3.1 Radius of the exploded star

The radius of an exploding star (R_⋆) can be estimated through the phenomenon of shock breakout: when the SN shock emerges from the surface of the star, it produces a distinctive photometric signature. Shock breakout is expected to appear as an early-time excess in the light curve, with the luminosity and duration of the excess scaling with the radius of the exploding star (Kasen Reference Kasen2010; Piro, Chang, & Weinberg Reference Piro, Chang and Weinberg2010; Rabinak & Waxman Reference Rabinak and Waxman2011).

The shock breakout constraint depends crucially on knowing the precise time of the explosion. This is estimated to be UT 2011 August 23 16:29 ± 20 minutes by Nugent et al. (Reference Nugent2011b). They derive this time by fitting a power law to the early optical light curve, following the expectation that the SN luminosity L will increase as the area of the optically thick photosphere, producing the relation L∝t ². This simple model fits the photometry very well over the first four days (see Figures 3 and 4).

Figure 3. Early-time optical light curve for SN 2011fe plotted as black dots. The light curve is well fit with a simple L∝t ² power law (dotted black line). Three variations of shock breakout models are plotted as blue lines (Kasen Reference Kasen2010; Piro et al. Reference Piro, Chang and Weinberg2010; Rabinak & Waxman Reference Rabinak and Waxman2011), and are shown for different radii of the exploding star. Assuming that the explosion time can be determined from the simple power-law fit (Nugent et al. Reference Nugent2011b), the non-detection was obtained four hours after explosion and implies a size R_⋆≲0.02 R_⊙ for the exploding star. Figure from Bloom et al. (Reference Bloom2012), reproduced by permission of the AAS.

Figure 4. The limits on a shock breakout signature and R_⋆ depend on the estimated explosion date. In both panels, the measured early-time light curve of SN 2011fe is shown as filled circles and an upper-limit arrow. The shock breakout signature is a sold black line, and the SN light curve, powered by ⁵⁶Ni, is a dashed line. The top panel shows the model of Bloom et al. (Reference Bloom2012, as in Figure 3), assuming an explosion date of UT 2011 August 23 16:30 and constraining R_⋆≲0.02 R_⊙. The bottom panel is for an explosion date of UT 2011 August 23 4:30, yielding a 12-hour long dark phase and a larger radius constraint R_⋆≲0.04 R_⊙. Figure from Piro & Nakar (Reference Piro and Nakar2012), reproduced by permission of the authors.

The modelling of the shock breakout is aided by the serendipitous availability of optical imaging of M101 that had been obtained a mere four hours after Nugent et al.’s estimated time of explosion, but before the SN was actually discovered (Bloom et al. Reference Bloom2012). These data, obtained with The Open University’s 0.4-m telescope, yield a robust non-detection at this epoch. The first detection of SN 2011fe was made 11 hours after Nugent et al.’s estimated explosion time.

The faint optical flux at very early times places strong constraints on the shock breakout signal, implying that the exploding star was compact, with a radius R_⋆≲0.02 R_⊙ (Figure 3). From the measured ⁵⁶Ni mass, we know the star was ≳0.5 M_⊙. Only degenerate stars satisfy these mass and radius constraints. Thus, the exploded body in SN 2011fe must have been a neutron star or white dwarf. There are no plausible mechanisms for producing SN Ia-like thermonuclear yields from a neutron star (e.g., Jaikumar et al. Reference Jaikumar, Meyer, Otsuki and Ouyed2007). Radius constraints therefore provide strong evidence that SN 2011fe marked the explosion of a white dwarf (Bloom et al. Reference Bloom2012).

Several recent papers suggest that this initial analysis may be too simplistic (Mazzali et al. Reference Mazzali2013; Piro Reference Piro2012; Piro & Nakar Reference Piro and Nakar2012, Reference Piro and Nakar2013). Since the bolometric luminosity of an SN Ia is powered by ⁵⁶Ni at early times, if the ⁵⁶Ni is not mixed into the outermost regions of the ejecta, it will take some time for light to diffuse out. The diffusion time could lead to a ‘dark phase’ between explosion and optical rise, lasting a few hours to days depending on the radial profile of ⁵⁶Ni (Piro & Nakar Reference Piro and Nakar2012, Reference Piro and Nakar2013).

Supplementing light curves with spectroscopic information about the velocity evolution of the photosphere can help account for this effect. Piro & Nakar (Reference Piro and Nakar2012) use spectroscopic measurements from Parrent et al. (Reference Parrent2012) to refine the explosion date of SN 2011fe backward to UT 2011 August 23 02:30 (with a conservative uncertainly of 0.5 day). This explosion time is 14 hours earlier than that of Nugent et al. (Reference Nugent2011b). Using a different spectroscopic data set and modelling strategy, Mazzali et al. (Reference Mazzali2013) find an explosion time that is more than 33 hours before Nugent et al.’s estimate: UT 2011 August 22 07:00.

