Periodic Bursts of Coherent Radio Emission from an Ultracool Dwarf

Hallinan, Gregg; Bourke, S.; Lane, Caoilfhionn; Antonova, A.; Zavala, R. T.; Brisken, Walter; Boyle, R. P.; Vrba, F. J.; Doyle, J. G.; Golden, Aaron

doi:10.1086/519790

Cited by 224 publications

(341 citation statements)

References 27 publications

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“…From previous observations we know that the rotation period is ≈1.96 h (Hallinan et al 2006;Lane et al 2007). The main difference between the present data and the 2006 data reported by Hallinan et al (2007) is that the intervals of activity are longer, typically spread over 0.25 phase, comprising of several pulses. For the June 2007 data shown in Fig.…”

Section: Resultscontrasting

confidence: 88%

“…In addition, we have an inter-pulse at ≈3.8 h (best seen in Stokes I but also visible in Stokes V), i.e. 0.5 phase later than the pulse at ≈2.8 h. As shown by Hallinan et al (2007), due to the beaming of the ECM emission, additional activity can be observed ≈0.5 phase later. However, depending on the local density condition, this secondary activity 0.5 phase later is not always observed.…”

Section: Resultssupporting

confidence: 50%

“…In January 2005, Hallinan et al (2006) observed the same target simultaneously at 8.4 GHz and 4.9 GHz for a total of 5 h. These authors reported a periodicity at both frequencies of ≈2 h (later confirmed as the rotation period of the dwarf, Lane et al 2007), with a ≈400 μJy flux at 8.4 GHz. The first report of pulsed emission from TVLM 513 was by Hallinan et al (2007) (2008) report a nonperiodicity in the pulses/flaring activity (see later). A summary of the radio observations of TVLM 513 is given in Table 1.…”

Section: Introductionmentioning

confidence: 98%

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Phase connecting multi-epoch radio data for the ultracool dwarf TVLM 513-46546

Doyle¹,

Antonova

Marsh

et al. 2010

A&A

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Context. Radio data obtained for the ultracool dwarf TVLM 513-46546 has indicated a rotation period of ≈1.96 h via regular radio pulses, but how stable is this period. This has major implications regarding the stability of the magnetic field structures responsible for the radio emission from the ultracool dwarf. Aims. The aim of the present work is to investigate the stability of this rotation period using two datasets taken ≈40 days apart, some 12 months after the first report of periodical pulses in the radio data. Methods. Here we use a Bayesian analysis method which is a statistical procedure that endeavours to estimate the parameters of an underlying model probability distribution based on the observed data. Results. Periodical pulses are detected in datasets taken in April and June 2007, with the pulses being confined to a narrow range in the rotation period. This is in contradiction to a previous report of only aperiodic activity in the April 2007 dataset, while in fact both datasets have a periodic signal with a false alarm probability 10 −12 . These two datasets are then used to derive a more accurate period (previously determined to be 1.96 h) of 1.96733 ± 0.00002 h. Conclusions. The similarly in the burst structure in datasets taken several weeks apart point towards the stability of an electric field structure which is somehow generated and sustained within the magnetosphere of the ultracool dwarf. The derived period of 1.96733 h is consistent with the period derived via radio and optical data taken some 12 months prior to the present observations and implies the near phase constancy of the pulsed emission. This suggest the presence of stable large-scale magnetic fields on timescales of more than 1 year. The characteristics of the pulses suggest that they are produced by the electron cyclotron maser (ECM) instability.

