Friday, March 4, 2016

Radial Velocity method: Moving around a common center of mass

The Radial Velocity (RV) method is the second-most successful technique to find exoplanets. In contrast to the more successful transit method it has an important advantage: it gives us the mass of the planet. However, it also has at least one major drawback: it is more complicated.

In this post I will try to explain how it works. There are two things you have to realize before you understand why and how the RV method can be used to detect planets.

(1) Although we usually say that a planet orbits a star, this is only half true. Actually, the planet and the star move around a common center of mass. So not only the planet is moving, but the star itself is moving too; however, it is of course not moving as much because it has much more mass.

(2) The light emitted by a moving object is shifted in wavelength/frequency. This is called the Doppler effect and works for all kinds of waves, e.g. sound waves and light. Because the star is moving, the light it emits is shifted to longer wavelengths when moving away from the observer and to shorter wavelengths when moving towards the observer. Light shifted to longer wavelengths is called red-shifted, for shorter wavelengths it is called blue-shifted.

Because the RV method really is about movement, I prepared a little video instead of a static diagram this time. It shows that planet and host star move around a common center of mass indicated by the black cross, and that the light coming towards the observer is shifted in color because of the movement of the star. Only the movement in the direction of the observer is important, which is called the radial movement. This is where the method gets its name from: we only measure the radial component of the velocity.

In the movie the stellar light is not shifted when the planet is exactly behind or in front of the star. In these positions the radial velocity of the star (and the planet too) is zero and no wavelength shift is caused. The higher the velocity of the star in the direction of the observer is, the higher is the wavelength shift.

This also means the RV method works best if we look at a planetary system edge-on. The observer's viewing angle on the system is called inclination i. If i=90° we look at the system directly edge-on and the movement of the star is largest. If i=0° we look at the system from above and the star is not moving in our direction at all - and the RV method does not work anymore.

I tried to illustrate this in a second movie. Now the inclination of the system in respect to the observer has changed and our viewing angle is close to 0°. The radial movement of the star (in direction towards and away from the observer) is much smaller now and, thus, the wavelength shift is smaller too.

This inclination plays an important role, because observers usually do not know its exact value. However, the radial velocity of the star depends on it and, therefore, also the measured mass of the planet depends on the inclination. This is why planetary masses derived with the RV method are described as m sin(i). m is the true mass of the planet and sin(i) is the sine of the inclination. Observers do not measure the true mass, but its "projection" on the angle i. So if we measure a low mass for a planet, this can mean two things: either we really have a low-mass planet with an angle i close to 90°, or we have a higher mass planet with an angle closer to 0° (or 180°). In the end we cannot be sure what kind of planet it is until we know what the inclination is.

The RV method only works as good as we can measure the radial velocity of the star, and this is where the really difficult part begins. If you want to measure the radial velocity of the Sun caused by the gravitational drag of the Earth, you have to have an instrument measuring velocities with a precision of about 10 cm/s. This is tiny. Just compare it to the preferred walking speed of humans, which is already more than a factor 10 higher. The rotation speed of the Sun is roughly 2 km/s. The radius of the Sun is 700000 km, which means you have to measure a change in distance of 10-10 of the radius of the Sun per second. Or, finally, make yourself aware that Earth orbits the Sun with a speed of about 30 km/s.

Today the best instruments measure radial velocities down to below 1 m/s. Wavelength-stabilized spectrographs observe spectra of the stars and the spectral lines within these spectra can be used to determine their shift due to the Doppler effect. It might be hard to understand how difficult it is to get down to 1 m/s - or even 10 cm/s - if one has never tried to get velocities out of a spectrum. Maybe I can try to show this is one of my next posts in more detail, but think about it that way: the minimum width of a spectral line for the Sun with a rotation velocity of 2 km/s is at least a few km/s. This means you want to measure the position of the line more than a factor 1000 better than its width. The reason why this works at all is that the spectra have hundreds or even thousands of lines.