These results highlight the uncertainties in constraining the radius of the exploded star with shock breakout models. An earlier explosion time and longer dark phase translate into less stringent radius limits from early-time non-detections (Figure 4). If SN 2011fe has a 24-hour long dark phase, then the photometry presented by Bloom et al. (Reference Bloom2012) only limits R_⋆ to ≲0.1 R_⊙ (Piro & Nakar Reference Piro and Nakar2012). As illustrated in Figure 3 of Bloom et al. (Reference Bloom2012), this less stringent limit could accommodate unusual non-degenerate stars, such as carbon or perhaps helium stars, as the exploded star in SN 2011fe.

3.2 Abundances in the exploded star

Early-time optical spectra show significant carbon and oxygen features at a range of velocities (7 000–30 000 km s⁻¹) (Mazzali et al. Reference Mazzali2013; Nugent et al. Reference Nugent2011b; Parrent et al. Reference Parrent2012; Pereira et al. Reference Pereira2013). Neutral carbon is also observed in IR spectra (Hsiao et al. Reference Hsiao2013). SN 2011fe is certainly not alone amongst SNe Ia in showing carbon in its spectrum, although it is the best-studied example. In recent years, a rash of studies have found C ii in many SNe Ia spectra, provided that observations are obtained early in the explosion (e.g., Folatelli et al. Reference Folatelli2012; Parrent et al. Reference Parrent2011; Silverman & Filippenko Reference Silverman and Filippenko2012). Nugent et al. (Reference Nugent2011b) and Parrent et al. (Reference Parrent2012) interpret the presence of C in early-time spectra of SN 2011fe as evidence that carbon and oxygen are the unburnt remains of the exploded star. They conclude that the star that exploded as SN 2011fe was likely a CO white dwarf, as commonly expected for SNe Ia (e.g., Livio Reference Livio, Livio, Panagia and Sahu2001).

Mazzali et al. (Reference Mazzali2013) use observations of the fastest-moving outermost layer of ejecta (v >19 400 km s⁻¹) in SN 2011fe to estimate the metallicity of the progenitor. Most of this material is carbon, but the remaining 2% of the mass should represent the heavier elements in the progenitor white dwarf. By modelling an Fe-group absorption feature at ~4 800 Å in conjunction with Hubble Space Telescope (HST) UV spectroscopy, Mazzali et al. find a metallicity of ~0.25–0.5 Z_⊙ for the outermost ejecta. Foley & Kirshner (Reference Foley and Kirshner2013) also use UV spectroscopy to argue that the progenitor of SN 2011fe had sub-solar metallicity. M101’s gas-phase metallicity, measured at the galactocentric radius of SN 2011fe, is ~0.5 Z_⊙ (Stoll, Shappee, & Stanek Reference Stoll, Shappee and Stanek2011)—consistent with estimates for SN 2011fe’s progenitor system. However, it is important to keep in mind that SNe Ia show a range of delays between the formation of the progenitor system and explosion (Maoz & Mannucci Reference Maoz and Mannucci2012); it would not be surprising if there was an offset between the metallicity of SN 2011fe and the current gas-phase metallicity in the region.

The metallicity of the progenitor may be important in shaping an SN Ia, perhaps affecting the yield of ⁵⁶Ni (Jackson et al. Reference Jackson, Calder, Townsley, Chamulak, Brown and Timmes2010; Timmes, Brown, & Truran Reference Timmes, Brown and Truran2003) and also determining the observed spectral energy distribution in the rest-frame UV, where high-redshift observations of SNe Ia commonly take place (e.g., Höflich, Wheeler, & Thielemann Reference Höflich, Wheeler and Thielemann1998; Lentz et al. Reference Lentz, Baron, Branch, Hauschildt and Nugent2000; Maguire et al. Reference Maguire2012). The measurements in SN 2011fe are an important data point for testing the predicted effects of metallicity on observed SNe Ia.

3.3 Mass of the exploded star

SN Ia models would be strongly constrained if we could determine whether white dwarfs must reach the Chandrasekhar mass to explode, or if sub-Chandrasekhar explosions are common. Unfortunately, estimates of the ejected mass are challenging to achieve at the necessary accuracy (e.g., Mazzali et al. Reference Mazzali, Chugai, Turatto, Lucy, Danziger, Cappellaro, della Valle and Benetti1997; Stritzinger et al. Reference Stritzinger, Leibundgut, Walch and Contardo2006). Uncertainties of <15% are needed to distinguish between Chandrasekhar and sub-Chandrasekhar models, an extremely difficult task given the diversity of elements, densities, and ionic states in the ejecta of SNe Ia.

