New Evidence for a Flux-independent Spectral Index of Sgr A* in the Near-infrared
Abstract
In this work, we measure the spectral index of Sagittarius A* (Sgr A*) between the H (1.6 μm) and K (2.2 μm) broadband filters in the near-infrared (NIR), sampling over a factor 40 in brightness, the largest range probed to date by a factor 3. Sgr A*-NIR is highly variable, and studying the spectral index α (with F α) is essential to determine the underlying emission mechanism. For example, variations in α with flux may arise from shifts in the synchrotron cutoff frequency, changes in the distribution of electrons, or multiple concurrent emission mechanisms. We investigate potential variations of αH-K with flux by analyzing 7 epochs (2005 to 2022) of Keck Observatory imaging observations from the Galactic Center Orbits Initiative (GCOI). We remove the flux contribution of known sources confused with Sgr A*-NIR, which can significantly impact color at faint flux levels. We interpolate between the interleaved H and K observations using Multi-Output Gaussian Processes. We introduce a flexible empirical model to quantify α variations and probe different scenarios. The observations are best fit by an αH-K = - 0.50 0.08 stat 0.17 sys that is constant from 1 mJy to 40 mJy (dereddened 2 μm flux). We find no evidence for a flux-dependence of Sgr A*'s intrinsic spectral index. In particular, we rule out a model explaining NIR variability purely by shifts in the synchrotron cutoff frequency. We also constrain the presence of redder, quiescent emission from the black hole, concluding that the dereddened 2 μm flux contribution must be ≤ 0.3 mJy at 95% confidence level.
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