Thursday, March 3, 2016

Exoplanets in the Milky Way: The view from above


Finally my figure of the positions of exoplanets in the Milky Way is finished. Again you see my artist impression of a view from above on the Milky Way, but this time I added the positions of all the known exoplanets for which I could find a distance measurement. The exoplanet data are coming from exoplanet.eu. There are a little bit more than 1000 exoplanets in this map, which means we only have distances for about half of all the exoplanets we know today.

The methods used to detect the planets are indicated by different colors and symbols. Most of the planets in this plot come from the RV method (618) and not from transits (313). At first this might be unexpected, but on average stars observed in RV campaigns are closer to the Sun than transit host-stars because a spectrum needs more light than a brightness measurement. For closer stars the distance is usually easier to determine than for stars far away, for example when using the parallax method.

A quite large number of planets detected by transits orbit stars further away than several thousand light years. This is especially true for those regions in the sky that were observed intensely by transit surveys as for example Kepler. I marked the Kepler field-of-view in the map where several distant planets were found.

The most distant exoplanets, however, were found by microlensing surveys - with the exception of the SWEEPS transit survey. These distant microlensing planets are all located on a line pointing to the center of the Milky Way. Why? This is due to the way the microlensing method works: to see an event we do not only need a planet around a star, we also need a background star which gets 'lensed'. Because the density of stars is highest in the galactic center, the probability to get a lensing event is largest there. Since it is a method which only requires photometric observations, you can see events caused by very distant planetary systems as long as the lensed source is bright enough - or the lensing effect strong enough - to be seen by your telescope.

In case you wonder how scientist get the distances to planetary systems that are so  far away: This would lead too far in this post, but it is not by using the parallax. In these cases distances are usually estimated and, thus, the uncertainties are quite large. Because of the large uncertainty on the distance of the SWEEP exoplanets, one might argue that they possibly are not that far away.

I leave you with a list of names for the most distant planetary systems which are further away from the Sun than 20000 light years. The last two are transiting planets, the rest were all detected in microlensing events.

20961 ly  -  MOA-2010-BLG-353L b
21190 ly  -  OGLE-2005-390L b
22168 ly  -  OGLE-2008-BLG-355L b
22820 ly  -  OGLE-2008-BLG-092L b
23961 ly  -  MOA-2011-BLG-262L b
24058 ly  -  MOA-2011-BLG-028L b
25102 ly  -  MOA-2011-BLG-293L b
25232 ly  -  MOA-2011-BLG-322L b
26732 ly  -  KMT-2015-1 b
27710 ly  -  SWEEPS-4
27710 ly  -  SWEEPS-11

What Hipparcos saw and Gaia will see


In the last post I wrote about the Hipparcos mission and I would like to follow up with a few more nice plots. Hipparcos used the geometric parallax to measure the distances of stars in a rather limited volume around the Sun. Although it measured more than 100000 distances, this covers only a tiny fraction of stars in our Milky Way. Whether Hipparcos can measure the distance to a star depends mainly on two things: The star has to be bright enough to be seen and it has to be close enough to move in the sky by a parallax at least as large as the measurement precision of the instrument.

The latter is slightly better than one milli-arcsecond for Hipparcos and means that only stars that are not much further away than several thousand light years can be measured in distance. The first criterium is called the limiting magnitude, which is about 12 for Hipparcos. It means that stars fainter than an apparent magnitude of 12 are not bright enough to determine the distance. The apparent magnitude depends on the intrinsic brightness of the star (the absolute magnitude) and on the distance - if a star is further away it appears to be fainter. If a star is far away but very bright, it can still be seen by Hipparcos, although the distance cannot be measured if it is so far away that its parallax is smaller than the measurement precision of Hipparcos.

The picture on top shows you again my artist impression of the Milky Way in inverted colors. This time I try to show how far Hipparcos could see for a specific type of star which is called the spectral type. A star with a spectral type M is cooler than the Sun and, therefore, its absolute brightness is lower. The hottest and most luminous stars are O stars. The Sun is a G2 star which has a (surface) temperature of slightly below 6000° Celsius. Unsurprisingly, more luminous stars like O stars can be seen in a much larger distance than cooler stars like F or even M stars. The distance to which a G2 star can be seen by Hipparcos is so small, its smaller than the size of the cross marking the position of the Sun in the picture. But O stars are so very bright, they can be seen throughout the entire galaxy.

