Citizen scientists discover 42 new planet candidates

This is just a short post to mention a very neat paper I have been involved with. The Planet Hunters project gets a group of very proficient citizen scientists to look for planets in data coming from the Kepler spacecraft. They have found 42 new planet candidates in the data. The paper can be found on arXiv and is lead by Yale postdoc Ji Wang.

One of the most exciting thing about this work is that the majority of the candidates have long orbital periods and twenty of these candidates are in or close to the habitable region around their host star. This is astounding because it shows for the first time that planets orbiting the habitable zone are common. Most of their candidates are Neptune-sized planets but if we find large planets we can expect to find small planets. Very exciting!

The darkest exoplanet is even darker!

The blog post feels a little egocentric as I am going to discuss a paper I wrote which has recently been accepted for publication in ApJ. It is a paper which is based on the Kepler data of a star known as TrES-2 and the science we were able to deduce from small brightness variations we measure.

TrES-2 is a star a little smaller than our Sun which falls into the field of view of the Kepler spacecraft. TrES-2 was one three stars in the Kepler field known to host a transiting exoplanet pre-launch (the other two being HAT-P-7 and HAT-P-11). The planet is of similar size to Jupiter and orbits with a period of just under 2.5 days.

One of the keys to understanding exoplanets is understanding the star’s that host the planets. This is because the two most productive techniques for discovering new exoplanets (the Doppler method and the transit method), measure a planet’s mass (for Doppler) and radius (for transit) relative to the stellar mass and radius. Without accurate stellar parameters own knowledge of the planet is severely restricted.

In the case of TrES-2 we were able to determine with very high precision the star’s mass and radius by measuring seismic oscillations on the star’s surface. This technique, known as asteroseismology, is very powerful and is one of the very few ways with which to accurately determine stellar parameters (another being to directly image the star).

With these parameters in hand, the next step was to determine some planet parameters. TrES-2 is fairly bright and has been observed for the entirety of the Kepler mission. As such, the data we have for TrES-2 is some of the most exquisite exoplanet data ever obtained. We were able to observe a number of effects that until recently were thought impossible to see.

Doppler Beaming: The gravitational pull of the planet on the star causes the star to move towards and away from the observer as it orbits and can be seen as a radial velocity shift. This is the principle used to find planets with the Doppler method. It turns out that this effect can also be seen as a variation in the brightness of the star owing to a special relativistic effect known as Doppler beaming. As the star moves toward us, it’s light cone gets beamed very slightly towards us resulting in a slight increase in brightness. As it moves away it gets a little fainter because the light from the star is beamed away from us slightly. The change in brightness induced by transiting planets is very small. For TrES-2 the star only changes in brightness by 3.4 parts per million. Small but (just) detectable.

Ellipsoidal Variations: The gravitational pull of the planet on the star actually deforms the star slightly (remember, the star is a fluid). As the planet orbits the star, we periodically see more then less surface area of the star. The more surface area of the star we see the brighter the star appears to be. The deformation affect may only be to increase to the size of the star along one axis by 10 km or so but again this effect is just detectable. For TrES-2 we detected a modulation in the star’s brightness of 2.7 parts per million.

The reason why the detection of Doppler beaming and ellipsoidal variations is interesting is that both are gravitational effects and hence both depend on the mass of the planet. Therefore, by measuring the amplitude of the effects we directly measure the mass of the planet. This is very exciting as usually determining planet masses is a time consuming and expensive effort involving many nights typically using a very large and expensive telescope. Here we get it for free (almost, I still need to eat).

Phase Variations: Another effect we measured is similar to the different phases of the Moon we see from Earth, as a planet orbits a star we see the day side of the planet followed by the night side. When we see the day side of the planet, we see light. We measure a day and night brightness ratio of 3.4 parts per mission. We are also able to measure an albedo for the planet. TrES-2b was already thought to be the darkest exoplanet. We now report that this planet is about half as bright as we previously thought.

The model phase curve of TrES-2b is shown in the top
panel with the three constituent part which make up the model:
The ellipsoidal effect (green dashed curve), the Doppler beaming (blue dot-dashed curve) and reflection/emission (purple dotted
curve). The sum of these effects is the final model, shown by the
red solid line in the top and middle panel. The phase folded Kepler
data is plotted in the central panel. The residuals of
this fit are shown in the lower panel. The constant offset in our fits
has been removed from the models shown for ease of comparison
and the transit and occultation has been cut out. Data has been
binned in the figure with 15,000 short cadence data point making
up each bin, for ease of interpretation. The fit described in the
text was performed on un-folded and un-binned data.