Mazzali et al. (Reference Mazzali2013) estimate ~1.1 M_⊙ of material is ejected at speeds >4 500 km s⁻¹ in SN 2011fe; this determination is a model-dependent lower limit, as it does not account for the slowest moving material. Future work on nebular spectra may lead to a more complete census of the ejecta mass in SN 2011fe (e.g. Stehle et al. Reference Stehle, Mazzali, Benetti and Hillebrandt2005). In the meantime, the ⁵⁶Ni mass places a secure lower limit on the ejecta mass in SN 2011fe, M _ej>0.5 M_⊙.

5.1 Constraints on the companion star

Li et al. (Reference Li2011) study deep pre-explosion HST imaging of the site of SN 2011fe in M101. No source is present at the location of SN 2011fe, ruling out bright binary companions like most red giants (Figure 7). These are by far the deepest pre-explosion limits placed on the progenitor of an SN Ia; others have been factors of >60 less sensitive and also yielded non-detections (Maoz & Mannucci Reference Maoz and Mannucci2008). Still, Li et al. cannot exclude main sequence or subgiant companions of ≲4 M_⊙.

Figure 7. A Hertzprung–Russell diagram showing the limits on a companion star to SN 2011fe, derived from pre-explosion HST imaging. The parameter space above the yellow line is ruled out, excluding most red giants as the companions to SN 2011fe. The stellar main sequence is plotted as a black line and giant branches for stars of various masses are plotted as coloured dots (key in bottom left). Several famous candidates for single-degenerate SN Ia progenitors are also plotted as shaded grey regions: recurrent novae with red giant companions (RS Oph and T CrB), a recurrent nova with a main-sequence companion (U Sco), and a He nova (V445 Pup). Figure from Li et al. (Reference Li2011). Reprinted by permission from Macmillan Publishers Ltd: Nature, copyright 2011.

If the SN shock plows over a non-degenerate companion star, this interaction is expected to produce an early-time blue ‘bump’ in the UV/optical light curve (Kasen Reference Kasen2010). The amplitude of this bump depends on the binary separation and viewing angle. Brown et al. (Reference Brown2012) find no such feature in Swift/UVOT photometry of SN 2011fe (see also Bloom et al. Reference Bloom2012; Figure 3), and constrain the binary separation to ~few ×10¹¹ cm (~0.01 AU). This constraint also rules out red giant companions, and, assuming mass transfer by Roche Lobe overflow, it implies a mass of ≲1 M_⊙ for a potential main sequence companion. However, the dark phase predicted by Piro & Nakar (Reference Piro and Nakar2012) and discussed in Section 4 may soften these constraints by a factor of several; future work is needed to self-consistently model the dark phase and the ejecta’s interaction with a companion.

Shappee et al. (Reference Shappee, Stanek, Pogge and Garnavich2013b) also place constraints on the companion star to SN 2011fe by searching for Hα emission in a nebular spectrum nine months after explosion. If the companion to an SN Ia is non-degenerate, ~0.1–0.2 M_⊙ of hydrogen is predicted to be swept from the companion and entrained in the low-velocity ejecta (Liu et al. Reference Liu, Pakmor, Röpke, Edelmann, Wang, Kromer, Hillebrandt and Han2012b; Marietta, Burrows, & Fryxell Reference Marietta, Burrows and Fryxell2000; Pan, Ricker, & Taam Reference Pan, Ricker and Taam2012). Once the ejecta become optically thin, the hydrogen-rich material should be observable as Hα emission (Mattila et al. Reference Mattila, Lundqvist, Sollerman, Kozma, Baron, Fransson, Leibundgut and Nomoto2005). Studies of previous SNe Ia constrained the entrained H to ≲0.01 M_⊙ (Leonard Reference Leonard2007), but Shappee et al. (Reference Shappee, Stanek, Pogge and Garnavich2013b) place an order-of-magnitude stronger limit in SN 2011fe, ≲0.001 M_⊙. If this result holds, it would essentially exclude all non-degenerate secondaries and require a double-degenerate model for SN 2011fe. However, more theoretical work is needed to thoroughly explore gamma-ray trapping in the ejecta, which is responsible for powering the Hα emission. Considerable uncertainties remain in predicting the Hα luminosity associated with a given mass of entrained hydrogen, but late-time Hα observations hold promise for constraining the companions of SNe Ia.

