Difference between revisions of "Triggers:Supernovae"

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== Supernova Types and Rates ==
 
== Supernova Types and Rates ==
  
Numbers based on Belokurov and Evans (1993: MNRAS, 341, 569-576). Note that f in the table below is the fraction of all type-II supernovae that are L-type.
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Numbers based on Belokurov and Evans [http://adsabs.harvard.edu/abs/2003MNRAS.341..569B (2003: MNRAS, 341, 569-576)]. Note that f in the table below is the fraction of all type-II supernovae that are L-type (they suggest using f=0.5).
 
The numbers are derived by taking the Galaxy number counts out to 75 Mpc and extrapolating as D^3. These are combined with supernova event rates compiled from the literature.
 
The numbers are derived by taking the Galaxy number counts out to 75 Mpc and extrapolating as D^3. These are combined with supernova event rates compiled from the literature.
  
Although Belokuroav and Evans used an old scanning law to make their predictions, the numbers of total events down to G=20 will not change.
+
Although Belokurov and Evans used an old scanning law to make their predictions, the numbers of total events down to G=20 will not change.
  
 
This magnitude limit corresponds to a distance of 630 Mpc for a type-Ia with an average G-band maximum magnitude of -18.99.  
 
This magnitude limit corresponds to a distance of 630 Mpc for a type-Ia with an average G-band maximum magnitude of -18.99.  
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|-
 
|-
 
| IIL
 
| IIL
| 5600*f
+
| 28500*f
 
|-
 
|-
 
| IIP
 
| IIP
| 28500*(1-f)
+
| 5600*(1-f)
 
|-
 
|-
 
|}
 
|}
 
  
 
The other piece of information needed is the Luminosity function. Supernova absolute magnitude distributions are also given in Belokurov and Evans. They
 
The other piece of information needed is the Luminosity function. Supernova absolute magnitude distributions are also given in Belokurov and Evans. They
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{| border="1" cellspacing=0 cellpadding="5"  align="center"
 
{| border="1" cellspacing=0 cellpadding="5"  align="center"
 
! Type  
 
! Type  
! M\dG\u
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! <math>M_{G}</math>
! sigma\dG\u
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! <math>\sigma_G</math>
 
|-
 
|-
 
| 1a
 
| 1a
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|-
 
|-
 
|}
 
|}
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Peter Nugent's page with templates for SNe [http://supernova.lbl.gov/~nugent/nugent_templates.html]
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Revised numbers can be found here: [http://www.ast.cam.ac.uk/ioa/wikis/gsawgwiki/images/6/66/Supernovae_alerts.pdf]. The bottom line is that the total SuperNova catch is more like 19 down to G=19 (2000 before maximum), and
 +
about 200 will be brighter than G=16. A figure is reproduced here.
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 +
[[File:Gaia_sne.png|300px]]
  
 
== Supernovae type Ia ==
 
== Supernovae type Ia ==
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[[File:HoltzmanStripe82SNIa.jpg|600px]] From [http://ukads.nottingham.ac.uk/abs/2008AJ....136.2306H Holtzman et al. 2008].
 
[[File:HoltzmanStripe82SNIa.jpg|600px]] From [http://ukads.nottingham.ac.uk/abs/2008AJ....136.2306H Holtzman et al. 2008].
 +
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=== Rise and fall times of SN Ia ===
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[http://arxiv.org/abs/1001.3428 Hayden et al.2010] studied times of rise and fall of supernovae Ia.
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They selected a subset of 105 light curves well-observed in both rise and fall portions of the light curves and developed a '2-stretch' fit algorithm which estimates the rise and fall times independently. They found the '''average time from explosion to B-band peak brightness is 17.38 +/- 0.17 days''', but with a spread of rise times which range from 13 days to 23 days. This average rise time is shorter than the 19.5 days found in previous studies.
  
 
== Supernovae type II ==
 
== Supernovae type II ==
 +
 +
Example of unusual supernova IIn 2008iy [http://uk.arxiv.org/abs/0911.4719 Miller et al. 2009.], which took 400 days to rise.
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[[File:SN2008iy-phot.png|300px|Photometry of SN2008iy.]]
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[[File:SN2008iy-spec.png|300px|Spectrometry of SN2008iy. d is the time of discovery.]]
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For the progenitors of the type IIn the best candidates are Luminous Blue Variables (LBV) [http://xxx.lanl.gov/abs/1011.3484 Dwarkadas (2010)].
  
