A new paper out of George Mason University tackles the subject of planets deformed by tidal effects in close proximity to their star. It's a useful study for reasons I'll explain in a moment, but first a digression: I once had the chance to talk physics with the late Sheridan Simon, who besides being a popular lecturer on astrophysics at Guilford College (Greensboro, NC) also had a cottage industry designing planets for science fiction writers. Simon loved oddly shaped planets and because the Super Bowl was coming up, he had taken it upon himself to design a planet in the shape of a football, just to see what would happen if a place like this actually existed. "And you know what? It works," the bearded, exuberant Simon said with a grin. "But when you model what it looks like from space, the atmosphere is a problem. It looks plaid!" Simon played around with planets of every description, and if you'd like to see him at work on a planetary system around Tau Ceti, check what he developed...

We're going to be bringing both space- and ground-based assets to bear on the detection of rocky planets within the habitable zone in coming years. Cool M-class stars (red dwarfs) stand out in this regard because their habitable zones (in this case defined as where water can exist in liquid form on the surface) are relatively close to the parent star, making for increased likelihood of transits as well as a larger number of them in a given time period. Ground observatories like the Giant Magellan Telescope and the European Extremely Large Telescope should be able to perform spectroscopic studies of M-class planets as well. So consider this: We have a high probability for planets around these stars (see Ravi Kopparapu's How Common Are Potential Habitable Worlds in Our Galaxy?), and then factor in what Ramses Ramirez and Lisa Kaltenegger have, the fact that before they reach the main sequence, M-class stars go through a period of 'infancy' that can last up to 2.5 billion years. It's an...

A common trope from Hollywood's earlier decades was the team of explorers, or perhaps soldiers, lost in the desert and running out of water. On the horizon appears an oasis surrounded by verdant green, but it turns out to be a mirage. At the University of Washington, graduate student Rodrigo Luger and co-author Rory Barnes have deployed the word 'mirage' to describe planets that, from afar, look promisingly like a home for our kind of life. But the reality is that while oxygen may be present in their atmospheres, they're actually dry worlds that have undergone a runaway greenhouse state. This is a startling addition to our thinking about planets around red dwarf stars, where the concerns have largely revolved around tidal lock -- one side of the planet always facing the star -- and flare activity. Now we have to worry about another issue, for Luger and Barnes argue in a paper soon to be published in Astrobiology that planets that form in the habitable zone of such stars, close in to...

Forty light years from Earth, the planet 55 Cancri e was detected about a decade ago using radial velocity methods, in which the motion of the host star to and from the Earth can be precisely measured to reveal the signature of the orbiting body. Now comes news that 55 Cancri e has been bagged in a transit from the ground, using the 2.5-meter Nordic Optical Telescope on the island of La Palma, Spain. That makes the distant world's transit the shallowest we've yet detected from the Earth's surface, which bodes well for future small planet detections. Maybe 'small' isn't quite the right word -- 55 Cancri e is actually almost 26000 kilometers in diameter, a bit more than twice the diameter of the Earth -- which turned out to be enough to dim the light of the parent star by 1/2000th for almost two hours. The planet's period is 18 hours, bringing it close enough to reach temperatures on the dayside of 1700° Celsius. As the innermost of the five known worlds around 55 Cancri, 55 Cancri...

As I decompress from the Tennessee Valley Interstellar Workshop (and review my notes for next week's report), I have the pleasure of bringing you Andrew LePage's incisive essay into a key exoplanet question. Are some of the planets now considered potentially habitable actually unlikely to support life? Recent work gives us some hard numbers on just how large and massive a planet can be before it is more likely to be closer to Neptune than the Earth in composition. The transition from rocky to non-rocky planets is particularly important now, when our instruments are just becoming able to detect planets small enough to qualify as habitable. LePage, who writes the excellent Drew ex Machina, remains optimistic about habitable planets in the galaxy, but so far the case for many of those identified as such may be weaker than we had thought. A prolific writer, Drew is also a Senior Project Scientist at Visidyne, Inc., where he specializes in the processing and analysis of remote sensing...

