Proper Motions of the LMC and SMC: Reanalysis of Hubble Space Telescope Data

TL;DR

This paper reanalyzes Hubble Space Telescope data to verify proper motions of the LMC and SMC, revealing a detectable rotation of the LMC and refining previous measurements with improved systematic corrections.

Contribution

It provides an independent reanalysis of proper motions, correcting systematic errors, and for the first time detects the rotation of the LMC using proper motion data.

Findings

Proper motions are consistent with previous measurements after correction.

Detected rotation of the LMC with a velocity of 120 ± 15 km/s.

Improved data reduction methods enhance measurement reliability.

Abstract

Kallivayalil et al. have used the \textit{Hubble Space Telescope} to measure proper motions of the LMC and SMC using images in 21 and five fields, respectively, all centered on known QSOs. These results are more precise than previous measurements, but have surprising and important physical implications: for example, the LMC and SMC may be approaching the Milky Way for the first time; they might not have been in a binary system; and the origin of the Magellanic Stream needs to be re-examined. Motivated by these implications, we have reanalyzed the original data in order to check the validity of these measurements. Our work has produced a proper motion for the LMC that is in excellent agreement with that of Kallivayalil et al., and for the SMC that is in acceptable agreement. We have detected a dependence between the brightness of stars and their mean measured motion in a majority of the fields in both our reduction and that of Kallivayalil et al. Correcting for this systematic error and for the errors caused by the decreasing charge transfer efficiency of the detector produces better agreement between the measurements from different fields. With our improved reduction, we do not need to exclude any fields from the final averages and, for the first time using proper motions, we are able to detect the rotation of the LMC. The best-fit amplitude of the rotation curve at a radius of 275 arcmin in the disk plane is $120 \pm 15$ km s$^{-1}$. This value is larger than the 60--70 km s$^{-1}$ derived from the radial velocities of HI and carbon stars, but in agreement with the value of 107 km s$^{-1}$ derived from the radial velocities of red supergiants.