| Latest revision |
Your text |
| Line 20: |
Line 20: |
| | | | |
| | The size of the circle could be more accurately estimated by noting that the majority of phones have between a 4.7 to 5.8 inch diagonal (https://deviceatlas.com/blog/viewport-resolution-diagonal-screen-size-and-dpi-most-popular-smartphones). While aspect ratios vary, that seems a decent approximation for the diagonal of the image, and from that, the size of the circle could more accurately estimated from its pixel size relative to the image diagonal. Overkill, though, I know. [[Special:Contributions/172.70.131.122|172.70.131.122]] 16:55, 22 March 2022 (UTC) | | The size of the circle could be more accurately estimated by noting that the majority of phones have between a 4.7 to 5.8 inch diagonal (https://deviceatlas.com/blog/viewport-resolution-diagonal-screen-size-and-dpi-most-popular-smartphones). While aspect ratios vary, that seems a decent approximation for the diagonal of the image, and from that, the size of the circle could more accurately estimated from its pixel size relative to the image diagonal. Overkill, though, I know. [[Special:Contributions/172.70.131.122|172.70.131.122]] 16:55, 22 March 2022 (UTC) |
| − |
| |
| − | "Most are undetectable by even our most powerful astronomical instruments today," - surely the point is that they ''are'' all detectable by the most powerful instruments, otherwise we could not count how many (typically) there are. It's just that we ''need'' more than your 'average' telescope, i.e. Hubble/Webb. The HDF image shows 3,000 items in a solid-angle approximately 1/24millionth of the sky, by the way, which is (at 50cm radius) approximately an eighth of a mm². 50,000 <s>stars</s>galaxies would be in ~2mm² of such an image, which is a circle almost 0.8mm in radius - if I haven't slipped up somewhere in the mental arithmatic (someone will tell me that I have, probably!). But that seems to relate well to the scenario suggested. [[Special:Contributions/141.101.98.145|141.101.98.145]] 20:29, 22 March 2022 (UTC)
| |
| − |
| |
| − | :"Surely the point is that they ''are'' all detectable by the most powerful instruments" - no, not necessarily. I figure that we can guess at the number of galaxies out there without being able to detect them all - by estimating the density of galaxies and considering the size of the universe, for example; and it may be that some galaxies are so far away and that the universe is expanding at such a rate that energy from those galaxies has not yet reached us and might never. - [[User:Brian Kendig|Brian Kendig]] ([[User talk:Brian Kendig|talk]]) 20:47, 22 March 2022 (UTC)
| |
| − | ::Both those points are (differently) addressed by the fact that we're talking about the ''Observable Universe''.
| |
| − | ::We're already seeing to the edge of where galaxies are. In reality, as far back in time as we can, when galaxies and their composition of stars were about as young as they could be, meaning that there's not many things yet to be seen beyond (though whatever we ''do'' end up seeing is going to be interesting to science).
| |
| − | ::Anything whose image will never reach us is beyond the limit of the O.U. and is, by definition, unknowable and uncountable.
| |
| − | ::(Maybe the interface between the matter and antimatter remnants of the original ''actually'' balanced universe is beyond this effective limit? Or we may indeed have an infinite universe that, if we could see it all, means there's ''no'' patch of dark sky, because there's always something bright in whatever bit of the sky we look, at whatever scale or level of zoom.)
| |
| − | ::Actually, I tend to suspect that the real problem is that the universe has a wrap-around topology which means that looking far/long enough in any direction (barring expansion or even big-rip limits to what we could see) means we start seeing things from the opposite side of the entire field of view but from the other direction... Then everything closer to us (beyond that) then eventually, ourselves. And beyond us (*hand-wave away what happens if some strangeness of the situation means we're effectively the thing we see 28.5 gigaparsecs or more away ''in every direction at once'' and so can't be seen beyond... ;) *) a smaller copy of everything we's been peering between to see our current view....