Because building an economically sustainable infrastructure in the Solar System is crucial for the development of interstellar flight, I was interested to learn about a game called High Frontier, which looks to combine O'Neill habitats with a steady expansion of our species outward. Have a look at the Kickstarter campaign page if the idea of modeling space colonies as an extension of human civilization appeals to you. High Frontier seems to be a chance to get involved in game creation from the ground up to create models of how a starfaring culture might grow. I've never gotten involved in gaming, but I can see the potential for education in games that accurately model complex economies or cultural interactions. In the case of deep space scenarios, it's possible to model an interstellar mission that does not rely on an established infrastructure. Indeed, we just looked at one in Dana Andrews' recent paper, which asks how a mission without such resources could be mounted. But building...

Imaging planets around other stars is challenging enough because their light is overwhelmed by the proximity of the parent star. But what about comets? We may not be able to see them directly, but minute variations in light can mark their passage across the stellar disk. Nearly 500 comets have been detected around the star Beta Pictoris using these methods. New work led by Flavien Kiefer (IAP/CNRS/UPMC) analyzes this cometary hoard to give us a look at what is happening in a young planetary system. Using the HARPS instrument at the European Southern Observatory’s site at La Silla in Chile, Kiefer and team have compiled what the ESO is calling ‘the most complete census of comets around another star ever created.’ Beta Pictoris is becoming an old friend, a young star some 63 light years from the Sun that is no older than 20 million years. The star is surrounded by a disk of material that has been the subject of intense study as we watch the interaction between gas, dust and the...

A physicist and writer well-versed in the intricacies of the exoplanet hunt, Andrew LePage now turns his attention to the question of planets around Centauri B, and in particular the controversy over whether the highly publicized Centauri Bb does in fact exist. Today is the second anniversary of the discovery announcement, and we still have work to do to resolve whether 'noise' in the data -- explained below -- may account for what seems to be a planet. The good news is that multiple teams continue to work on Alpha Centauri, and we should expect answers within several years, or just possibly, as LePage explains, a bit sooner than that. by Andrew LePage Time certainly seems to fly at times. It has already been two years since the October 16, 2012 announcement by a Geneva-based team of astronomers of the discovery of a planet orbiting our Sun-like neighbor, α Centauri B, using precision radial velocity measurements. While this planet, designated α Centauri Bb, was hardly...

On Friday I mentioned transmission spectroscopy, the technique of analyzing the light of a parent star as it is filtered through a planetary atmosphere. We've used it on various 'hot Jupiters' before now -- think of the much studied planet HD 209458b, where water vapor, carbon dioxide and methane have been detected and fierce upper atmosphere winds revealed. And while we wait to see if the method can be applied to the interesting WASP-94 system, we can look at its uses in another hot Jupiter whose weather has now been mapped. WASP-43b has twice Jupiter's mass and a breathtaking 19-hour year. Scientists using the Hubble Space Telescope have used transmission spectroscopy to determine the abundance of water in the atmosphere at the terminator between night and day on this tidally locked world. The team also used so-called emission spectroscopy -- in which much of the light of the parent star is subtracted -- to measure water abundance and temperature at different points in its orbit....

The WASP Consortium (Wide Angle Search for Planets) has come up with an interesting find: Two new Jupiter-class worlds, one around each star in a binary star system. Both are 'hot Jupiters,' a class of planets that is susceptible to discovery by transit methods, as in this case, and radial velocity as well. Consisting of two robotic observatories, one on La Palma (Canary Islands) and the other in South Africa, WASP has a proven track record, having found over 100 planets since 2006. WASP-94A and WASP-94B, like all WASP candidates, were confirmed by radial velocity techniques through a collaboration with the Geneva Observatory. The two stars are about 600 light years away in the constellation Microscopium. In this case, it was the WASP-South survey team that noticed dips in the light of WASP-94A, the mark of a likely hot Jupiter, with WASP-94B being found by the Geneva team during the confirmation process for the first planet. "We observed the other star by accident, and then found a...