The biggest exoplanet discovery since 51 Peg

Back in 1995 Michel Mayor and Didier Queloz announced the discovery of the first ‘real’ exoplanet – a planet orbiting a normal star. This announcement changed everything. The Sun was no longer unique in hosting planets. Since that time we have learnt that exoplanet are everywhere. However, a frequent complaint is that these planets are far away and knowing there is a habitable planet will do us no good. Yesterday all that changed. After years of searching a planet has finally been found in the Alpha Centauri system (it actually orbits the smaller star Alpha Cen B). Awkwardly designated Alpha Cen Bb, this planet is around 4 light years away – meaning that in a few generations we could actually go there!!

Now would we want to go there? Probably not. The planet is likely a hot ball of molten rock. But… one things results from Kepler have taught us is that if you have one planet you probably have many. Exciting times indeed!

Kepler-47 – the first multiplanet circumbinary star system

This is just a very quite post to mention that our paper on the first multiplanet circumbinary system was published online today in Science. Basically what we have found is two stars orbiting each other and two planets orbiting around the outside of these two stars. This is in some ways similar to the Pluto-Charon system in the outer solar system which hosts four smaller bodies (in the case of Pluto they are moons) in addition to Pluto and Charon.

One of the planets may be in the habitable zone. However, both are very likely not rocky and so will not suport life as we know it.

Amazingly this paper was written in a couple of weeks, was submitted on Aug 3 and published Aug 28. This is the fastest I have ever heard of a paper being published by any journal.

My view of AAS 220

I arrived back from the 220th meeting of the American Astronomical Society on Sunday. The conference was held in Anchorage, Alaska. The picturesque and unusual setting probably contributed to the large attendance of 1200. Higher than most Summer AAS meetings. I had a very enjoyable week although as I was staffing the Kepler booth most of the time I only got to a handful of sessions.

My personal highlight was chairing my first session at a conference. It was a somewhat nerve wracking experience (far worse than giving a talk) because there is much to think about. I really hate being in meetings where the speakers don’t run to time and it is the job of the chair to avoid overrunning talks. I was relieved that no one went on too long although I did have to get on stage when one person was talking to encourage them to get to their summary slide. Aside from constantly checking the time I also had to think up a question to ask every speaker incase no one had one from the audience. Fortunately I had a reasonable knowledge of the subject matter for every talk and was able to ask good questions every time. I actually enjoyed the experience and hopefully will be asked to chair again.

There were only a couple of announcements from the Kepler team – Lars Buchhave announced that the metallicity of the host stars seems to play no role in the occurrence rate for small planets. This is the opposite of what we find for giant planets. One reason this is interesting is that is indicates that the number of small planets may be higher than previously suspected as they can form around almost any type of star. Or as Lars puts it (in a better way than me!)

“This study shows that small planets do not discriminate and form around stars with a wide range of heavy metal content, including stars with only 25 percent of the sun’s metallicity.”

The fourth circumbinary planet was announced by Jerry Orosz. These types of planets are starting to look pretty common and did not appear until now because they have longer orbital periods then standard planets. This is due to orbits close to the stellar pair being unstable.

A non-announcement but something that may be of interest is that we now have 13 viable Kepler planet candidates smaller than Mars. I mentioned this in my talk but given this was the morning after the party, the attendance was low and those who were there were looking a little worse for wear.

The social aspect of AAS meeting is usually the real highlight, both from the point of view of meeting collaborators to discuss science and a time to unwind and party. Anchorage did not disappoint. Given it did not get dark – ever – this should not be surprising. I was sampling the local beverages and culture until 3am or so most nights. However, it was the AAS party that again proved to be the most fun. As usual this was held in a local gay bar and involved both current and former AAS presidents throwing shapes on the dance floor. However, its probably best for my career that I don’t divulge some of the more debaucherous goings on!

Fortunately I did get to see some what Alaska is famous for – moose and glaciers. I spent a wonderful day with a couple of locals who showed me some spectacular sights. I particularly enjoyed the town of Wittier, a place only accessible via a train tunnel which cars can drive along when no train in coming.

All in all a fantastic week, bring on AAS 221 in Long Beach, California!

Turning a planet candidate into a bona fide planet

I wrote a blog post of the Planethunters blog. You can find the original version can be found here. I’ve reproduced it here. I will probably write a blog post about Planethunters another time but they are a fantastic group consisting of member of the public who discover planets in Kepler data… Ok here is what I wrote for them.