In the upper left corner of the plot on top you find the color code for the type of the star and the distance to which this type of star can be seen by Hipparcos. Keep in mind that this does not necessary mean that the distance can be measured just because Hipparcos would be able to see the star.

The region close to the Sun is hard to see in the plot, so I prepared some more pictures to show what is going on there. On the left you see a histogram of the number of stars for a certain distance from the Sun. It shows that within a radius of 100 light years Hipparcos saw 2466 stars, in a radius of 20 light years 'only' 75 stars. The closest stars to the Sun are between 4 and 5 light years away in the Alpha Centauri system: Proxima Centauri, alpha Centauri A and alpha Centauri B.

For the first 400 to 500 light years the number of stars Hipparcos saw increases, then the numbers start to go down. The larger the distance gets, the larger the volume of the shell of the sphere gets in which we are looking for stars. And for the first few hundred light years this is close enough to see more and more stars. However, stars with a low absolute magnitude like M stars get 'invisible' for Hipparcos after a distance of about 120 light years. The further we go away, the more stars become undetectable by Hipparcos. At about 400 to 500 light years the increasing volume of the shell is counter-balanced by the quickly decreasing number of stars that still can be seen, and the absolute numbers start to go down. In a distance of about 4300 light years Hipparcos does not even see A stars anymore, which is where the mission provides virtually no distance measurements anymore. In the cumulative distribution you can see that in a distance of about 500 light years about 50 % of all the stars are located that Hipparcos could measure distances for.

So what ca we do to see more stars and measure their distances? To see more stars we need a better telescope, which practically means a larger telescope. To get larger distances we need a better measurement precision. This is what Gaia is supposed to do. Gaia will have a limiting magnitude of about 20 and will detect stars that are 1600 times fainter than what Hipparcos could see. The precision to measure the parallax will be better than 10 micro-arcseconds, which is more than a 100 times better than Hipparcos; distances of 300000 light years, which is three times the assumed diameter of the Milky Way, should be possible for very bright stars.

The plot at the bottom shows what Gaia will be able to see in terms of brightness. Hipparcos could see a G2 star only in the close neighborhood of the Sun, Gaia will see G stars in a radius of more than 40000 light years - larger than the distance from the Sun to the center of the Milky Way. And stars as luminous as F stars will be visible virtually all over our entire Galaxy.

This way it is assumed that Gaia will see about 1 % of all stars in the Milky Way. This is more than 1 billion stars! However, you still might think: Why 'only' one percent if it can look so 'far'? Well, this is because more than 70 % of the stars in our Milky Way are M stars - and M stars cannot be seen by Gaia in distances larger than about 5000 light years.

Addendum: Writing about magnitudes is always a pain in the ***, which is because the definition is kind of backwards. The magnitude of a star stands for its brightness (either apparent or absolute). So we intuitively think that a high brightness (or luminosity) also means a high magnitude. However, the magnitude system is defined with a negative sign. A bright star has a smaller numerical value for its magnitude than a fainter star. This is confusing and sometimes leads to confusing (or even plain wrong) statements. I hope I manage to avoid this in my texts.

Wednesday, March 2, 2016

The Milky Way: A pre-Gaia map of our home galaxy


Today's post will be about the galaxy we live in: the Milky Way. It will not be about exoplanets. However, I will come back to this topic in one of my next blogs because I will try to show where the exoplanets we know are located in this 'map' of the Milky Way.

First of all: If somebody shows you a map of the Milky Way, you should immediately be aware of the fact that this cannot be a real map in the sense that everything that is shown represents a real object with a measured position. There is no real map of the galaxy we live in, simply because (a) we cannot travel out and make a picture from above or below, and (b) we can only see 'far' enough to observe a tiny fraction of the stars in the Milky Way. The latter will hopefully improve soon because Gaia is already operating and observes more stars of the Milky Way than was ever possible before. With a little bit of luck we will get a much better impression of how our galaxy looks like this year.

