Bandwidth smearing in infrared long-baseline interferometry. Application to stellar companion search in fringe-scanning mode

TL;DR

This paper develops an analytical correction method for bandwidth smearing effects in infrared long-baseline interferometry, improving the accuracy of stellar companion detection and characterization.

Contribution

It introduces a novel analytical approach to correct bandwidth smearing in interferometric data, accounting for instrumental and atmospheric effects.

Findings

Chromatic dispersion significantly biases closure phase measurements.

Atmospheric turbulence impacts bias mainly at low spectral resolution.

Modeling a Gaussian bandpass improves fit quality under moderate smearing.

Abstract

In long-baseline interferometry, bandwidth smearing of an extended source occurs at finite bandwidth when its different components produce interference packets that only partially overlap. In this case, traditional model fitting or image reconstruction using standard formulas and tools lead to biased results. We propose and implement a method to overcome this effect by calculating analytically a corrective term for the conventional interferometric observables: the visibility amplitude and closure phase. For that purpose, we model the interferogram taking into account the finite bandwidth and the instrumental differential phase. We obtain generic expressions for the visibility and closure phase in the case of temporally-modulated interferograms, either processed using Fourier analysis or with the ABCD method. The expressions can be used to fit arbitrary models to the data. We then apply our results to the search and characterisation of stellar companions with PIONIER at the Very Large Telescope Interferometer, assessing the bias on observables and model-fitted parameters of a binary star. Finally, we consider the role of the atmosphere, with an analytic model to identify the main contributions to bias and also a numerical simulation of the turbulence. In addition to the analytic expressions, the main results of our study are: the chromatic dispersion in the beam transport in the instrument has a strong impact on the closure phase and introduces additional biases even at separations where smearing is not expected to play an important role; the atmospheric turbulence introduces additional biases when smearing is present, but the impact is important only at very low spectral resolution; the bias on the observables strongly depends on the recombination scheme and data processing; the goodness of fits is improved by modelling a Gaussian bandpass as long as the smearing is moderate.