Optical variability in Late-M and Early-L dwarfs
Dulaimi, Salam E. Hammeed
Dulaimi, Salam E. Hammeed
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Publication Date
2021-05-05
Type
Thesis
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Abstract
Brown dwarfs and low-mass stars together comprise the group of galactic objects known as ultracool dwarfs. A number have been detected as radio sources – in some cases, emitting periodic radio pulses synchronised to the dwarf's known rotational period. Detections of optical variability in ultracool dwarfs have been primarily attributed to stellar rotation, with the modulations observed a consequence of either magnetic spots on the surface, the presence of atmospheric dust, or auroral emission. A combination of these mechanisms may be required to explain some dwarf lightcurves. Rotational estimates of ultracool dwarfs are typically obtained spectroscopically; however accurate estimates of true rotation velocities require knowledge of the dwarf's rotational inclination axes. Direct measurement of a rotational signature in photometric data however provides an unambiguous rotational period, and this information can be used to constrain dwarf inclination geometries. In this thesis, we report on over ~ 160 hrs monitoring in I-band of multiple epochs from four ultracool dwarfs, spanning M tight binary dwarf 2MASS J1314203+132001A and L tight binary dwarf 2MASS J0746425+200032AB, the M9.5 dwarf BRI 0021-0214, and the L3.5 dwarf 2MASS J00361617+18211. This photometric campaign was carried out using the Galway Ultra-Fast Imager (GUFI) on the 1.8m Vatican Advanced Technology Telescope (VATT), on Mt. Graham, Arizona. All selected dwarfs exhibit periodic optical variability, where periods of both secondary components for our binary samples were newly discovered. This thesis discusses the use of two photometric analysis tools with the explicit aim of improving the quality of ground-based photometric measurements. Each data set was used to test the performance of the two systems. We find the LuckyPhot technique has obvious benefits to high precision photometry by reducing photometric errors, where the mean RMS error was reduced by ~ 47% with respect to the errors produced by the more standard GUFI pipeline method. This thesis also outlines a novel tool, Light Curve Fitter, which we apply to the binaries to investigate the presence of periodic photometric modulation in both binary members: refining the dominant member variability parameters, and searching for an elusive period of the weaker member. Light Curve Fitter is a python-based program, capable of detecting superposition of two sinusoidal waves to untangle the weaker components variability signature from that of the dominant source variability. We identify a newly discovered optical variability in the primary and secondary components of ultracool dwarf binary 2MASS J1314203+132001AB and 2MASS J0746425+200032AB, respectively. The optical data presented for both systems shows strongly correlated emissions in terms of phase and temporal variability. We have also shown the A and B variability signals of both dwarf binaries 2MASS J0746425+200032AB and 2MASS J1314203+132001AB, respectively, to be extremely consistent and stable over multiple epochs. This stability had seen in both radio and spectroscopic data, and the mechanism driving these processes in different parts of the electromagnetic spectrum could perhaps be fundamentally linked. We also investigate the orbital coplanarity of both binary dwarfs. Here the ability to deconvolve the inclination angle from the spectroscopic radial velocities, using direct estimates of the dwarf rotational periods, allows us to constrain the spin-orbit coupling of the binary system. In the case of the L dwarf binary 2MASS J0746425+200032AB, we calculate the equatorial inclination angle of the binary rotation axes are in alignment with the orbital plane of the system to within 10 degrees, consistent with solar-type binary formation mechanisms. For the M7 dwarf binary 2MASS J1314203+132001AB, due to missing parameters for the primary component, we investigate a tentative alignment of the spin-orbital axes of the A component. We find that the equatorial inclination angle of the secondary member spin axes is largely consistent with being aligned perpendicularly to the orbital plane. Finally, we find the rotation axes of the two single dwarfs are not perpendicular to our line of sight.
Publisher
NUI Galway
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Attribution-NonCommercial-NoDerivs 3.0 Ireland