Near infrared and optical continuum emission region size measurements in the gravitationally lensed quasars Q0957+561 and SBS0909+532

TL;DR

This study uses microlensing to measure the size of quasar emission regions across multiple wavelengths, revealing a shallower size-wavelength relation than thin disk theory predicts, consistent with other microlensing results.

Contribution

It provides new size measurements of quasar emission regions in multiple bands and constrains the wavelength scaling of accretion disk sizes using Bayesian analysis.

Findings

Measured emission region sizes in three bands for two quasars.

Found a size-wavelength scaling slope shallower than thin disk theory.

Results align with previous microlensing studies.

Abstract

We present a microlensing analysis of updated light curves in three filters, $g$--band, $r$--band, and $H$--band, for the gravitationally lensed quasars Q0957+561 and SBS0909+532. Both systems display prominent microlensing features which we analyze using our Bayesian Monte Carlo technique to constrain the quasar continuum emission region sizes in each band. We report sizes as half-light radii scaled to a 60 degree inclination angle. For Q0957+561 we measure $\log{(r_{1/2}/\text{cm})} = 16.54^{+0.33}_{-0.33}$, $16.66^{+0.37}_{-0.62}$, and $17.37^{+0.49}_{-0.40}$ in $g$--, $r$--, and $H$--band respectively. For SBS0909+532 we measure $\log{(r_{1/2}/\text{cm})} = 15.83^{+0.33}_{-0.33}$, $16.21^{+0.37}_{-0.62}$, and $17.90^{+0.61}_{-0.63}$ in $g$--, $r$--, and $H$--band respectively. With size measurements in three bands spanning the quasar rest frame ultraviolet to optical, we can place constraints on the scaling of accretion disk size with wavelength, $r\propto\lambda^{1/\beta}$. In a joint analysis of both systems we find a slope shallower than that predicted by thin disk theory, $\beta = 0.35^{+0.16}_{-0.08}$, consistent with other constraints from multi-epoch microlensing studies.