Early Spectroscopy and Dense Circumstellar Medium Interaction in SN 2023ixf

被引：53

作者：

Bostroem, K. Azalee ^{[1
]}

Pearson, Jeniveve ^{[1
]}

Shrestha, Manisha ^{[1
]}

Sand, David J. ^{[1
]}

Valenti, Stefano ^{[2
]}

Jha, Saurabh W. ^{[3
]}

Andrews, Jennifer E. ^{[4
]}

Smith, Nathan ^{[1
]}

Terreran, Giacomo ^{[5
]}

Green, Elizabeth ^{[1
]}

Lundquist, Michael ^{[6
]}

Haislip, Joshua ^{[7
]}

Hoang, Emily T. ^{[2
]}

Hosseinzadeh, Griffin ^{[1
]}

Janzen, Daryl ^{[8
]}

Jencson, Jacob E. ^{[9
]}

Kouprianov, Vladimir ^{[7
]}

Paraskeva, Emmy ^{[2
]}

Retamal, Nicolas E. Meza ^{[2
]}

Reichart, Daniel E. ^{[7
]}

Arcavi, Iair ^{[10
]}

Bonanos, Alceste Z. ^{[11
]}

Coughlin, Michael W. ^{[12
]}

Dobson, Ross ^{[13
,14
]}

Farah, Joseph ^{[5
,15
]}

Galbany, Lluis ^{[16
,17
]}

Gutierrez, Claudia ^{[16
,17
]}

Hawley, Suzanne ^{[18
]}

Hebb, Leslie ^{[19
,20
]}

Hiramatsu, Daichi ^{[21
,22
]}

Howell, D. Andrew ^{[5
,15
]}

Iijima, Takashi ^{[23
]}

Ilyin, Ilya ^{[24
]}

Jhass, Kiran ^{[14
,25
]}

McCully, Curtis ^{[5
,15
]}

Moran, Sean ^{[21
]}

Morris, Brett M. ^{[26
]}

Mura, Alessandra C. ^{[27
]}

Mueller-Bravo, Tomas E. ^{[16
,17
]}

Munday, James ^{[14
,28
]}

Newsome, Megan ^{[5
,15
]}

Pabst, Maria Th. ^{[27
]}

Ochner, Paolo ^{[23
,27
]}

Gonzalez, Estefania Padilla ^{[5
,15
]}

Pastorello, Andrea ^{[23
]}

Pellegrino, Craig ^{[5
,15
]}

Piscarreta, Lara ^{[16
]}

Ravi, Aravind P. ^{[29
]}

Reguitti, Andrea ^{[23
,30
]}

Salo, Laura ^{[12
]}

机构：

[1] Univ Arizona, Steward Observ, 933 North Cherry Ave, Tucson, AZ 85721 USA

[2] Univ Calif Davis, Dept Phys & Astron, 1 Shields Ave, Davis, CA 95616 USA

[3] Rutgers State Univ, Dept Phys & Astron, 136 Frelinghuysen Rd, Piscataway, NJ 08854 USA

[4] Gemini Observ, 670 North Aohoku Pl, Hilo, HI 96720 USA

[5] Cumbres Observ, 6740 Cortona Dr,Suite 102, Goleta, CA 93117 USA

[6] WM Keck Observ, 65-1120 Mamalahoa Highway, Kamuela, HI 96743 USA

[7] Univ N Carolina, Dept Phys & Astron, 120 East Cameron Ave, Chapel Hill, NC 27599 USA

[8] Univ Saskatchewan, Dept Phys & Engn Phys, 116 Sci Pl, Saskatoon, SK S7N 5E2, Canada

[9] Johns Hopkins Univ, Dept Phys & Astron, 3400 North Charles St, Baltimore, MD 21218 USA

[10] Tel Aviv Univ, Sch Phys & Astron, IL-69978 Tel Aviv, Israel

[11] Natl Observ Athens, IAASARS, Penteli 15236, Greece

[12] Univ Minnesota, Sch Phys & Astron, 116 Church St SE, Minneapolis, MN 55455 USA

[13] Univ Coll London, Mullard Space Sci Lab, Dorking RH5 6NT, Surrey, England

[14] Isaac Newton Grp Telescopes, Apt Correos 368, E-38700 Santa Cruz De La Palma, Spain

[15] Univ Calif Santa Barbara, Dept Phys, Santa Barbara, CA 93106 USA

[16] CSIC, Inst Space Sci ICE, Campus UAB,Carrer Can Magrans S-N, E-08193 Barcelona, Spain

[17] Inst Estudis Espacials Catalunya, Gran Capita 2-4,Edif Nexus,Desp 201, E-08034 Barcelona, Spain

