Five-Year Optical and Near Infrared Observations of the Extremely Slow Nova V1280 Scorpii

TL;DR

This study provides a comprehensive five-year optical and near-infrared observation of the extremely slow nova V1280 Scorpii, revealing its unique prolonged evolution, dust formation, and re-ignition episodes, contributing valuable data on slow nova behavior.

Contribution

First detailed five-year multi-wavelength observational analysis of V1280 Scorpii, highlighting its unprecedented slow evolution and dust formation processes.

Findings

Long-lasting plateau in optical brightness over 1000 days

Extended time (~50 months) before entering nebular phase

Estimated white dwarf mass of 0.6 solar masses or less

Abstract

We present optical ($B$, $V$, $R_{\rm c}$, $I_{\rm c}$ and $y$) and near infrared ($J$, $H$ and $K_{\rm s}$) photometric and spectroscopic observations of a classical nova V1280 Scorpii for five years from 2007 to 2011. Our photometric observations show a declining event in optical bands shortly after the maximum light which continues $\sim$ 250 days. The event is most probably caused by a dust formation. The event is accompanied by a short ($\sim$ 30 days) re-brightening episode ($\sim$ 2.5 mag in $V$), which suggests a re-ignition of the surface nuclear burning. After 2008, the $y$ band observations show a very long plateau at around $y$ = 10.5 for more than 1000 days until April 2011 ($\sim$ 1500 days after the maximum light). The nova had taken a very long time ($\sim$ 50 months) before entering the nebular phase (clear detection of both [\ion{O}{iii}] 4959 and 5007) and is still continuing to generate the wind caused by H-burning. The finding suggests that V1280 Sco is going through the historically slowest evolution. The interval from the maximum light (2007 February 16) to the beginning of the nebular phase is longer than any previously known slow novae: V723 Cas (18 months), RR Pic (10 months), or HR Del (8 months). It suggests that the mass of a white dwarf in the V1280 Sco system might be 0.6 $M_\mathrm{\sun}$ or smaller. The distance, based on our measurements of the expansion velocity combined with the directly measured size of the dust shell, is estimated to be 1.1 $\pm$ 0.5 kpc.