Talk:Gravitational microlensing

Latest comment: 2 years ago by Bobsd in topic Use of the term "constrain"

Well, the article is not very well descibed, but it is my first Wiki article. The previous article (stating that a planet magnifies the light of its host star) was just good-old wrong, since it is the planet around the lens causing a deviation in the lightcurve!

There are plenty of potential issues to add: Microlensing is a tool producing many papers every month, so there is plenty of potential subjects to cover.

--Christianvinter 14:56, 12 July 2005 (UTC)Reply

Illustration of microlensing

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The NASA figure illustrating the effect of microlensing is technically wrong: The gravitational field of the lens star does not focus the light of the observed source star like a convex lens. Instead, light rays closer to the lens star experience a stronger bending (rather than a weaker one). Can this figure be replaced? I have contacted NASA JPL on this issue.

Martin Dominik, 21 February 2006

There are plenty of good illustrations about microlensing floating around on the web, but I don't know how to get around the copyright restrictions. David s graff 13:13, 20 March 2006 (UTC)Reply

Fresh Start

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I felt like this page needed a new start, so I did a major overhall. Rather than adding my own work to some of the previous work, I included nearly all the pre-existing links and ideas to my own description. I've introduced many sections, currently blank, to be filled in later, but done some major overhall on the links to collaborations. My apologies to the previous contributors if I've left something out.

I don't know why, but it seems to me that Astronomy articles lag behind other technical fields in Wikipedia. Perhaps Astronomers are less likely to use Wikipedia than computer scientists. Perhaps its just because as an Astronomer, my expectations are higher. Or perhaps the neglect of this article reflects how the once red-hot field of microlensing has passed its glory. David s graff 10:35, 21 March 2006 (UTC)Reply

Detecting Planets

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Something that is not clear in the article is how different things are detected. As far as I can tell (from reading), microlensing occurs when a body passes in front of a distant light source. But that sounds no different from gravitational lensing.

From the attached article (Low-Mass Exoplanet), it sounds more like this: Gravitational microlensing is when a body passes in front of a gravitational lens. So a distant star, a closer star, and the closer star's planet all align. We detect the planet because of the change in the lens effect as the planet joins the alignment. (The planet passes in and out of alignment while the other stay aligned.) Does that sounds like an accurate description? --Daev 16:11, 17 April 2006 (UTC)Reply

Microlensing is gravitational lensing - it's just on a smaller scale. The detection of planets using it is when the lensing star has a planet which also does some of the lensing. Mike Peel 16:55, 17 April 2006 (UTC)Reply
Well, yes. But it's a subset isn't it? Like red light is a subset of visible light. There's no point in a separate article if the subset equals the superset. Since the article doesn't seem to mention anything that differentiates the two, I'm confused.
Unless you mean that gravitational lensing is the theory and microlensing is the practice, or something like that.
Saw your edits and modified. I assume you meant transit method? Or perhaps, astrometry. I'm not so sure that it should be in the Exotic Microlensing section (is this really an exotic use for it?). --Daev 17:27, 17 April 2006 (UTC)Reply
A better example would be visible light being a subset of the EM spectrum. Gravitational lensing is generally split into Strong (usually just called Gravitational Lensing), Weak and Microlensing.
This article is very much a work in progress atm; when I get the time, I'll add a lot more to it.
You were correct with transit, not transient. I've been working a lot with transient events recently, hence the slip. Thanks for correcting it. I put it in the 'exotic' section, as it's not a common thing to detect in microlensing events - of the order of 1 in 100 microlensing events - hence it's 'exotic', i.e. different from the norm. Mike Peel 18:14, 17 April 2006 (UTC)Reply
'Gravitational lensing' means the bending of radiation due to the gravitational field, which can involve any mass scale of the deflector and any distance scale. 'Microlensing' is a special case with a fuzzy definition (in fact, there are at least four different ones, which partially overlap: lensing with unresolved images, lensing with ~ micro-as deflection, splitting of macro-image into micro-images by substructure in a deflector, or lensing by compact objects). Two observed effects are commonly described as 'gravitational microlensing': the variation of lensed quasar images caused by individual stars in the lensing galaxy, and the brightening of background stars in our own or neighbouring galaxies caused by an intervening foreground lens star (galactic microlensing). Planets around the lens star alter the gravitational field and therefore can affect the observed light curve during a microlensing event, which is not a superposition of the effects by isolated planet and host star. Instead, the tidal field (and higher orders) of the source star at the position of the planet significantly increases its detection probability. The duration of the planetary signal (hours to days) is much shorter than the orbital period, so that the motion of the planet relative to its host star can typically be neglected. MD:astronomer 22:26, 17 April 2006 (UTC)Reply

I've tried to fix the fuzzyness of the definition of microlensing with a new one: Microlensing is the subset of gravitational lensing whose variations in time can be measured. Typically, this means that the lens mass must be small enough that it will cross its own Einstein ring radius in less than the time it takes for a graduate student to finish a PhD thesis. The EROS collaboration is analysing our own and MACHOs data for evidence of very long time scale events of order 100s or 1000s of years (see sec. 5.6 of [1]). Although these may not be confirmed as microlensing events (rather than some other very long time-scale variability), the non-detection of these events would allow a limit on dark matter by 100-1000 Mo MACHOs. Any event where the lens mass is so big and far away that it takes millions of years to cross its einstein ring radius, and thus changes too slowly in time to be studied in the time domain, is a "macrolens".