Centauri Dreams welcomes Ravi Kopparapu, a research associate in the Department of Geosciences at Pennsylvania State University. He obtained his Ph.D in Physics from Louisiana State University, working with the LIGO (Laser Interferometer Gravitational-wave Observatory) collaboration. After a brief stint as a LIGO postdoc at Penn State, Ravi switched to the exoplanet field and started working with Prof. James Kasting. His current research work includes estimating habitable zones around different kinds of stars, calculating the occurrence of exoplanets using the data from NASA's Kepler space telescope, and understanding the bio-signatures that can potentially be detected by future space telescope missions. Dr. Kopparapu's website is http://www3.geosc.psu.edu/~ruk15/index.shtml. by Ravi Kopparapu Imagine this scenario: You are planning to buy a new house in a nice neighborhood. The schools in the area are good, the neighborhood is very safe, but you want to know the 'kid friendly'...

Like most people, I'm highly interested in the hunt for habitable worlds, planets that could truly be called Earth 2.0. But sometimes we need to step back from the 'habitable' preoccupation and think about the extraordinary range of worlds we've been finding. I'm reminded of something Caleb Scharf says in his new book The Copernicus Complex (Farrar, Straus and Giroux, 2014), in a chapter where he describes the work of Johannes Kepler and other astronomical pioneers. Kepler's laws of planetary motion first told us that planetary orbits are ellipses rather than the perfect circles envisioned by the school of Ptolemy. The implications are striking and lead us to expect just the kind of wild variety we find in the exoplanet hunt, where we're uncovering everything from 'hot Jupiters' to 'super-Earths' and a wide variety of Neptune-like worlds. Says Scharf: If planets follow elliptical paths as a general rule, and those paths need not be all within a single plane around a centrally massive...

While I'm in Houston attending the 100 Year Starship Symposium (about which more next week), Andrew LePage has the floor. A physicist and freelance writer specializing in astronomy and the history of spaceflight, LePage will be joining us on a regular basis to provide the benefits of his considerable insight. Over the last 25 years, he has had over 100 articles published in magazines including Scientific American, Sky & Telescope and Ad Astra as well as numerous online sites. He also has a web site, www.DrewExMachina.com, where he regularly publishes a blog on various space-related topics. When not writing, LePage works as a Senior Project Scientist at Visidyne, Inc. located outside Boston, Massachusetts, where he specializes in the processing and analysis of remote sensing data. by Andrew LePage Like many space exploration enthusiasts and professional scientists, I was inspired as a child by science fiction in films, television and print. Even as a young adult, science fiction...

Bringing some order into the realm of 'hot Jupiters' is all to the good. How do these enormous worlds get so close to their star, having presumably formed much further out beyond the 'snowline' in their systems, and what effects do they have on the central star itself? And how do 'hot Jupiter' orbits evolve so as to create spin-orbit misalignments? A team at Cornell University led by astronomy professor Dong Lai, working with graduate students Natalia Storch and Kassandra Anderson, has produced a paper that tells us much about orbital alignments and 'hot Jupiter' formation. It's no surprise that large planets -- and small ones, for that matter -- can make their stars wobble. This is the basis for the Doppler method that so accurately measures the movement of a star as affected by the planets around it. But something else is going on in 'hot Jupiter' systems. In our own Solar System the rotational axis of the Sun is more or less aligned with the orbital axis of the planets. But some...

In terms of habitability, it's clear that getting a world too close to its star spells trouble. In the case of Gliese 581c, we had a planet that some thought would allow liquid water at the surface, but subsequent work tells us it's simply too hot for life as we know it. With the recent dismissal of Gl 581d and g (see Red Dwarf Planets: Weeding Out the False Positives), that leaves no habitable zone worlds that we know about in this otherwise interesting red dwarf system. I'm glad to see that Stephen Kane (San Francisco State) and his team of researchers are working on the matter of distinguishing an Earth-like world from one that is more like Venus. We've made so much of the quest to find something roughly the same size as the Earth that we haven't always been clear to the general public about what that implies. For Venus is Earth-like in terms of size, but it's clearly a far cry from Earth in terms of conditions. Indeed, you would be hard-pressed to find a more hellish place than...

