Re: PNV J20233073+2046041 mag 6.8
Posted: Sun Aug 18, 2013 9:04 am
Hello,
Steve Shore sent for all of us a very interesting explanation on what is happening with the nova Del 2013.
He clearly encourages all of us to continue to observe this nova and to increase time zone coverage (US Time zone but also Australia Time zone). Please observe with different resolution and in different wavelengths, at least the 4000-4400 A and 4900 -6000 A range, and of course H-alpha. This will allow a comparison of the Fe, He, CN, Balmer, O and N lines.
Cordialement,
Olivier Thizy
Vous ne verrez plus des étoiles comme avant !
http://www.shelyak.com/en/
---------------
The last spectra are showing what HAS to happen, Olivier, please
encourage everyone to keep banging away. Let me explain, I'll try to
keep these notes coming if people find them useful (and I hope not too
long-winded).
steve
---------------
At the start of the expansion, at least when we see the nova visibly,
the ejecta should pass through a stage called the fireball. This is an
opaque stage that resembles a single expanding surface, or a sort of
thin atmosphere, with an almost uniform temperature. Usually that
isn't observed but in this nova it might have been caught. The
expansion velocity is high enough that the matter can't radiate
efficiently enough to cool by energy loss, the temperature drops
instead because of the increasing volume at constant mass -- he energy
density is dropping. This is the same as saying that the total energy
remains almost constant but the temperature decreases. Then something
important happens. When the matter gets cool enough, first the
hydrogen and then heavier elements start to recombine. This releases
some energy (from the excess energy of the electrons as they're
captured by the ions) but mainly that the neutral and low ionization
stages have much higher line (and continuum) opacities and the
absorption in the ultraviolet increases quickly. The lines that absorb
there are the ground state transitions; that is, they're the strong
zero volt states. Their upper levels are those that both pump the
absorption strength of the optical transitions and excite the levels to
reradiate. So the Fe II spectrum, for instance, suddenly starts to
appear. There are coincidences with some of the He I lines, e.g. He I
5016 is close to Fe II 5018, the same for He I 4923 being near an Fe II
line (in these cases they're both from the same lower level). The
lack, in the last spectra, of He I 5875 gives the game away: the
triplet series (He I 7065, 5875, 4471) being absent means the stuff at
the near-coincidences if Fe II (and other heavy ions). In the Ondrejov
spectra, we have Ca I 4226 yesterday suddenly making an entry. At the
same time Ca II showed a higher velocity absorption than the H-beta
line. So the ejecta seem to be showing some depth structure now.
What all this means is that we're watching a stage in a classical nova
that hasn't been covered since photographic series on DQ Her, the last
nova that was bright enough for such coverage in the modern era,
although DN Gem and CP Pup were also well covered (but not like what
all of you have produced!) As I've already written, we're in new
territory here -- between observational capabilities and opportunities
to catch individual events -- so it's important that you keep up your
courage and bang away. It is possible that within the next week there
'll be a shortlived absorption stage in CN 4216 (and also 3883). In
the IR there should be a CO 2 micron emission stage. If the nova isn't
a DQ Her type, then we really have no analog.
The continuing fluctuations in the photometry, also known from other
novae at maximum light, remain a very deep problem and, again, any
observations with the highest possible cadence (this also means
longitude coverage from all of you to get the most continuous
sequences) will be critical. For instance, the disappearance of the He
I corresponded to a "local" peak in the optical light, this could be a
recombination event or it could be multiple ejections. To speculate,
so early, is too risky (even for a theorist!) so I'll stop now and hope
this explains the stages you're seeing.
One more point, though. The recession of the absorption velocity is
something also known from the DQ Her outburst, this is an effect of
the change in the transparency of the ejecta. If this is the effect of
seeing deeper into the layers at first during the late fireball, then
it should reverse as he recombination sets in and the ejecta cool.
_
Steve Shore
Steve Shore sent for all of us a very interesting explanation on what is happening with the nova Del 2013.
He clearly encourages all of us to continue to observe this nova and to increase time zone coverage (US Time zone but also Australia Time zone). Please observe with different resolution and in different wavelengths, at least the 4000-4400 A and 4900 -6000 A range, and of course H-alpha. This will allow a comparison of the Fe, He, CN, Balmer, O and N lines.
Cordialement,
Olivier Thizy
Vous ne verrez plus des étoiles comme avant !
http://www.shelyak.com/en/
---------------
The last spectra are showing what HAS to happen, Olivier, please
encourage everyone to keep banging away. Let me explain, I'll try to
keep these notes coming if people find them useful (and I hope not too
long-winded).
steve
---------------
At the start of the expansion, at least when we see the nova visibly,
the ejecta should pass through a stage called the fireball. This is an
opaque stage that resembles a single expanding surface, or a sort of
thin atmosphere, with an almost uniform temperature. Usually that
isn't observed but in this nova it might have been caught. The
expansion velocity is high enough that the matter can't radiate
efficiently enough to cool by energy loss, the temperature drops
instead because of the increasing volume at constant mass -- he energy
density is dropping. This is the same as saying that the total energy
remains almost constant but the temperature decreases. Then something
important happens. When the matter gets cool enough, first the
hydrogen and then heavier elements start to recombine. This releases
some energy (from the excess energy of the electrons as they're
captured by the ions) but mainly that the neutral and low ionization
stages have much higher line (and continuum) opacities and the
absorption in the ultraviolet increases quickly. The lines that absorb
there are the ground state transitions; that is, they're the strong
zero volt states. Their upper levels are those that both pump the
absorption strength of the optical transitions and excite the levels to
reradiate. So the Fe II spectrum, for instance, suddenly starts to
appear. There are coincidences with some of the He I lines, e.g. He I
5016 is close to Fe II 5018, the same for He I 4923 being near an Fe II
line (in these cases they're both from the same lower level). The
lack, in the last spectra, of He I 5875 gives the game away: the
triplet series (He I 7065, 5875, 4471) being absent means the stuff at
the near-coincidences if Fe II (and other heavy ions). In the Ondrejov
spectra, we have Ca I 4226 yesterday suddenly making an entry. At the
same time Ca II showed a higher velocity absorption than the H-beta
line. So the ejecta seem to be showing some depth structure now.
What all this means is that we're watching a stage in a classical nova
that hasn't been covered since photographic series on DQ Her, the last
nova that was bright enough for such coverage in the modern era,
although DN Gem and CP Pup were also well covered (but not like what
all of you have produced!) As I've already written, we're in new
territory here -- between observational capabilities and opportunities
to catch individual events -- so it's important that you keep up your
courage and bang away. It is possible that within the next week there
'll be a shortlived absorption stage in CN 4216 (and also 3883). In
the IR there should be a CO 2 micron emission stage. If the nova isn't
a DQ Her type, then we really have no analog.
The continuing fluctuations in the photometry, also known from other
novae at maximum light, remain a very deep problem and, again, any
observations with the highest possible cadence (this also means
longitude coverage from all of you to get the most continuous
sequences) will be critical. For instance, the disappearance of the He
I corresponded to a "local" peak in the optical light, this could be a
recombination event or it could be multiple ejections. To speculate,
so early, is too risky (even for a theorist!) so I'll stop now and hope
this explains the stages you're seeing.
One more point, though. The recession of the absorption velocity is
something also known from the DQ Her outburst, this is an effect of
the change in the transparency of the ejecta. If this is the effect of
seeing deeper into the layers at first during the late fireball, then
it should reverse as he recombination sets in and the ejecta cool.
_
Steve Shore