 
== Luminous Red Novae ==
 
== Luminous Red Novae ==
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* they last over several weeks.
 
* they last over several weeks.
 
* distinctively red in colour, getting redder while fading
 
* distinctively red in colour, getting redder while fading
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 +
== Extremely Luminous Supernovae ==
 +
Type IIn, <math>M_V \approx 22.1~\textrm{mag}</math>, example: 2008fz detected by the Catalina Survey [http://uk.arxiv.org/abs/0908.1990 Drake et al. 2009]
 +
 +
== Underluminous Supernovae ==
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Possibly linked with double-degenerate binary systems containing extremely low mass (<0.25 Msol) white dwarfs [http://uk.arxiv.org/abs/1011.3047 Brown et al.(2010)].

Latest revision as of 13:29, 13 September 2011

Supernova Types and Rates

Numbers based on Belokurov and Evans (2003: MNRAS, 341, 569-576). Note that f in the table below is the fraction of all type-II supernovae that are L-type (they suggest using f=0.5). The numbers are derived by taking the Galaxy number counts out to 75 Mpc and extrapolating as D^3. These are combined with supernova event rates compiled from the literature.

Although Belokurov and Evans used an old scanning law to make their predictions, the numbers of total events down to G=20 will not change.

This magnitude limit corresponds to a distance of 630 Mpc for a type-Ia with an average G-band maximum magnitude of -18.99.

Type Total to G=20
Ia 48000
Ib 7000
IIL 28500*f
IIP 5600*(1-f)

The other piece of information needed is the Luminosity function. Supernova absolute magnitude distributions are also given in Belokurov and Evans. They assume Gaussian distributions of absolute magnitude around maximum brightness as below:

Type <math>M_{G}</math> <math>\sigma_G</math>
1a -18.99 0.76
1b/c -17.75 1.29
II-L -17.63 0.88
II-P -16.44 1.23

Peter Nugent's page with templates for SNe [1]

Revised numbers can be found here: [2]. The bottom line is that the total SuperNova catch is more like 19 down to G=19 (2000 before maximum), and about 200 will be brighter than G=16. A figure is reproduced here.

Gaia sne.png

Supernovae type Ia

SDSS-II Supernova Survey (Stripe 82)

Stripe 82 spreads over 300 sq.deg between RA=-60 to RA=60 and Dec=-1.25 to Dec=+1.25. It was monitored by SDSS in 5 filters (ugriz) since 1998, but more intensively in 2005 and 2006. Numerous supernovae were found in 2005 season using difference imaging techniques, e.g. Sako et al. 2008.

HoltzmanStripe82SNIa.jpg From Holtzman et al. 2008.

Rise and fall times of SN Ia

Hayden et al.2010 studied times of rise and fall of supernovae Ia. They selected a subset of 105 light curves well-observed in both rise and fall portions of the light curves and developed a '2-stretch' fit algorithm which estimates the rise and fall times independently. They found the average time from explosion to B-band peak brightness is 17.38 +/- 0.17 days, but with a spread of rise times which range from 13 days to 23 days. This average rise time is shorter than the 19.5 days found in previous studies.

Supernovae type II

Example of unusual supernova IIn 2008iy Miller et al. 2009., which took 400 days to rise.

Photometry of SN2008iy. Spectrometry of SN2008iy. d is the time of discovery.

For the progenitors of the type IIn the best candidates are Luminous Blue Variables (LBV) Dwarkadas (2010).

Luminous Red Novae

The class of Luminous Red Novae was established in 2007 by Shrinivas Kulkarni classifying M85 OT2006-1 as LRN. It is disputed if it is a new class or subclass of SN-IIp.

  • they are fainter than SNe and brighter than novae.
  • they last over several weeks.
  • distinctively red in colour, getting redder while fading

Extremely Luminous Supernovae

Type IIn, <math>M_V \approx 22.1~\textrm{mag}</math>, example: 2008fz detected by the Catalina Survey Drake et al. 2009

Underluminous Supernovae

Possibly linked with double-degenerate binary systems containing extremely low mass (<0.25 Msol) white dwarfs Brown et al.(2010).