In Greg Bear's novel Queen of Angels (Gollancz, 1990), a robotic probe called AXIS (Automated eXplorer of Interstellar Space) has used antimatter propulsion to make a fifteen-year crossing to Alpha Centauri. The world's various networks of the future begin to feast on reports of what it finds, like this one: "In the past few weeks, AXIS has returned images of three planets circling Alpha Centauri B. As yet these worlds have not been named, and are called only B-1, B-2, and B-3. B-3 was already known to moonbased astronomers; it is a huge gas giant some ten times larger than Jupiter in our own solar system. Like Saturn, it is surrounded by a thin rugged ring of icy moonlets. B-1 is a barren rock hugging close to Alpha Centauri B, similar to Mercury. But the focus of our attention is now on B-2, a justright world slightly smaller than Earth. B-2 possesses an atmosphere closely approximating Earth's, as well as continents and oceans of liquid water. It is orbited by two moons each about...

For those of you who, like me, are fascinated with red dwarf stars and the prospects for life around them, I want to mention David Stevenson's Under a Crimson Sun (Springer, 2013), with the caveat that although it's on my reading list, I haven't gotten to it yet. More about this title after I've gone through it, but for now, notice that the interesting planet news around stars like Gliese 581 and GJ 667C is catching the eye of publishers and awakening interest in the public. It's easy to see why. Planets in the habitable zone of such stars would be exotic places, far different from Earth, but possibly bearing life. At the same time, we're learning a good deal more about both the above-mentioned stars. A new paper by Paul Robertson and Suvrath Mahadevan (both at Pennsylvania State) looks at GJ 667C with encouraging -- and cautionary -- results. The encouraging news is that GJ 667Cc, a super-Earth in the habitable zone of the star, is confirmed by their work. The cautionary note is...

Here's an interesting notion: Put future radio telescopes like the Long Wavelength Array, now under construction in the American southwest, to work looking for exomoons. The rationale is straightforward and I'll examine it in a minute, but a new paper advocating the idea homes in on two planets of unusual interest from the exomoon angle. Gliese 876b and Epsilon Eridani b are both nearby (15 light years and 10.5 light years respectively), both are gas giants, and both should offer a recognizable electromagnetic signature if indeed either of them has a moon. The study in question comes out of the University of Texas at Arlington, where a research group led by Zdzislaw Musielak is looking at how large moons interact with a gas giant's magnetosphere. The obvious local analogue is Io, Jupiter's closest moon, whose upper atmosphere (presumably created by the active volcanic eruptions on the surface) encounters the charged plasma of the magnetosphere, creating current and radio emissions....

I've made no secret of my interest in red dwarf stars as possible hosts of life-bearing planets, and this is partially because these long-lived stars excite visions of civilizations that could have a stable environment for many billions of years. I admit it, the interest is science fictional, growing out of my imagination working on the possibility of life under the light of a class of stars that out-live all others. What might emerge in such settings, in places where tidal lock could keep the planet's star fixed at one point in the sky and all shadows would be permanent? Some of this interest grows out of an early reading of Olaf Stapledon's 1937 novel Star Maker, in which the author describes life in the form of intelligent plants that live on such a tidally locked world. For that matter, Larry Niven developed an alien race called the Chirpsithra, natives of a red dwarf who have a yen for good drink and socializing with other species (you can sample Niven's lively tales of these...

When I was a boy in ninth grade, I asked our science teacher whether the nearest star was likely to have planets. He loved the question because it gave him the chance to explain to the class that Alpha Centauri was a binary star (we left poor Proxima out of the discussion), and that as a binary, it couldn't possibly have planets because their orbits would be too disrupted by gravitational effects to survive. That sounded reasonable to me, and I began putting my hopes on places like Tau Ceti and Epsilon Eridani, single stars with no disruptive companion. Since then we've begun finding binary stars with planets and are learning about the diversity of exoplanetary systems, putting Alpha Centauri back into the game. A good thing, too, given the fact that binary stars are common, and keeping them in the planet hunt allows that many more chances to find an Earth 2.0, not to mention all the other interesting kinds of planets including 'super-Earths' that we're locating. But the fact that...