EVIDENCE FOR PRE-EXISTING DUST IN THE BRIGHT TYPE IIn SN 2010jl

Andrews, Jennifer E.; Clayton, Geoffrey C.; Wesson, R.; Sugerman, Ben; Barlow, M. J.; Clem, James L.; Ercolano, Barbara; Fabbri, J.; Gallagher, J.; Landolt, A. U.; Meixner, Margaret; Otsuka, Masaaki; Riebel, D.; Welch, D. L.

doi:10.1088/0004-6256/142/2/45

Cited by 72 publications

(126 citation statements)

References 38 publications

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“…This, in turn, supported the hypothesis that the pre-SN CSM of SN 2006gy was formed in an LBV-like outburst rather than in a steady wind, and a similar scenario may apply to SN 2010jl. This appears to be consistent with the very massive progenitor star inferred for SN 2010jl (Smith et al 2011b) and its dense, dusty CSM (Andrews et al 2011). However, additional analysis of the CSM emission lines is needed.…”

Section: Resultssupporting

confidence: 81%

“…Andrews et al (2011) favor the interpretation that the IR excess they observe in SN 2010jl is due to an IR echo caused by pre-existing CSM dust that is warmed by the luminosity of the SN, and not due to newly formed dust. They favor this interpretation based on the relatively cool dust temperatures of T = 750 K in their model, whereas they expect newly formed dust to emit at 1600 K. Andrews et al (2011) did mention, however, that without a detailed study of the optical emission-line profiles, it is difficult to rule out the possibility of new dust formation as an explanation for the IR emission. As noted above, the Hα profile does in fact show very clear evidence of a systematic blueshift with time, which would normally be taken as strong evidence for new dust formation.…”

Section: Discussionmentioning

confidence: 64%

“…SNe IIn constitute only about 6%-9% of core-collapse SNe (Smith et al 2011a;Li et al 2011), so even if they are very efficient dust producers, it is not clear that they can account for the dust present in high-redshift galaxies unless they are more common at high redshift. Andrews et al (2011) recently reported an IR excess in the very bright Type IIn SN 2010jl. They note that the IR excess may arise from either newly formed dust or an IR echo from pre-existing dust, although they favor the hypothesis of an IR echo because of the observed dust temperature.…”

Section: Introductionmentioning

confidence: 97%

“…In a previous paper (Smith et al 2011b), we analyzed preexplosion archival images of the field of SN 2010jl obtained with the Hubble Space Telescope (HST), showing that the progenitor of SN 2010jl was likely to be a very massive star with an initial mass above 30 M , and with dense CSM expanding at 40-120 km s −1 along our line of sight. Attributing the IR excess to pre-existing dust, Andrews et al (2011) infer a very large amount of mass in the CSM of SN 2010jl, possibly suggesting a massive progenitor similar to luminous blue variables (LBVs). Additional information on the basic observed properties of SN 2010jl can be found in recent reports (Patat et al 2011;Smith et al 2011b;Andrews et al 2011).…”

Section: Introductionmentioning

confidence: 97%

“…Attributing the IR excess to pre-existing dust, Andrews et al (2011) infer a very large amount of mass in the CSM of SN 2010jl, possibly suggesting a massive progenitor similar to luminous blue variables (LBVs). Additional information on the basic observed properties of SN 2010jl can be found in recent reports (Patat et al 2011;Smith et al 2011b;Andrews et al 2011). …”

Section: Introductionmentioning

confidence: 97%

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SYSTEMATIC BLUESHIFT OF LINE PROFILES IN THE TYPE IIn SUPERNOVA 2010jl: EVIDENCE FOR POST-SHOCK DUST FORMATION?

Smith

Silverman

Filippenko

et al. 2011

The Astronomical Journal

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Type IIn supernovae (SNe) show spectral evidence for strong interaction between their blast wave and dense circumstellar material (CSM) around the progenitor star. SN 2010jl was the brightest core-collapse supernova in 2010, and it was a Type IIn explosion with strong CSM interaction. Andrews et al. recently reported evidence for an infrared (IR) excess in SN 2010jl, indicating either new dust formation or the heating of CSM dust in an IR echo. Here we report multi-epoch spectra of SN 2010jl that reveal the tell-tale signature of new dust formation: emission-line profiles becoming systematically more blueshifted as the red side of the line is blocked by increasing extinction. The effect is seen clearly in the intermediate-width (400-4000 km s −1 ) component of Hα beginning roughly 30 days after explosion. Moreover, we present near-IR spectra demonstrating that the asymmetry in the hydrogen-line profiles is wavelength dependent, appearing more pronounced at shorter wavelengths. This evidence suggests that new dust grains had formed quickly in the post-shock shell of SN 2010jl arising from CSM interaction. Since the observed dust temperature has been attributed to an IR echo and not to new dust, either (1) IR excess emission at λ < 5 μm is not a particularly sensitive tracer of new dust formation in SNe, or (2) some assumptions about expected dust temperatures might require further study. Lastly, we discuss one possible mechanism other than dust that might lead to increasingly blueshifted line profiles in SNe IIn, although the wavelength dependence of the asymmetry argues against this hypothesis in the case of SN 2010jl.

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Section: Resultssupporting

confidence: 81%

Section: Discussionmentioning

confidence: 64%