The mean infrared emission of SagittariusA*

TL;DR

This study provides new infrared flux limits for SagittariusA*, using advanced imaging techniques, constraining its emission in the near-to-mid infrared and refining its spectral energy distribution with implications for theoretical models.

Contribution

The paper introduces a novel speckle imaging and holographic reconstruction method to set tighter infrared emission limits for SagittariusA* and refines its spectral energy distribution.

Findings

No detection of SagittariusA* at 8.6 microns, with a 3 sigma upper limit of ~10 mJy.

Detection of SagittariusA* at 3.8 and 4.8 microns with flux densities of 5.0+-0.6 mJy and 3.8+-1.3 mJy.

Well-constrained flux estimates at 2.1-2.2 microns, supporting existing models.

Abstract

(abridged) The massive black hole at the center of the Milky Way, SagittariusA* is, in relative terms, the weakest accreting black hole accessible to observations. At the moment, the mean SED of SgrA* is only known reliably in the radio to mm regimes. The goal of this paper is to provide constraints on the mean emission from SgrA* in the near-to-mid infrared. Excellent imaging quality was reached in the MIR by using speckle imaging combined with holographic image reconstruction, a novel technique for this kind of data. No counterpart of SgrA* is detected at 8.6 microns. At this wavelength, SgrA* is located atop a dust ridge, which considerably complicates the search for a potential point source. An observed 3 sigma upper limit of ~10 mJy is estimated for the emission of SgrA* at 8.6 microns, a tighter limit at this wavelength than in previous work. The de-reddened 3 sigma upper limit, including the uncertainty of the extinction correction, is ~84 mJy . Based on the available data, it is argued that, with currently available instruments, SgrA* cannot be detected in the MIR, not even during flares. At 4.8 and 3.8 microns, on the other hand, SgrA* is detected at all times, at least when considering timescales of a few up to 13 min. We derive well-defined time-averaged, de-reddened flux densities of 3.8+-1.3 mJy at 4.8 microns and 5.0+-0.6 mJy at 3.8 microns. Observations with NIRC2/Keck and NaCo/VLT from the literature provide good evidence that SgrA* also has a fairly well-defined de-reddened mean flux of 0.5-2.5 mJy at wavelengths of 2.1-2.2 microns. We present well-constrained anchor points for the SED of SgrA* on the high-frequency side of the Terahertz peak. The new data are in general agreement with published theoretical SEDs of the mean emission from SgrA*, but we expect them to have an appreciable impact on the model parameters in future theoretical work.