A final test of the companion to SN 2011fe is possible from late-time observations of the light curve. A non-degenerate companion should expand and grow in luminosity after being shocked by the supernova blast wave; it is expected to remain a factor of 10 − 10³ over-luminous for ~10³ − 10⁴ yr (Shappee et al. Reference Shappee, Kochanek and Stanek2013a). The signature of such a puffed-up companion should be visible in SN 2011fe ≳3.5 years after explosion, but could at first be confused with variations in radioactive yields from the SN itself (Röpke et al. Reference Röpke2012). Very late-time measurements will effectively search for such an altered companion at the site of SN 2011fe.

5.2 Constraints on the circumbinary medium

A red giant progenitor is also ruled out by searches for circumbinary material using radio and X-ray observations (Chomiuk et al. Reference Chomiuk2012; Horesh et al. Reference Horesh2012; Margutti et al. Reference Margutti2012). The interaction between a supernova blastwave and the circumstellar medium accelerates particles to relativistic speeds and amplifies the magnetic field in the shock front, producing radio synchrotron emission (Chevalier Reference Chevalier1982, Reference Chevalier1998). These same relativistic electrons also up-scatter photons radiated by the supernova itself, producing inverse Compton radiation at X-ray wavelengths (Chevalier & Fransson Reference Chevalier and Fransson2006). While these signals are often observed in nearby core-collapse SNe (Soderberg et al. Reference Soderberg, Chevalier, Kulkarni and Frail2006; Weiler et al. Reference Weiler, Panagia, Montes and Sramek2002), no SN Ia has ever been detected at radio or X-ray wavelengths, implying that SNe Ia do not explode in dense environments (Hancock, Gaensler, & Murphy Reference Hancock, Gaensler and Murphy2011; Immler et al. Reference Immler2006; Panagia et al. Reference Panagia, Van Dyk, Weiler, Sramek, Stockdale and Murata2006; Russell & Immler Reference Russell and Immler2012). SN 2011fe is no exception, with multiple epochs of non-detections in deep radio and X-ray data.

With SN 2011fe, we can place the most stringent limits to date on the circumbinary environment around an SN Ia. Assuming the circumbinary material is distributed in a wind profile ( $\rho = {{\dot{M}}\over {4 \pi v_w}} r^{-2}$ , where $\dot{M}$ and v_w are the mass-loss rate and velocity of the wind), Chomiuk et al. (Reference Chomiuk2012) use deep radio limits from the Karl G. Jansky Very Large Array to find that $\dot{M} \lesssim 6 \times 10^{-10}$ M_⊙ yr⁻¹ in the surroundings of SN 2011fe, for v_w = 100 km s⁻¹. Assuming a uniform density medium, they find its density must be n _CSM≲6 cm⁻³. These limits on the circumbinary medium not only rule out a red giant companion for SN 2011fe, but also exclude optically thick accretion winds and non-conservative mass transfer during Roche Lobe overflow (Chomiuk et al. Reference Chomiuk2012). The environment around SN 2011fe is extremely low density.

Horesh et al. (Reference Horesh2012) caution that radio limits on the circumbinary density depend on poorly understood microphysical parameters governing the efficiency of particle acceleration and magnetic field amplification. Margutti et al. (Reference Margutti2012) use X-ray observations from Chandra and Swift to place constraints on the circumbinary medium which are less model-dependent than the radio limits, because they do not depend on an assumed magnetic field strength. While the X-ray limits on circumbinary density are somewhat less stringent than the radio constraints, it is worth noting that the sensitivity of X-ray observations to circumstellar material scales with the bolometric luminosity of the supernova. The deep Chandra observation on SN 2011fe was obtained just three days after discovery, significantly before light curve peak. If instead Chandra had observed at optical maximum, the X-ray constraints on circumbinary material around SN 2011fe would be more stringent than the radio limits.

A search for circumstellar dust carried out by Johansson, Amanullah, & Goobar (Reference Johansson, Amanullah and Goobar2013) uses imaging from Herschel at 70 and 160 μm. Both pre- and post-explosion imaging yield non-detections, constraining the dust mass in the vicinity of SN 2011fe to ≲ 7×10⁻³ M_⊙ (assuming a dust temperature of 500 K).

A clean circumbinary environment is also found by Patat et al. (Reference Patat2013), who study optical absorption lines along the line of sight to SN 2011fe. In a few SNe Ia, time-variable Na i D absorption has been observed and attributed to the presence of circumbinary material that is ionised by the SN and then recombines (Patat et al. Reference Patat2007; Simon et al. Reference Simon2009). Patat et al. (Reference Patat2013) obtain multi-epoch high-resolution spectroscopy of SN 2011fe and find no evidence for time variability in the Na i D profile, again implying a lack of significant circumbinary material.