The Kepler team have found several thousand exoplanet candidates. The number of targets showing transit-like signals is increasing on a nearly daily basis as we search through light curves. However, these candidates are just that, candidates. Even though the planet candidates list is thought to have a high degree of fidelity, meaning that the vast majority of candidates are indeed real planets (somewhere in the region of 90%), it requires significant amounts of time and resources to turn a planet candidate into a planet.

I’ll start by being careful with my terminology. The Kepler team use two terms when deciding a candidate is a planet. Confirmation and validation. The former generally only used when we have spectroscopic radial velocity follow-up observations. These are measurements of the wobble induced on the star by the mass of the planet. The planet and star orbit a common point in space. When the planet is moving towards us the star moves away, and vice versa. When the star moves away it gets a little redder and when it moves towards us it get a little bluer. We measure these shifts and it tells us how fast the star is moving in along out line of sight.

Radial velocity measurements in combination with a transit give the planet’s mass and radius. A radial velocity detection of a planetary mass object (normally taken to be less than 13 Jupiter masses) is very unlikely to be erroneous and we are therefore happy to confirm the existence of a planet.

In order to measure a radial velocity a planet must be close enough and massive enough to have a measurable effect on the star. The best instruments currently available are sensitive to a periodic change in radial velocity of around 1 m/s and even getting this precision requires a bright star. The Earth causes a radial velocity pull on the Sun of around 10 cm/s, measuring with this precision is out of the question with currently available instruments. We therefore require another method to use another method if we want to turn small planet candidates into planet.

Validation of a planet

Validation of a planet applies when we use a statistical argument to say that it is much more likely that the transit signal is caused by a planet passing in front of the the target star (I’ll call it star A) that it is to be caused by something else.

There are 4 main ‘something else’, or false positive, scenarios we consider.

  1. A background eclipsing binary
  2. A background planetary system
  3.  An eclipsing binary physically associated with the star A
  4.  A transiting star-planet system physically associated with star A

(*There is some debate on whether a planet orbiting a star other than star A should really be considered a false positive. It is still a planet but it does contaminates our statistics on how many small planet are in the Galaxy.*)
A background eclipsing binary is a system of two stars that are appear fainter than star A, usually because they are far away (although they could be intrinsically faint stars which are, counter-intuitively, in the foreground between us and star A). The two fainter stars pass in front of one another much like a transiting planet does and cause a periodic dip in brightness. Because star A is much brighter than the eclipsing system, the eclipse depth appears to be much shallower than it really is and hence the eclipse looks similar to planet transiting star A.

A background planetary system is much the same as scenario (1) but the fainter system contains a star and a planet instead of two stars. If we think the transit is of a planet around the larger star A, we get the planet radius wrong. If we are not careful this scenario could cause us to claim a Jupiter-sized planet is Earth-sized.

Scenario (3) is what is known as a hierarchical triple. There are three stars in the system, star A and two lower mass stars which eclipse each other and orbit around the same center of mass as star A. This is more common than one would initially think guess. Around half of all stars are members of binary systems and in the region of 10% of these are triple or multiple star systems. The light from star A washes out the eclipse of the smaller stars and the eclipse looks much more shallow than it intrinsically is.

Finally, there is the case where a star-planet system orbits star A. The depth of the transit is decreased by the presence of extra light from star A and we get the planet radius wrong.

We try to obtain high resolution images using fancy techniques like adaptive optics imaging which changes the shape of one of the telescope’s mirrors to correct for the movement of the air in the atmosphere. These images allow us to see very close to the star and therefore look for other stars nearby in the image that could cause the transit-like signal. Typically if we don’t see star nearby star A we are able to say there are no stars further than 0.1 arcseconds away (0.00003 degrees) which could cause the transit-like signal. We are then able to make use of models of our Galaxy to predict the probability that there is a star in the right brightness range and within the allowed separation from star A that could mimic the transit signal. It is common for us to be able to say there is less than one in a million chance of a there being an allowed background star. When we take into account the probability that a background star is an eclipsing binary or hosts a planet the result is usually that it is very unlikely that there is a background eclipsing binary or star-planet system.