What you see in the picture is my own little artist impression of how the Milky Way might look like. Again I emphasize that this might be completely wrong. Every other picture, even the I guess most famous one by NASA (R. Hurt), probably is pretty much wrong too. This 'map' is just an illustration which is supposed to show four things we believe to know about our galaxy: (a) It is a (flat) spiral galaxy. (b) It has a bright center with a bar-like structure. (c) It has four spiral arms at roughly about these locations. (d) It has a diameter of roughly about 100000 light years (ly).

Additionally, I tried to incorporate some real astrophysical data into this map. The white circles are measurements of embedded clusters (by Camargo) using the WISE telescope. The circles in cyan present the positions of molecular clouds coming from a catalogue by Ellsworth-Bowers. The only stellar data in the map are galactic cepheids (by Berdnikov, shown in magenta), which are variable stars used for distance measurements. There certainly are other dataset that should be in there to have a more complete picture, but I think these three are good enough to get the general picture. These data points give you an idea of what is actually measured and used to conclude that the Milky Way looks like what I drew.

There is a fourth dataset in the picture which cannot be seen. This dataset is the one with the best distance measurements for stars we have, at least until the first Gaia results get published. It is the Hipparcos data. However, all the data is located close to the black cross which marks the position of our Sun in the Milky Way. Our position in the Milky Way is about 8200 parsec or roughly 27000 ly away from the galactic center.

On the left side you see a blowup of the region of the Sun, where I used the new Hipparcos catalogue (van Leeuwen, 2007) to draw the positions of more than 100000 stars (white dots). Hipparcos measured the positions of stars better than one milli-arcsecond, which means the most distant stars in this catalogue are more than 3000 ly away. Of course, most of the observed stars are much closer to the Sun; 90 % of the stars with measure distances are within a radius of 1660 ly.
Although the Hipparcos map consists of a huge number of measurements, the distances from the Sun are not nearly far enough to tell us something about the large-scale structure of the Milky Way. Gaia will hopefully be about a factor 100 better than this, which will do the trick and give us a pretty good picture about a large part of the Milky Way covering maybe even 1 % of all the stars in our galaxy. Still, Gaia will not be able to see everything; some parts will be blocked from view, and some stars are just too faint or too far away to be seen.


Wednesday, February 17, 2016

Biggest sunspots since 1990: larger than a transiting Earth

This plot was inspired by this web page (History's Biggest Sunspots) and uses data from this database (DPD). It presents the area of the biggest sunspot of each month since January 1990. The sunspot area is given in millionth of the solar hemisphere, so 1000 means that 0.1 % of half of the Sun's surface is covered by the spot.

So why is this interesting for my exopanet blog? If we take a look at the radius ratio between Sun and Earth, which is about 110, we see that a transiting Earth will reduce the solar brightness by about 1/(110)² = 1/12100, which is approximately 100 millionth.

A comparison with the plot shows that there was almost no month in the last 25 years where the Sun did not have at least one spot with an area larger than 100 millionth of the solar hemisphere. So almost all of these spots cause brightness reductions larger than the transiting Earth. The Sun is not even a very active star, so chances are that many other stars have even more and larger spots. This might give you an impression why it is pretty hard to find small transiting planets around active stars.

However, the good thing is that spots change. The brightness variations they imprint on lightcurves are quite different from exoplanetary transits and they always change with time - although sometimes they change very slowly. A transiting planet usually does not change its transit (although there seem to be exceptions), so the same signal is coming again and again at a predictable time. If the transit is changing, either its shape or its transit time, you always have to be extra cautious because this takes you very close to what spots do.