5.3 Constraints on the accretion history

The above-described constraints rule out many single-degenerate progenitors, and are often cited as evidence that SN 2011fe was the product of a white dwarf merger. However, the constraints can not conclusively exclude a main-sequence or sub-giant donor of reasonably low mass, ≲1–2 M_⊙, transferring material via Roche lobe overflow.

At low mass transfer rates, such a system might look like the recurrent nova U Sco (Figure 7), which ejects 10⁻⁶ M_⊙ every ~10 years in a nova explosion and harbors a white dwarf near the Chandrasekhar mass (Diaz et al. Reference Diaz, Williams, Luna, Moraes and Takeda2010; Schaefer Reference Schaefer2010; Thoroughgood et al. Reference Thoroughgood, Dhillon, Littlefair, Marsh and Smith2001; although the white dwarf in U Sco is likely composed of ONe, rather than CO; Mason Reference Mason2011). Li et al. (Reference Li2011) collect a time series of pre-explosion photometry at the site of SN 2011fe to search for novae preceding the supernova. All epochs yield non-detections, and they estimate a ~60% chance that a nova would have been detected if it had erupted in the five years prior to SN 2011fe. There have also been suggestions in the literature that nova shells around SNe Ia should produce time-variable Na i D absorption features (Patat et al. Reference Patat, Chugai, Podsiadlowski, Mason, Melo and Pasquini2011); Patat et al. (Reference Patat2013) find no evidence of a nova-like shell surrounding SN 2011fe.

In a progenitor system with a main sequence companion transferring mass at higher rates, steady burning of hydrogen is expected on the white dwarf surface, instead of unstable burning in the form of novae. The white dwarf will radiate thermal emission of ~few ×10⁵ K, with a spectral energy distribution peaking in the far-UV to soft X-ray. Liu et al. (Reference Liu, Di Stefano, Wang and Moe2012a) and Nielsen, Voss, & Nelemans (Reference Nielsen, Voss and Nelemans2012) search deep pre-explosion X-ray imaging of the site of SN 2011fe, looking for evidence of such a super-soft X-ray source, and emerge with non-detections. While this constraint rules out many known super-soft sources, it is not stringent enough to exclude those with lower luminosities or cooler temperatures.

One piece of evidence suggesting a single-degenerate system is that the fastest-moving ejecta (>19 400 km s⁻¹) in SN 2011fe are almost exclusively composed of carbon (98% by mass; Mazzali et al. Reference Mazzali2013). Mazzali et al. interpret these outermost ejecta as the ashes of the material accreted onto the white dwarf before the SN. If SN 2011fe marked the merger of two CO white dwarfs, a significant fraction of this material should be oxygen—but the O fraction is small and strongly constrained by the observed O i feature at 7 774 Å. They conclude that the dominance of C in highest-velocity ejecta is support for H-rich accretion onto the white dwarf, because H will fuse to C on the outskirts of an SN Ia, but the ejecta will expand before significant amounts of C can subsequently fuse to O. The outer ejecta might also be consistent with the accretion of helium under special circumstances, but in most conditions He should burn explosively up to the Fe-peak.

A relatively exotic strategy for ‘hiding’ the non-degenerate companion of an SN Ia was proposed by Justham (Reference Justham2011) and Di Stefano, Voss, & Claeys (Reference Di Stefano, Voss and Claeys2011) and dubbed the ‘spin-up/spin-down’ model. A white dwarf accreting from a non-degenerate companion may reach significant rotational speeds by conservation of angular momentum, and centripetal force will help support the white dwarf and prevent it from exploding as an SN Ia. Upon the cessation of mass transfer (presumably due to the evolution of the companion), the white dwarf will begin to spin down, and after a delay, it will finally explode as an SN Ia. The spin-down time is uncertain and potentially highly variable, ~10³ − 10¹⁰ yr. This delay may provide sufficient time for the evolved companion to lose any remaining H-rich envelope and contract to a small and unobtrusive radius. While this model can reconcile SN 2011fe to a range of single-degenerate progenitor systems (Hachisu, Kato, & Nomoto Reference Hachisu, Kato and Nomoto2012), it is highly speculative. Accreting white dwarfs are observed to spin at significantly lower rates than predicted by simple conservation of momentum (Sion Reference Sion1999), and the models of spinning white dwarfs remain preliminary (e.g., Yoon & Langer Reference Yoon and Langer2005).