star, not by their own IR emission.

Did you miss the part about HR 8799's 4 planets still glowing red hot due to their young age. :?:

Ann wrote:However, the star Lambda Boötis itself is much bluer than HR 8799 (with a B-V index of around 0.10, versus about 0.27 for HR 8799), and Lambda Boötis is about three times brighter than HR 8799, some 16 times solar, versus about 5 times solar for the star of today's APOD.

Ah, stellar classifications, what a fascinating subject! :D

Chris Peterson wrote:

neufer wrote:
I think the key is that they are all young stars with young hot planets which show up well with infrared adaptive optics.

In some cases, perhaps. However, the IR band used with ground-based adaptive optics only slightly enhances thermal IR emissions, which are largely blocked by the Earth's atmosphere. In this case (HR 8799) we are seeing the planets by the reflected light of the star, not by their own IR emission.

Did you miss the part about HR 8799's 4 planets still glowing red hot due to their young age.

Keck's adaptive optics run from 1 micron to 5 microns (i.e., 3,000K to 600K 'thermal' IR).

https://en.wikipedia.org/wiki/HR_8799 wrote:
HR 8799 is a young (~30 million-year-old) main-sequence star with roughly 1.5 times the Sun's mass and 4.9 times its luminosity.

On 13 November 2008, Christian Marois and his team announced they had directly observed three planets orbiting the star with the Keck and Gemini telescopes in Hawaii, in both cases employing adaptive optics to make observations in the infrared. The 4 planets are still glowing red hot due to their young age.

mudkip177 wrote:The orbits are apparently much longer compared to earth years. Does that imply these are outer planets? What else is implied? TY -- B

Chris Peterson wrote:

Ann wrote:And once again, it is an A-type star that provides really spectacular images. (HR 8799 is an A5V-type star, aout five times more luminous than the Sun and bluer in color.)

Strictly speaking, this is not an A-type star. Based on its hydrogen emission lines and temperature, it is best classified as F0 V. However, its heavy element absorption line spectrum suggests a classification of A5 V. It is a member of a special class of low metallicity pulsating stars called Lambda Boötis stars. Its formal spectral classification is kA5 hF0 mA5 V; λ Boo. This breaks down to

A5 characteristics, spectra with interstellar absorption features;
F0 characteristics, WR star with emission lines due to hydrogen;
A5 characteristics, enhanced metal features;
Lambda Boötis class.

A spectral mess, for sure!

neufer wrote:I think the key is that they are all young stars with young hot planets which show up well with infrared adaptive optics.

Ann wrote:And once again, it is an A-type star that provides really spectacular images. (HR 8799 is an A5V-type star, aout five times more luminous than the Sun and bluer in color.)

Ann wrote:
And once again, it is an A-type star that provides really spectacular images. (HR 8799 is an A5V-type star, aout five times more luminous than the Sun and bluer in color.) Other A-type stars with spectacular planets are Fomalhaut, spectral class A3V, some 17 times more luminous than the Sun, and Beta Pictoris, also spectral class A3V, 9 times brighter than the Sun.

It seems "intuitively correct" that more massive stars should have more massive planets, although I have no idea if this is really the case. Nevertheless, it seems certain that A-type stars are becoming a treasure trove when it comes to offering up spectacular planets that can be actually imaged rather than just inferred.

https://en.wikipedia.org/wiki/Beta_Pictoris wrote:
Beta Pictoris (β Pic, β Pictoris) is 1.75 times as massive and 8.7 times as luminous as the Sun. The Beta Pictoris system is very young, only 20 to 26 million years old, although it is already in the main sequence stage of its evolution.

https://en.wikipedia.org/wiki/HR_8799 wrote:
HR 8799 is a young (~30 million-year-old) main-sequence star with roughly 1.5 times the Sun's mass and 4.9 times its luminosity.

On 13 November 2008, Christian Marois and his team announced they had directly observed three planets orbiting the star with the Keck and Gemini telescopes in Hawaii, in both cases employing adaptive optics to make observations in the infrared. The 4 planets are still glowing red hot due to their young age.

https://en.wikipedia.org/wiki/Fomalhaut wrote:
Fomalhaut is a young star, for many years thought to be only 100 to 300 million years old, with a potential lifespan of a billion years. A 2012 study gave a slightly higher age of 440±40 million years. Fomalhaut's mass is about 1.92 times that of the Sun, its luminosity is about 16.6 times greater, and its diameter is roughly 1.84 times as large.

Roger wrote:It is approximately along a line between the western two stars of the Great Square of Pegasus, halfway between those two stars.