M Dwarf Flare Continuum Variations on One-Second Timescales: Calibrating and Modeling of Ultracam Flare Color Indices*

Kowalski, Adam F.; Mathioudakis, M.; Hawley, Suzanne L.; Wisniewski, John P.; Dhillon, V. S.; Marsh, T. R.; Hilton, Eric J.; Brown, Benjamin

doi:10.3847/0004-637x/820/2/95

Cited by 62 publications

(148 citation statements)

References 68 publications

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“…In moderatecadence photometry, however, these events would likely go undetected having similar amplitudes and colors as accretion variability. Only if a measurement were to contain a large flare or a flare peak, where the photometric color is typically bluer than accretion, would it stand out from the underlying accretion variability (Kowalski et al 2016). …”

Section: Light Curve Variabilitymentioning

confidence: 99%

Pulsed Accretion in the T Tauri Binary TWA 3A

Tofflemire

Herczeg

Akeson

et al. 2017

ApJL

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TWA 3A is the most recent addition to a small group of young binary systems that both actively accrete from a circumbinary disk and have spectroscopic orbital solutions. As such, it provides a unique opportunity to test binary accretion theory in a well-constrained setting. To examine TWA 3A's time-variable accretion behavior, we have conducted a two-year, optical photometric monitoring campaign, obtaining dense orbital phase coverage (∼20 observations per orbit) for ∼15 orbital periods. From U-band measurements we derive the time-dependent binary mass accretion rate, finding bursts of accretion near each periastron passage. On average, these enhanced accretion events evolve over orbital phases 0.85 to 1.05, reaching their peak at periastron. The specific accretion rate increases above the quiescent value by a factor of ∼4 on average but the peak can be as high as an order of magnitude in a given orbit. The phase dependence and amplitude of TWA 3A accretion is in good agreement with numerical simulations of binary accretion with similar orbital parameters. In these simulations, periastron accretion bursts are fueled by periodic streams of material from the circumbinary disk that are driven by the binary orbit. We find that TWA 3A's average accretion behavior is remarkably similar to DQ Tau, another T Tauri binary with similar orbital parameters, but with significantly less variability from orbit to orbit. This is only the second clear case of orbital-phase-dependent accretion in a T Tauri binary.

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Section: Light Curve Variabilitymentioning

confidence: 99%

Pulsed Accretion in the T Tauri Binary TWA 3A

Tofflemire

Herczeg

Akeson

et al. 2017

ApJL

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“…In one case, the B-band brightness is consistent with a non-detection, so the minimum and maximum accretion rates before and during the burst are not reported. These short bursts are attributed here to accretion but could alternatively be attributed to stellar flares (e.g., Kowalski et al 2016;Tofflemire et al 2017aTofflemire et al , 2017b.…”

Section: Short Timescale Burstsmentioning

confidence: 99%

Star–Disk Interactions in Multiband Photometric Monitoring of the Classical T Tauri Star GI Tau

Guo

Herczeg

Jose

et al. 2018

ApJ

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The variability of young stellar objects is mostly driven by star-disk interactions. In long-term photometric monitoring of the accreting T Tauri star GI Tau, we detect extinction events with typical depths of DṼ 2.5 mag that last for days to months and often appear to occur stochastically. In 2014-2015, extinctions that repeated with a quasi-period of 21 days over several months are the first empirical evidence of slow warps predicted by magnetohydrodynamic simulations to form at a few stellar radii away from the central star. The reddening is consistent with =  R 3.85 0.5 V and, along with an absence of diffuse interstellar bands, indicates that some dust processing has occurred in the disk. The 2015-2016 multiband light curve includes variations in spot coverage, extinction, and accretion, each of which results in different traces in color-magnitude diagrams. This light curve is initially dominated by a month-long extinction event and a return to the unocculted brightness. The subsequent light curve then features spot modulation with a 7.03 day period, punctuated by brief, randomly spaced extinction events. The accretion rate measured from U-band photometry ranges from´-1.3 10 8 to´-1.1 10 10 M e yr −1 (excluding the highest and lowest 5% of high-and low-accretion rate outliers), with an average of4.7 -10 9 M e yr −1 . A total of 50% of the mass is accreted during bursts of >´-12.8 10 9 M e yr -1, which indicates limitations on analyses of disk evolution using single-epoch accretion rates.

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“…In the impulsive phase of impulsive-type flares from active M dwarf stars, the NUV and blue optical continuum distribution often exhibits a color temperature of T∼ 10,000-12,000 K, with a small Balmer jump in emission (Hawley & Pettersen 1991;Kowalski et al 2013Kowalski et al , 2016. Due to a low surface flux of an M dwarf in quiescence, subtracting an M dwarf pre-flare spectrum from a flare observation (to infer a color temperature) does not artificially produce a hot continuum in the blue and NUV as is possible for the Sun as discussed in Kleint et al (2016).…”

Section: Appendix C Comparison Of 5f11 and F13 Rhd Modelsmentioning

confidence: 99%

“…We repeat the calculations (L. Kleint 2016, private communication) using the data from Kretzschmar (2011) while adjusting for the fraction of the solar surface no longer emitting at pre-flare values during the flare (Equation3 of Kowalski et al 2016) for a direct comparison to a blackbody flare model.…”

mentioning

confidence: 99%

The Atmospheric Response to High Nonthermal Electron Beam Fluxes in Solar Flares. I. Modeling the Brightest NUV Footpoints in the X1 Solar Flare of 2014 March 29

Kowalski

Allred

Daw

et al. 2017

ApJ

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The 2014 March 29 X1 solar flare (SOL20140329T17:48) produced bright continuum emission in the far-and near-ultraviolet (NUV) and highly asymmetric chromospheric emission lines, providing long-sought constraints on the heating mechanisms of the lower atmosphere in solar flares. We analyze the continuum and emission line data from the Interface Region Imaging Spectrograph (IRIS) of the brightest flaring magnetic footpoints in this flare. We compare the NUV spectra of the brightest pixels to new radiative-hydrodynamic predictions calculated with the RADYN code using constraints on a nonthermal electron beam inferred from the collisional thick-target modeling of hard X-ray data from Reuven Ramaty High Energy Solar Spectroscopic Imager. We show that the atmospheric response to a high beam flux density satisfactorily achieves the observed continuum brightness in the NUV. The NUV continuum emission in this flare is consistent with hydrogen (Balmer) recombination radiation that originates from low optical depth in a dense chromospheric condensation and from the stationary beam-heated layers just below the condensation. A model producing two flaring regions (a condensation and stationary layers) in the lower atmosphere is also consistent with the asymmetric Fe II chromospheric emission line profiles observed in the impulsive phase.

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M Dwarf Flare Continuum Variations on One-Second Timescales: Calibrating and Modeling of Ultracam Flare Color Indices*

Cited by 62 publications

References 68 publications

Pulsed Accretion in the T Tauri Binary TWA 3A

Pulsed Accretion in the T Tauri Binary TWA 3A

Star–Disk Interactions in Multiband Photometric Monitoring of the Classical T Tauri Star GI Tau

The Atmospheric Response to High Nonthermal Electron Beam Fluxes in Solar Flares. I. Modeling the Brightest NUV Footpoints in the X1 Solar Flare of 2014 March 29

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