[18] Univ Washington, Dept Astron, 3910 15th Ave NE, Seattle, WA 98195 USA

[19] Hobart & William Smith Coll, Phys Dept, 300 Pulteney St, Geneva, NY 14456 USA

[20] Cornell Univ, Dept Astron, 245 East Ave, Ithaca, NY 14850 USA

[21] Harvard & Smithsonian, Ctr Astrophys, 60 Garden St, Cambridge, MA 02138 USA

[22] NSF Inst Artificial Intelligence & Fundamental Int, Boston, MA USA

[23] INAF Osservatorio Astron Padova, Vicolo Osservatorio 5, I-35122 Padua, Italy

[24] Leibniz Inst Astrophys Potsdam AIP, Sternwarte 16, D-14482 Potsdam, Germany

[25] Univ Sheffield, Dept Phys & Astron, Sheffield S3 7RH, England

[26] Space Telescope Sci Inst, 3700 San Martin Dr, Baltimore, MD 21218 USA

[27] Univ Padua, Phys & Astron Dept Galileo Galilei, Vicolo Osservatorio 3, I-35122 Padua, Italy

[28] Univ Warwick, Dept Phys, Gibbet Hill Rd, Coventry CV4 7AL, England

[29] Univ Texas Arlington, Dept Phys, Box 19059, Arlington, TX 76019 USA

[30] INAF Osservatorio Astron Brera, Osservatorio Astron Brera, Via E Bianchi 46, I-23807 Merate, LC, Italy

[31] Univ Texas Austin, Univ Stn 1 C1400, Austin, TX 78712 USA

[32] MTA Ctr Excellence, Konkoly Observ, CSFK, Konkoly Thege M Ut 15-17, H-1121 Budapest, Hungary

[33] Eotvos Lorand Univ, Inst Phys & Astron, Pazmany Peter Setany 1-A, H-1117 Budapest, Hungary

[34] Univ Szeged, Dept Expt Phys, Dom Ter 9, H-6720 Szeged, Hungary

[35] Univ Nottingham, Sch Phys & Astron, Univ Pk, Nottingham NG7 2RD, England

[36] Univ Arizona, MMT, 933 North Cherry Ave, Tucson, AZ 85721 USA

[37] Univ Arizona, Steward Observ, 933 North Cherry Ave, Tucson, AZ 85721 USA

来源：

ASTROPHYSICAL JOURNAL LETTERS | 2023年 / 956卷 / 01期

基金：

欧盟地平线“2020”; 匈牙利科学研究基金会; 欧洲研究理事会; 英国科学技术设施理事会; 美国国家科学基金会;

关键词：

MASS-LOSS RATES; RED-SUPERGIANT; LIGHT-CURVES; PRECURSOR EMISSION; RADIATIVE-TRANSFER; MESSIER; 101; 1ST MONTH; PROGENITOR; EXPLOSION; SUPERNOVAE;

D O I：

10.3847/2041-8213/acf9a4

中图分类号：

P1 [天文学];

学科分类号：

0704 ;

摘要：

We present the optical spectroscopic evolution of SN 2023ixf seen in subnight cadence spectra from 1.18 to 15 days after explosion. We identify high-ionization emission features, signatures of interaction with material surrounding the progenitor star, that fade over the first 7 days, with rapid evolution between spectra observed within the same night. We compare the emission lines present and their relative strength to those of other supernovae with early interaction, finding a close match to SN 2020pni and SN 2017ahn in the first spectrum and SN 2014G at later epochs. To physically interpret our observations, we compare them to CMFGEN models with confined, dense circumstellar material around a red supergiant (RSG) progenitor from the literature. We find that very few models reproduce the blended N iii (lambda lambda 4634.0,4640.6)/C iii (lambda lambda 4647.5,4650.0) emission lines observed in the first few spectra and their rapid disappearance thereafter, making this a unique diagnostic. From the best models, we find a mass-loss rate of 10-3-10-2 M circle dot yr-1, which far exceeds the mass-loss rate for any steady wind, especially for an RSG in the initial mass range of the detected progenitor. These mass-loss rates are, however, similar to rates inferred for other supernovae with early circumstellar interaction. Using the phase when the narrow emission features disappear, we calculate an outer dense radius of circumstellar material R CSM,out approximate to 5 x 1014 cm, and a mean circumstellar material density of rho = 5.6 x 10-14 g cm-3. This is consistent with the lower limit on the outer radius of the circumstellar material we calculate from the peak H alpha emission flux, R CSM,out greater than or similar to 9 x 1013 cm.

引用

页数：17

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