Ruling out a physically associated star-planet or eclipsing binary system can be much more challenging. We can again use the high resolution imaging but it is much more likely that a companion star is very close to star A than is the case for a background star. One thing on our side is that the shape of the transit can be used to rule out a stellar eclipse: eclipses are usually much more ‘V-shaped’ than the typically ‘U-shaped’ planet transit. We can often say that we cannot fit the shape we observe with a stellar binary. It is also possible to rule out planet transits around a smaller star because the timescale of the ingress and egress (the part of a transit where the planet is moving into and out of transit) does not agree with the transit depth as both these piece of information yield the planet radius. However, we really need good signal-to-noise in order to place firm constraints on the ingress and egress durations. Even so, it always gives us some information even if it is not particularly constraining and this can be used to calculate a false positive probability.

The final step is to sum up the combined false positive probabilities from the different scenarios and compare that to the probability that the transit signal is due to a planet transit around star A. If the transit scenario is much more likely (say 1000 times more likely) than a false positive we claim the planet is validated. On other occasions we have to hold our hands up and say we can’t rule out the false positive scenario with a high enough degree of confidence and the source of the signal remains a planet candidate.

The case where stars host multiple planet candidates, such as that found by the Planet Hunter in the paper by Chris Lintott, is a particularly interesting one. This is because the probability that the a multi-planet candidate system contains a false positive is much lower than for single planet candidates system, somewhere in the region of 50 times less likely. This makes validation much easier.

Planet Hunters have already shown they can find these multi-planet system. Keep searching a more will appear, especially long period ones. There is a good chance that there is an Earth-like planet hiding somewhere in the data currently available.

Live Q&A on the Venus transit

Just a quick note to say that I’m going to be doing a live Q&A session answering question people have on the transit of Venus but I guess you can ask what you like. Head over to http://www.nasa.gov/connect/chat/venus_transit.html to find details. It should begin at 5.30pm Eastern time, 1.30 Pacific.

I’m pretty busy this week, finishing up some code, preparing for the AAS in Anchorage next week and I have a person coming to work with me on Wednesday and Thursday. I get quite a few visitors who come to learn how to analyse Kepler data. It should be pretty straight forward.

I’ll try to blog from the AAS meeting in Anchorage next week. I’m giving a talk and chairing a session on ‘Astrophysics with Kepler’. Before that, I need to write my talk.

Academic Authorship

There has been a bit of discussion recently at work at what someone needs to do to warrant being an author. The American Astronomical Society (AAS) ethics policy states:

All persons who have made significant contributions to a work intended for publication should be offered the opportunity to be listed as authors. This includes all those who have contributed significantly to the inception, design, execution, or interpretation of the research to be reported. People who have not contributed significantly should not be included as authors.

This seems like a perfectly reasonable, if somewhat ambiguous, definition to me. Obviously the word significant can be interpreted in different ways. My personal view is that anyone who does anything that materially contributes in even a small way should be given the opportunity to be an author. Basically, I can’t see how it hurts anyone to have extra authors on the paper.

Authorship affects the younger researchers more than the older ones. Those with tenure probably don’t need nth authorship on a paper, they have their career, but for an undergraduate or a masters student this could be a significant moment in their life! In both a positive and negative way. Positive, they see their name in print (even if they made only a modest contribution). Negative, they feel their efforts are not duly rewarded and get disillusioned with academia far earlier than necessary. Unfortunately, the older researchers seem to get added to papers as a matter of course whereas the younger scientists are often left off. In one situation I am aware of, the masters student, not knowing the system, thought it was normal to be author on a paper he helped prepare (this despite there being over 80 authors on the paper). Fortunately, when this was brought to the attention of senior people on the project the author was instructed to add him, though late enough that the paper was at the proofing stage. Whether this will help his career or not is debatable but he will always be able to say he was an author of one of the highest impact papers in exoplanet science.

Finally, internet!

Hurray! After 3 weeks of waiting for AT&T to fix things I finally have internet at my new place in San Francisco.

To back up a little, I was living in Mountain View, part of the urban sprawl that is Silicon Valley. It took me less than 15 min to cycle to work and my place was really nice but Mountain View is kinda quiet and full of guys working in the tech industry. So after weeks of umming and arring I finally made the plunge and moved into the city (SF seems to be known only as ‘the city’). I moved to the Mission District, mostly because it’s within a 10 min cycle of the Caltrain which I take to work. It’s also reputed to be one of the most fun (funnest) parts of town. It’s also full of hipsters. I do now have to commute for about 1h15m but I think it’s worth it.

Sunny today. I’m off to sit in Dolores Park for the next few hours. Bye