APOD and General Astronomy Discussion Forum
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That is precisely how we approach the problem in the space dust community. The mass of the Sun is irrelevant, the question is how is the rest of the mass distributed. How much is there? What does the population function look like? By what mechanisms is it consumed, and by what mechanisms created? (Space dust includes planets.)rstevenson wrote:I'm not so sure working from the mass of the original gas and dust cloud is the way to go. Consider that our Sun contains 99.8% of the total mass of the Solar System, and that Jupiter contains most of the rest. That leaves very little to work with when trying to turn the basic idea into numbers. I think it makes more sense to extrapolate from known planetary systems, few as they are, so far.
No, I don't think it's daunting at all. This approach recognizes that the population is either described by a smooth function, or a stepwise smooth function, and this is determinable on theoretical grounds. Observational verification is tricky at this point, mainly because of technological limitations. But the problem itself isn't particularly intractable.BDanielMayfield wrote:Would a rigorous approach involve finding a mathematical model or function including the total system mass as a summation of the mass contribution of particles and bodies of all sizes? If so that seems like a daunting task, given the infinite configurations that any given gas and dust cloud might collapse into.
Chris Peterson wrote:No, I don't think it's daunting at all. This approach recognizes that the population is either described by a smooth function, or a stepwise smooth function, and this is determinable on theoretical grounds. Observational verification is tricky at this point, mainly because of technological limitations. But the problem itself isn't particularly intractable.BDanielMayfield wrote:Would a rigorous approach involve finding a mathematical model or function including the total system mass as a summation of the mass contribution of particles and bodies of all sizes? If so that seems like a daunting task, given the infinite configurations that any given gas and dust cloud might collapse into.
Myself, and perhaps Rob and others too are a bit mystified at this point Chris. Can you point out material we might read that can help us understand this bottom up approach?Chris Peterson wrote:That is precisely how we approach the problem in the space dust community. The mass of the Sun is irrelevant, the question is how is the rest of the mass distributed. How much is there? What does the population function look like? By what mechanisms is it consumed, and by what mechanisms created? (Space dust includes planets.)rstevenson wrote:I'm not so sure working from the mass of the original gas and dust cloud is the way to go. Consider that our Sun contains 99.8% of the total mass of the Solar System, and that Jupiter contains most of the rest. That leaves very little to work with when trying to turn the basic idea into numbers. I think it makes more sense to extrapolate from known planetary systems, few as they are, so far.
Well, within the Solar System, it's fairly straightforward to catalog bodies from planets down to dust, looking for example at zodiacal light, meteors, comet dynamics, and other factors that are within the capabilities of our instruments. Of course, that capability drops off quickly at the inner edge of the scattered disc. We still don't know much about the far outer Solar System.BDanielMayfield wrote:Myself, and perhaps Rob and others too are a bit mystified at this point Chris. Can you point out material we might read that can help us understand this bottom up approach?