By the way, this plot also shows the 11 year activity cycle of the Sun. Around 1997 and 2009 you can see periods with only very few and comparatively small spots. In between the biggest spots are much larger. The magnetic activity of the Sun changes: when it is high, it has a lot of spots and also many large spots; when it is low, you sometimes even have periods of days where not a single spot is seen. These magnetic cycle are also an issue when searching for exoplanets, although not so much for transit surveys. You can see the different levels of activity of a star in the radial velocity measurements, which might mimic the signal of a far-out planet with a long period. Again, stellar activity can mess up things quite a bit.


Sunday, February 14, 2016

Exoplanet discoveries: The growing number of planets


People have been searching for planets ('wandering stars') for thousands of years, but the first detection of a planet around another star - not the Sun - was not that long ago. It has been suspected for a long time, but we only know since about 25 years that there actually are other planets orbiting around other stars.

If you take a look at the chart on top, you can see the number of known exoplanets over their discovery date. Usually, 51 Peg b is referred to as the first detected extrasolar planet - that is why I marked it with bold letters. However, it is easy to see that this is not the entire story of the detection of the first exoplanets. Clearly, there were five planets discovered before 51 Peg b - so what's the problem with them?

I guess the problem with these planets was three-fold. First, some people had a hard time believing the data. Especially the early detections by the radial velocity technique were not absolutely convincing because researchers were at the very limits of what their instruments could do. Second, the PSR planets are bodies with low masses around pulsars. Pulsars are neutron stars, stars at the end of their life cycle. This was not expected and many people were wondering whether this could really be a planet. Third, the first two exoplanets detected were huge with masses higher than 10 Jupiter-masses. Again, people were not sure whether this is a planet or not rather something like a 'small star'. In 1995 Mayor and Queloz presented a very clear signal of a planet with half the mass of Jupiter orbiting the solar-like star 51 Peg. This was so convincing that most scientist soon accepted it as the first definitive detection of an exoplanet.




This plot shows you the number of exoplanets per detection technique. The first thing that hits the eye is the huge number of detections by 'primary transit', which is the transit method. Half of the currently known planets were found using this technique. The second-most successful method is the radial velocity method.

In 2014 the number of detections peaks with almost 900 exoplanets found in this year. This is a little bit misleading because most of these planets were already known as Kepler planetary candidates - unconfirmed planets found by the Kepler mission. In 2014 many of these unconfirmed planets were suddenly counted as real planets, not because they actually were confirmed by e.g. detection with some other method (preferably RV), but based on a statistical argument. The short version of this argument is: Kepler planetary candidates with some specific properties (e.g. being part of a multi-planet system) are virtually always real planets.

It is interesting to see that the number of exoplanet detections seems to go down. The number in 2015 was lower than 2011, 2012, and 2013. This is certainly no real effect in the sense that there are no more new planets to be found out there. It rather reflects the fact that large, successful missions to find transiting planets, like CoRoT and Kepler, have ended and less data is obtained. Although there certainly will be new instruments dedicated to detect new exoplanets, with a number of more than 2000 known exoplanets the focus will probably shift to missions characterizing a selection of particularly interesting exoplanets in detail.



When presenting each detection method separately, we can see better how the number of detections is developing for each technique. The only method I do not show here is the astrometry technique which - according to exoplanet.eu - only has one detection.

The numbers coming from the RV method are more or less constantly rising since the 90s. Although it is resource intensive because one needs large telescopes and highly RV-stabilized spectrographs, this is our most important technique to detect the mass of exoplanets. Getting high-resolution spectra of the exoplanet system also helps analyzing other properties of the star and the planets.

After the detection of the first extrasolar planetary transit in 1999, most of the transiting planets came from Kepler from about 2010 on. Although the transit method is comparatively simple, the numbers go back since the Kepler main mission is over (and K2 is not obtaining as much and as good data). Data from ground is just not as fruitful, although it is producing a lot of results.

The numbers for microlensing and imaging are rising since about 2005. I hope this will continue because it is very good for our statistical understanding of exopanets; these methods probe different properties than RVs and transits, e.g. planets far away from their host stars, which will help to understand better how many planets there are, where they are, and what characteristics they have.