Peremennye Zvezdy

Peremennye Zvezdy (Variable Stars) 40, No. 4, 2020

Received 7 September; accepted 15 September.

DOI 10.24411/2221-0474-2020-10005



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Photometric observations of the type IIn
Supernova 2016ehw

D.Yu. Tsvetkov1, N.N. Pavlyuk1, P.A. Karnaukhov1, N.V. Tyurina1, A.V. Gabovich2, V.V. Yurkov2

  1. M.V.Lomonosov Moscow State University, Sternberg Astronomical Institute, Universitetskii pr. 13, 119991 Moscow, Russia

  2. Blagoveshchensk State Pedagogical University, Lenin str. 104, Amur Region, Blagoveshchensk 675000, Russia


CCD BVRI and unfiltered photometry is presented for the type IIn Supernova 2016ehw. The object reached maximum with Rmax = 15.4 mag and absolute magnitude MR = –18.1 mag on JD 2457547. The brightness in the R band declined by 3.1 mag during 170 days of observations. The rate of decline increased at the phase about 80 days past maximum. Comparison of the light and color curves of SN 2016ehw to those of well-studied type IIn SNe shows that this SN is quite typical for its class considering photometric evolution and maximum luminosity.

1. Introduction

A large fraction of massive stars explode at the end of their lives due to the gravitational collapse of their cores; such events are recognized as core-collapse supernovae (CCSNe). Type II SNe are hydrogen-rich CCSNe; a fraction of these objects exhibit signatures of ejecta interaction with circumstellar matter (CSM), such events are classified as SNe IIn (see, for instance, Schlegel, 1990). SNe IIn are characterized by relatively high maximum luminosity due to the energy input from interaction between ejecta and CSM, they exhibit diversity of photometric evolution because of different structure of CSM and parameters of the ejecta.

Fig. 1. SN 2016ehw and local standard stars. The image was obtained with the 60-cm telescope in the R band.

In this paper, we present the results of our photometric observations of a bright type IIn Supernova, SN 2016ehw.

The MASTER-Amur auto-detection system (Lipunov et al., 2010) discovered a transient source at on 2016-06-04 16:14:44.427 UT. The unfiltered magnitude of the object was 159. The reference images without the source were obtained on 2016-05-25 20:01:44 UT with unfiltered at the MASTER-Kislovodsk telescope. The object was located in from the center of a barred spiral galaxy PGC024209 (MCG+12-8-47) (Vladimirov et al., 2016). The SN was independently discovered by Gaia on 2016-07-20.31 and designated Gaia16avr, the photometric observations in the Gaia- band continued till 2017-02-181.

The Open Supernova Catalogue2reported classification of the SN as type IIn and the redshift of the host galaxy .

2. Observations and reductions

We carried out photometric observations of SN 2016ehw in the bands from 2016-08-29 to 2016-11-28 with the 60-cm reflector of the Crimean Observatory of Sternberg Astronomical Institute (SAI). The observations with MASTER telescopes were carried out at Kislovodsk, Tunka, and Amur sites (Lipunov et al., 2010). Unfiltered images (designated further as -band ones) were obtained from 2016-06-04 to 2016-10-13, observations with filters were carried out between 2016-06-06 and 2016-07-04.

The standard image reductions and photometry were made using IRAF3. Photometric measurements of the SN were made relative to local standard stars using PSF fitting with the IRAF DAOPHOT package. The unfiltered frames were reduced using the -band magnitudes of local standards. The surface brightness of host galaxy at the location of the SN was low and did not affect the measurements, so the subtraction of galaxy background was not necessary. The image of SN 2016ehw with local standards is shown in Fig. 1. The magnitudes of the stars were calibrated on 3 nights in November 2016, when the Landolt (1992) standards were observed. They are presented in Table 1.

The results of our photometry of SN 2016ehw are reported in Tables 2, 3, and 4.

3. Results and conclusions

The light curves are shown in Fig. 2. The upper limit on 2016-05-25.8 (JD 2457534.3) and the first observations demonstrate clearly that the SN was discovered on the rising part of its light curve. The maximum light was reached on JD 2457547 (2016-06-07) with . The unfiltered magnitudes are in a good agreement with the -band observations later than JD 2457570, but for earlier time, the magnitudes may be brighter due to the blue color of the SN. On JD 2457546.39, the -band magnitude was by  mag fainter than the unfiltered one, so we may expect the -band maximum magnitude to be about  mag.