| |
| − | ::Not that we could (speed of light + age of universe + continuing expansion of universe + any acceleration of expansion + something else we probably don't know of yet), but I have an unhealthy affinity for the concept of a boundless but finite universe, like the 3D surface of a hypersphere where looking in any direction (including a time-component!) eventually wraps-around on a Great Circle analogue. ;-p
| |
| − | :: ...anyway, the point being that if we have a problem with counting visible objects, it's more likely that we can be counting some things twice or more (cosmos-wide gravitational lensing?). Anything truly beyond visibility is irrelevent, and probably won't become any more relevent any time soon. But we can develop means to better see things that aren't that easy to see, yet can be seen with enough effort. [[Special:Contributions/172.70.162.147|172.70.162.147]] 23:18, 22 March 2022 (UTC)
| |
| − |
| |
| − | :Also note that the Hubble Deep Field depicts approximately 50,000 <i>galaxies</i>, not just stars. See [https://en.wikipedia.org/wiki/Hubble_Deep_Field]. - [[User:Brian Kendig|Brian Kendig]] ([[User talk:Brian Kendig|talk]]) 20:50, 22 March 2022 (UTC)
| |
| − | ::My error, now corrected. I was refering to the galaxies that both the comic and the HDF were enumerating, but I ''wrote'' stars - for reasons best known to my dithering mind at the time. But nice to see you're reading my waffle and actually paying attention. ;) [[Special:Contributions/172.70.162.147|172.70.162.147]] 23:18, 22 March 2022 (UTC)
| |
| − |
| |
| − | I measured the size of the circle compared to the frame width (it's 1/40 of the frame width). I left the other calculations alone, but someone should probably re-scale them, as they presume that the frame is 40mm wide, which seems small for "fullscreen on your phone". Or maybe the calculations are wrong; if I had to bet between Randall and some random Internet editor (myself being included in that category) I'd bet on Randall. -- [[User:Dtgriscom|Dtgriscom]] ([[User talk:Dtgriscom|talk]]) 10:29, 23 March 2022 (UTC)
| |
| − |
| |
| − | I question the comment about the title text being 'sarcasm' on the basis that "we know that galaxies contain billions of stars and most of them will have planets" (I paraphrase). My view is that most of the 50,000 galaxies are likely to be very young, and we believe that the first generation of stars were large, few and short lived.
| |
| − | As to whether they would have had multiple planets, this is an open question. Certainly, there wouldn't have been rocky planets, as the stars will have formed from the elements formed in the original big bang, which was almost exclusively Hydrogen and Helium, with essentially no heavier elements to form anything like rocky planets.
| |
| − | Gas giant planets may have formed alongside the first massive stars, but we just don't know.[[User:Owengwynne|OwenGwynne]] ([[User talk:Owengwynne|talk]]) 12:00, 23 March 2022 (UTC)
| |
| − |
| |
| − | Adding to the discussion about planets in galaxies: Most galaxies in the universe are [[wikipedia:Dwarf galaxy|Dwarf Galaxies]] (see also the external sources of the Wikipedia article). DG have very distinct physical properties than our Milky Way, they contain older and/or bigger (=hotter) stars, less heavy elements (>He) and are more compact, i.e., there are more stars in less space. They also seem to have more dark matter per visible mass than larger galaxies. All of these properties make it more improbable for the stars to form planets, and even more so small rocky ones. And it probably also makes it more difficult to create life, as the cosmic vicinity of each star is much more unstable.
| |
| − |
| |
| − | Not relevant, but a point about the numbers involved. It's estimated that there are 200 billion galaxies in the observable universe - undoubtedly a large number. It is also estimated that there are 3 ''trillion'' trees on Earth, so maybe 15 trees for every galaxy.
| |
| − |
| |
| − | == Dwarfs ==
| |
| − |
| |
| − | The discussion ignores dwarf galaxies. Some have diameters as small as 100 light years and contain as few as 1000 stars. (Examples available at Wikipedia's "List of Satellites of the Milky Way".) Apparently the title text refers to dwarf galaxies, which could be 90% of all galaxies.
| |
| − |
| |
| − | Of course, there is probably no obvious limit between a dwarf galaxy and a regular galaxy. At the other end of the scale, there is no obvious limit between a dwarf galaxy and a globular cluster (or just a bunch of stars) in intergalactic space.
| |
