by StarCuriousAero » Tue Apr 12, 2011 10:49 pm
neufer wrote:beefcalf wrote:Perhaps somebody can help...
The graphic portrays the smallest stars on the bottom-right to be smaller in diameter than the largest planet orbiting the largest star in the top-left. This seems to contradict the idea that any planet with a mass larger than Jupiter would not show an increase in size, just density. With brown dwarves in the 10-30 Jupiter-mass-range being the same size as (or even slightly smaller than) Jupiter, how should we interpret Kepler's finding of a planet with a diameter several times that of Jupiter? Bottom line: how can a body that large be considered a planet and not a stellar companion?
One could argue that a planet of Jupiter's mass could be heated
externally by its local sun to a size much larger than Jupiter.
On the other hand, Wikipedia claims that none of Kepler's planets are more than twice the size of Jupiter (in apparent contradiction with today's APOD).
http://en.wikipedia.org/wiki/Kepler_%28spacecraft%29 wrote:
<<On 2 February 2011, the Kepler team announced ... 1235 planetary candidates circling 997 host stars. (The numbers that follow assume the candidates are really planets, though the official papers call them only candidates. Independent analysis indicates that at least 90% of them are real planets and not false positives.) 68 planets were approximately Earth-size, 288 super-Earth-size, 662 Neptune-size, 165 Jupiter-size, and 19 up to twice the size of Jupiter.>>
The response above was mildly helpful, but I was really hoping for a response to the size/mass vs planet/star question posed by beefcalf. I may have to go do some independent google research though since I'm afraid this discussion quelled a couple weeks ago (I've been behind on my apods).
I too, had the same thought when I saw the relative sizes of the largest planet "candidate" compared to not only Jupiter but the smallest star at the bottom of the chart. I'm no star expert, (so correct me if I'm wrong and please explain) but I had thought that mass determined whether or not it could support fusion, etc., (unless it's a white dwarf or something past that stage), thereby making it a star or stellar companion, and thus not a "planet" by our current definition. So basically I'm pretty confused now, and am wondering if I'm simply misinterpreting the image and how Kepler's data gives size. Is it taken into account that if a red or brown dwarf passes in front of a brighter star that there will be dimming not proportional to actual size of the object, since it may emit some of its own light? Is the dimming measured across multiple or specific wavelengths to prevent this? Or am I way off-base?
[quote="neufer"][quote="beefcalf"]Perhaps somebody can help...
The graphic portrays the smallest stars on the bottom-right to be smaller in diameter than the largest planet orbiting the largest star in the top-left. This seems to contradict the idea that any planet with a mass larger than Jupiter would not show an increase in size, just density. With brown dwarves in the 10-30 Jupiter-mass-range being the same size as (or even slightly smaller than) Jupiter, how should we interpret Kepler's finding of a planet with a diameter several times that of Jupiter? Bottom line: how can a body that large be considered a planet and not a stellar companion?[/quote]
One could argue that a planet of Jupiter's mass could be heated [b][color=#FF0000]externally[/color][/b] by its local sun to a size much larger than Jupiter.
On the other hand, Wikipedia claims that none of Kepler's planets are more than twice the size of Jupiter (in apparent contradiction with today's APOD).
[quote=" http://en.wikipedia.org/wiki/Kepler_%28spacecraft%29"]
<<On 2 February 2011, the Kepler team announced ... 1235 planetary candidates circling 997 host stars. (The numbers that follow assume the candidates are really planets, though the official papers call them only candidates. Independent analysis indicates that at least 90% of them are real planets and not false positives.) 68 planets were approximately Earth-size, 288 super-Earth-size, 662 Neptune-size, 165 Jupiter-size, and 19 up to twice the size of Jupiter.>>[/quote][/quote]
The response above was mildly helpful, but I was really hoping for a response to the size/mass vs planet/star question posed by beefcalf. I may have to go do some independent google research though since I'm afraid this discussion quelled a couple weeks ago (I've been behind on my apods).
I too, had the same thought when I saw the relative sizes of the largest planet "candidate" compared to not only Jupiter but the smallest star at the bottom of the chart. I'm no star expert, (so correct me if I'm wrong and please explain) but I had thought that mass determined whether or not it could support fusion, etc., (unless it's a white dwarf or something past that stage), thereby making it a star or stellar companion, and thus not a "planet" by our current definition. So basically I'm pretty confused now, and am wondering if I'm simply misinterpreting the image and how Kepler's data gives size. Is it taken into account that if a red or brown dwarf passes in front of a brighter star that there will be dimming not proportional to actual size of the object, since it may emit some of its own light? Is the dimming measured across multiple or specific wavelengths to prevent this? Or am I way off-base?