Table 1. Magnitudes of local standard stars for SN 2016ehw
Star
1 12.73 0.02 12.25 0.02 11.93 0.01 11.67 0.02
2 15.65 0.05 14.95 0.03 14.50 0.03 14.11 0.01
3 16.21 0.02 15.53 0.03 15.11 0.03 14.71 0.02
4 16.63 0.02 15.80 0.02 15.30 0.02 14.89 0.03
5 16.39 0.03 15.45 0.02 14.91 0.02 14.39 0.02
6 17.15 0.08 16.12 0.03 15.54 0.03 15.04 0.05
7 16.45 0.07 15.60 0.02 15.02 0.02 14.52 0.02


Table 2. Observations of SN 2016ehw with the 60-cm telescope
JD 2457000+
631.57 18.27 0.11 17.08 0.03 16.39 0.03 16.08 0.03
632.58 18.15 0.10 17.10 0.05 16.41 0.05 16.09 0.03
634.49 18.29 0.06 17.15 0.03 16.46 0.03 16.12 0.03
635.56 18.35 0.06 17.23 0.03 16.48 0.03 16.18 0.03
636.54 18.35 0.05 17.29 0.03 16.53 0.03 16.22 0.03
638.55 18.50 0.06 17.30 0.03 16.51 0.04 16.23 0.04
640.56 18.56 0.06 17.36 0.03 16.57 0.03 16.28 0.03
642.57 18.62 0.06 17.41 0.03 16.65 0.03 16.35 0.03
645.55 18.75 0.06 17.54 0.03 16.73 0.03 16.41 0.03
646.56 18.80 0.06 17.62 0.03 16.79 0.03 16.45 0.03
704.50     19.42 0.05 18.27 0.04    
711.47     19.74 0.07 18.47 0.04 18.15 0.07
713.49     19.77 0.09 18.60 0.04 18.27 0.04
714.38     19.54 0.07 18.56 0.04 18.36 0.06
715.58         18.56 0.06 18.30 0.08

Table 3. Observations of SN 2016ehw with the MASTER telescopes in bands
JD 2457000+
546.39 15.68 0.06 15.55 0.04 15.49 0.04 15.64 0.08
555.39             15.46 0.06
558.39         15.57 0.07 15.57 0.09
561.39         15.54 0.06 15.40 0.07
570.40 16.51 0.07 15.97 0.05 15.62 0.04    
572.40 16.51 0.08 15.94 0.04 15.66 0.04    
573.40 16.58 0.08 15.98 0.04 15.66 0.04    
574.40 16.57 0.06 15.98 0.04 15.73 0.04    

Table 4. Unfiltered observations of SN 2016ehw with the MASTER telescopes
JD 2457000+ JD 2457000+
544.17 15.55 0.06 562.39 15.46 0.05
544.17 15.56 0.07 563.39 15.46 0.05
546.38 15.30 0.05 563.39 15.55 0.05
546.38 15.32 0.04 564.39 15.42 0.04
547.43 15.27 0.04 564.39 15.46 0.07
547.43 15.24 0.04 569.41 15.49 0.04
548.39 15.30 0.03 569.41 15.52 0.03
548.39 15.30 0.04 570.39 15.59 0.04
549.39 15.28 0.04 572.39 15.57 0.04
549.39 15.31 0.03 573.39 15.62 0.03
550.39 15.31 0.04 574.39 15.62 0.03
550.41 15.30 0.04 576.39 15.70 0.04
554.55 15.33 0.04 576.39 15.68 0.03
554.55 15.36 0.04 577.39 15.69 0.04
555.39 15.31 0.04 578.42 15.71 0.03
556.39 15.36 0.04 578.42 15.70 0.04
557.39 15.39 0.05 579.39 15.71 0.04
557.39 15.38 0.04 579.39 15.74 0.03
558.39 15.43 0.06 580.39 15.74 0.04
558.39 15.42 0.05 580.39 15.71 0.04
559.39 15.41 0.04 585.30 15.81 0.07
559.39 15.39 0.04 585.31 15.80 0.07
560.39 15.42 0.04 588.19 15.78 0.10
560.39 15.45 0.04 597.16 16.01 0.07
561.39 15.43 0.04 643.13 16.73 0.10
561.39 15.48 0.04 674.65 17.79 0.11
562.39 15.48 0.04      

The brightness decline after maximum in the and bands was linear with the rate 0.014 mag/day until JD 2457630, then the rate increased to 0.026 mag/day. Gaia observations show that such decline continued for at least 100 days after the end of our observations.

The absolute -band light curve of SN 2016ehw is presented in Fig. 3, the light curves of eight SNe IIn are plotted for comparison. The distance modulus for SN 2016ehw was computed based on the reported redshift and km (s Mpc), and we used galactic extinction from the NED database4. The data on eight SNe IIn were taken from Turatto et al. (1993), Rigon et al. (2003), Pastorello et al. (2002), Kankare et al. (2012), Hicken et al. (2017), Germany et al. (2004), Tsvetkov (2008), Tsvetkov et al. (2016).