I also disagree with the four definitions by MDAstronomer. It is not true that any lensing event with unresolved images is microlensing. A galaxy can lens a quasar, but have the images be too close to be resolved. This is not microlensing. Likewise,lensing by a compact object does not describe microlensing. "Any" gravitational lens must be physically smaller or about the same size as its own einstein radius to cause any measurable lensing effect. That is why we do not see any lensing effects from the Moon. It is so close that its Einstein radius is tiny. However, if the moon were a few kiloparsecs away, its einstein radius would be larger than its physical radius and it could be a perfectly ordinary microlens. The supermassive black hole at the center of the milky way is a compact object, but it cannot be a microlens... its einstein radius is too big for any changes in lensing to be monitored in time. It could in principle be a macrolens if there were a quasar right behind it. The microlensing at the edges of gravitationally lensed quasars is called microlensing because it causes time-varying effects in the apparent flux of the images. This has been significant because it interferes with attempts to use these gravitational lenses to measure the Hubble Constant.

The time-varying nature of a microlens is the key to all of its observations. And the need to take over large blocks of telescope time to do microlensing has revolutionized time-domain astronomy in general, in part through a bureaucratic reorganization of Telescope Allocation Committees and the advent of dedicated telescopes. There have been great resulting changes not only in microlensing but in searches for supernovae, asteroids, variable stars.

None of the various types of microlensing observations (photometric brightenning, astrometric shift, interferometric visibility reduction due to image splitting, shifts in color, spectrum, or variability amplitude) are strong enough to determine a microlensing event from a single observation. All of them require detecting some change in time, if only because there are plenty of natural causes that can mimic any one of the shifts for a single measurement. For example, how could one seperate a star which was split into two images from an ordinary binary star without time-domain information?

I disagree with Mike's splitting of lensing into strong, weak and microlensing. A lens is strong if it is within one Einstein radius of the line of sight to the source, and weak otherwise. Nearly all photometric microlenses are strong lenses, but astrometric lensing is much more sensitive to weak lensing than photometric lensing. Eddington's verification of general relativity was classic weak astrometric microlensing, and we will use SIM to study weak astrometric microlensing to measure the masses of other stars [2]. David s graff 22:17, 2 June 2006 (UTC)Reply

2nd paragraph

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in the second paragraph, it says: "When a nearby object passes in front of a distant star or quasar, the gravity of the nearby object magnifies the distant star. By detecting that magnification, astronomers can study the near star." Don't we want that last word to be "object," not "star"? Because before we were talking about some object that might not be a star. Am I right? If so, could someone change it? Thanks.

You are right. Changed. Christianvinter 15:43, 5 February 2007 (UTC)Reply
In fact, 'nearby object' is technically wrong. The probability for (phometric) microlensing tends to zero as the lens object gets close to the observer. A lens object half-way between source and observer is ideal. I took that opportunity to rephrase some other paragraphs. When I find some time, I should make further edits with respect to the historic developments. Maybe someone could send me a reminder? MD:astronomer 23:17, 10 February 2007 (UTC)Reply

"the bending of light due to its gravitational field, as discussed by Einstein in 1915, leads to two [sic] distorted unresolved images" - surely that is wrong? That's what you get with a two-dimensional drawing of the phenomenon on a piece of paper, but it really takes place in 3D. — Preceding unsigned comment added by 92.14.30.2 (talk) 23:39, 5 March 2012 (UTC)Reply

reversing the lens?

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Anyone seen comments along the lines of anywhere we are seeing something through a gravitational lens they (if anyone is there) are seeing us? Just looking for refs....--Smkolins (talk) 03:13, 22 March 2008 (UTC)Reply