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Section: Resultscontrasting

confidence: 88%

Section: Resultssupporting

confidence: 50%

Section: Introductionmentioning

confidence: 98%

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Phase connecting multi-epoch radio data for the ultracool dwarf TVLM 513-46546

Doyle¹,

Antonova

Marsh

et al. 2010

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“…By contrast, brown dwarfs are very bright radio emitters, but no correlation between X-ray and radio emission exists as is established for stars and solar events (Güdel-Benz relation, Benz and Güdel 1994). Since the discovery of the first radio emitting brown dwarf by Berger et al (2001), numerous surveys have detected radio emission at GHz frequencies in nearly 200 objects (Berger 2002(Berger , 2006Berger et al 2010;Hallinan et al 2006Hallinan et al , 2007Hallinan et al , 2008McLean et al 2012), including emission in the coolest brown dwarfs with spectral types as late as T6.5 (Route and Wolszczan 2012). In twelve of these objects, the radio emission is highly polarised, coherent and pulses on the rotation period of the dwarf.…”

Section: Multi-wavelength Observations Of Activity On Ultracool Dwarfsmentioning

confidence: 99%

“…In five of these systems, WD0137-349B (Maxted et al 2006), NLTT5306 (Steele et al 2013), SDSS141126þ200911 (Beuermann et al 2013), WD0837þ185 (Casewell et al 2012) and GD1400B (Farihi and Christopher 2004), the brown dwarf is known to have survived a phase of common envelope Fig. 13 Light curves of the total intensity (Stokes I) and the circularly polarised (Stokes V) radio emission detected at 8.44 GHz from TVLM 513-46546, an M9.5 dwarf, taken from Hallinan et al (2007). Right circular polarisation is represented by positive values, and left circular polarisation is represented by negative values in the Stokes V light curve.…”

Section: Multi-wavelength Observations Of Activity On Ultracool Dwarfsmentioning

confidence: 99%

Atmospheric Electrification in Dusty, Reactive Gases in the Solar System and Beyond

et al. 2016

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Detailed observations of the solar system planets reveal a wide variety of local atmospheric conditions. Astronomical observations have revealed a variety of extrasolar planets none of which resembles any of the solar system planets in full. Instead, the most massive amongst the extrasolar planets, the gas giants, appear very similar to the class of (young) brown dwarfs which are amongst the oldest objects in the Universe. Despite this diversity, solar system planets, extrasolar planets and brown dwarfs have broadly similar global temperatures between 300 and 2500 K. In consequence, clouds of different chemical species form in their atmospheres. While the details of these clouds differ, the fundamental physical processes are the same. Further to this, all these objects were observed to produce radio and X-ray emissions. While both kinds of radiation are well studied on Earth and to a lesser extent on the solar system planets, the occurrence of emissions that potentially originate from accelerated electrons on brown dwarfs, extrasolar planets and protoplanetary disks is not well understood yet. This paper offers an interdisciplinary view on electrification processes and their feedback on their hosting environment in meteorology, volcanology, planetology and research on extrasolar planets and planet formation.

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Loss cone‐driven cyclotron maser instability

Lee

Lim

et al. 2013

JGR Space Physics

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[1] The weakly (or mildly) relativistic cyclotron maser instability has been successfully applied to explain the Earth's auroral kilometric radiation and other radio sources in nature and laboratory. Among the most important physical parameters that determine the instability criteria is the ratio of plasma-to-electron cyclotron frequencies, ! p / . It is therefore instructive to consider how the normalized maximum growth rate, max / , varies as a function of ! p / . Although many authors have already discussed this problem, in order to complete the analysis, one must also understand how the radiation emission angle corresponding to the maximum growth, Â max , scales with ! p / , since the propagation angle determines the radiation beaming pattern. Also, the behavior of the frequency corresponding to the maximum growth rate at each harmonic, (! max -s )/ , where s = 1, 2, 3, : : : , as a function of ! p / is of importance for a complete understanding of the maser excitation. The present paper computes these additional quantities for the first time, making use of a model loss cone electron distribution function.

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Periodic Bursts of Coherent Radio Emission from an Ultracool Dwarf

Cited by 224 publications

References 27 publications

Phase connecting multi-epoch radio data for the ultracool dwarf TVLM 513-46546

Phase connecting multi-epoch radio data for the ultracool dwarf TVLM 513-46546

Atmospheric Electrification in Dusty, Reactive Gases in the Solar System and Beyond

Loss cone‐driven cyclotron maser instability

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