Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae?

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Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Jeffrey Schwartz (17 Apr 2014 14:23 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? garry.e.ward@xxxxxx (17 Apr 2014 14:58 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Andrew Staples (19 Apr 2014 07:06 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? shadow@xxxxxx (17 Apr 2014 22:20 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Knapp (18 Apr 2014 06:23 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Thomas Jones-Low (18 Apr 2014 11:44 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? shadow@xxxxxx (18 Apr 2014 18:46 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Thomas Jones-Low (18 Apr 2014 19:27 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? shadow@xxxxxx (19 Apr 2014 02:00 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Tim (18 Apr 2014 01:26 UTC)

Re: Black Hole Planets Re: [TML] Teaching my kids science: black holes & nebulae? Thomas Jones-Low 18 Apr 2014 19:27 UTC

On 4/18/2014 2:46 PM, shadow@shadowgard.com wrote:
> On 18 Apr 2014 at 7:44, Thomas Jones-Low wrote:
>
>> On 4/17/2014 6:20 PM, shadow@shadowgard.com wrote:
>>> Unlikely.
>>>
>>> Thde *neutrino* flux from a supernova will be prompt lethal to humans
>>> at *Jupiter's* distance. That's 5.2 AU. The flux at 1 AU will be 27
>>> times higher.
>>>
>>
>> 	These neutrino flux calculations are from the core of the star, not the
>> surface. So yes, the neutrino flux at 5.2 AU from the *core* of the star is
>> lethal, but that's still inside the photosphere of a large star.
>
> Anything that big won't have planets with life on it. If it's that
> big and on the main sequence, life never had time to evolve.
>
> If it's not on the main sequence, the expansion phase would have
> wiped out life as planets in the habitable zone first got baked, then
> got "eaten" when the star expanded past them.
>
	Stars that are not that big won't go supernova. They'll get bigger then slowly
collapse into a white dwarf star, or perhaps a neutron star. So no neutrino flux
to worry about.

>> 	For the Antares Supernova project I calculated, based upon known factors of the
>> supernova and assuming a brown dwarf + planet at a few hundred AU out, the
>> planet has ~150m of surface melted by the initial light blast. Then cools for a
>> year or so, allowing a few meters thickness of crust. Then the particle blast
>> wave hits, remelting the surface and an additional ~100m of crust. This depends
>> upon distance from the supernova. The paper referenced above should provide some
>> interesting details on the worlds around the supernova as the gamma ray blast
>> will have affected them too. In some cases quite badly.
>
> Frankly, that sort of thing is about the only way to get a habitable
> planet close to a supernova.
>
> Well, if life can evolve *after* a star in a double star system goes
> white dwarf and *before* enough matter from the companion (assuming a
> close binary) accumulates to cause a nova, or supernova.
>
> Come to think of it, a binary with a white dwarf that does the
> *periodic* nova bit might be intereesting.
>

	That might be an interesting balancing act. Have the WD companion in a sort of
close orbit, where it's not pulling a huge amount of material, but some. It
might be a while before the WD accumulates enough material to go boom. You might
need to wait for the central star to start expanding at the end of it's life
before the the WD starts absorbing enough material to be dangerous. That might
be an interesting system.

--
         Thomas Jones-Low
Work:	tjoneslo@softstart.com
Home:   tjoneslow@gmail.com