You mean the Sun-Earth system, the whole solar system or what? If someone was observing the Solar System -- no matter almost which way -- if they were lucky enough to see any planets, it would be completely dominated by Jupiter. Anyway, yes there are papers touching on this subject, and it is relevant to this article at some point. Christianvinter (talk) 10:02, 27 March 2008 (UTC)Reply
There's a fair bit of chatter in the news of forth coming efforts specifically to identify Earth-type planets and I think micro-lensing was mentioned too. I'd presume in a microlensing environment any place we find could see us- certainly picking up Jupiter first but if they have an equivalent scope then they should be able to see Earth. If they are there and watching of course. I suppose that pattern is true of non-microlensing situations too (looking at our system with big enough scopes etc. but I thought of it in the microlensing situation first because it has some extreme distances it covers if you then look at the larger scale lensing. I've not seen references to it yet and would like refs if they are public.--Smkolins (talk) 11:07, 27 March 2008 (UTC)Reply
Microlensing is generally used to study the *lens*, not the *source*, and in particular planet detections are always planets around the lens. When we see a source get lensed, we're studying the object between us and the source, not the source itself. If someone at the source were looking back at us, they could see our sun get lensed, but it wouldn't be especially useful for, say, detecting planets around our sun. Cosmologicon (talk) 23:02, 2 April 2008 (UTC)Reply
Thats not true. Microlensing has been used to study the source stars, and has the potential to search for planets around source stars as well. For example, and as detailed in http://spiff.rit.edu/classes/phys440/lectures/limb/limb.html , microlensing has been used to study limb darkening in source stars and is the only technique to study the surface of single stars besides the Sun and Betelgeuse. I've written a paper describing the use of microlensing to look for planets around source stars: Graff & Gaudi, Astrophysical Journal 2000 David s graff (talk) 19:25, 31 October 2008 (UTC)Reply

More work to be done

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This page seems pretty dead, which is too bad. I'll start bugging my microlensing buddies to help out with it. I've recently added some more text on other observables theta_E and r_E tilde/pi_E, and a new section of discussion of some other effects.

The introduction promises a discussion of how microlensing can be used to study a huge range of phenomena such as cosmic strings. Either we should put in links to papers proposing these different ideas, or discuss them here in the article. David s graff (talk) 16:55, 19 May 2009 (UTC)Reply

Is this a typo? Is there a missing word?

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What the hell does this mean: "...leads to two distorted unresolved images resulting in an observable magnification..." .

Does it mean that the image doubles, but is not resolved, so it just looks slightly bigger?

Or is the "observable magnification" of the light intensity; that is, the image is unresolved and therefore looks the same, but it is brighter? Old_Wombat (talk) 11:38, 22 May 2011 (UTC)Reply

Oh wait, found a better one. http://upload.wikimedia.org/wikipedia/commons/0/0b/Gravitationell-lins-4.jpg
I apparently have no idea how to use links. Sorry. 74.132.249.206 (talk) 14:35, 25 September 2011 (UTC)Reply
See: http://en.wikipedia.org/wiki/File:Gravitational_micro_rev.svg 74.132.249.206 (talk) 14:28, 25 September 2011 (UTC)Reply
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Use of the term "constrain"

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Regarding this paragraph in the lede:

"Microlensing by an isolated object was first detected in 1989. Since then, microlensing has been used to constrain the nature of the dark matter, detect exoplanets, study limb darkening in distant stars, constrain the binary star population, and constrain the structure of the Milky Way's disk. Microlensing has also been proposed as a means to find dark objects like brown dwarfs and black holes, study starspots, measure stellar rotation, and probe quasars[1][2] including their accretion disks.[3][4][5][6] Microlensing was used in 2018 to detect Icarus, the most distant star ever observed.[7][8]"

If you read the sources, you can see that microlensing can be used to enable astronomers to constrain certain otherwise unknown aspects of an investigation ... say an upper limit of some variable. But to say the microlensing can "constrain the structure of the Milky Way's disk", is perhaps overstating the power of gravitational lensing ... The astronomer can use the data obtained to "constrain" their understanding of the thing under investigation, but certainly not the object itself.

I think a preferable word would simply be "understand". Since then, microlensing has been used to understand the nature of the dark matter, etc.

Since this is in the lede, I didn't want to wade in there and rewrite without getting other opinions, in case this use of the word is somehow normal for the subject matter. I'll take a stab at it if I do not hear any objections in the month or so. Bobsd (talk) 18:36, 13 January 2022 (UTC)Reply

Yes, it's a jargonistic usage in physics and some other sciences. It applies to the range of possibilities, in which theoreticians imagine what might be, and more detailed study shows that some part of that range cannot be. For example, we are in a ship and want to know how deep the water is. We know the whole planet can't be water, so it's less than 7000 km deep. We look down, and decide we are seeing 10 meters down and it's all just water. So, it's somewhere in the range of ten meters to 5000 km. We use a sounding weight on a kilometer of rope, and don't hit bottom, so now we have further "constrained" the depth to be between one and 7000 kilometers deep. Similarly, are detectable microlenses more numerous or less numerous, than stars? If we have found that they cannot be less numerous, or cannot be more numerous, we have "constrained" the range of possibilities. This bit of jargon is well understood among practitioners, but we're not writing for practitioners; we're writing for outsiders who are unfamiliar with the jargon of this trade. Jim.henderson (talk) 14:15, 16 January 2022 (UTC)Reply
I think that means we are in agreement. Jargon is often used to avoid the need to be specific. The only current usage in the lede that is specific enough to add any information to the article is "constrain the binary star population" since it points to population, a value that could have some limit. But to use it for "nature" and "structure" is just too broad. I just retired as a software quality engineer, so yeah ... jargon. I'll sleep on making the changes. Thanks for the input. Bobsd (talk) 17:09, 20 January 2022 (UTC)Reply