Direct Spectral Detection: An Efficient Method to Detect and Characterize Binary Systems

TL;DR

This paper introduces a direct spectral detection method that efficiently identifies and characterizes binary star companions using high-resolution spectra, enabling detection with small telescopes and complementing imaging techniques.

Contribution

The paper presents a novel application of the direct spectral detection method for binary star detection, including calibration of biases and successful characterization of companions in known systems.

Findings

Detected nine binary companions in a sample of 34 systems.

Successfully characterized two previously single-lined binaries.

Method is effective for companions with moderate mass ratios within 100-200 mas.

Abstract

Young, intermediate-mass stars are experiencing renewed interest as targets for direct-imaging planet searches. However, these types of stars are part of multiple systems more often than not. Close stellar companions affect the formation and orbital evolution of any planets, and the properties of the companions can help constrain the binary formation mechanism. Unfortunately, close companions are difficult and expensive to detect with imaging techniques. In this paper, we describe the direct spectral detection method wherein a high-resolution spectrum of the primary is cross-correlated against a template for a companion star. Variants of this method have previously been used to search for stellar, brown dwarf, and even planetary companions. We show that the direct spectral detection method can detect companions as late as M-type orbiting A0 or earlier primary stars in a single epoch on small-aperture telescopes. In addition to estimating the detection limits, we determine the sources of uncertainty in characterizing the companion temperature, and find that large systematic biases can exist. After calibrating the systematic biases with synthetic binary star observations, we apply the method to a sample of 34 known binary systems with an A- or B-type primary star. We detect nine total companions, including four of the five known companions with literature temperatures between $4000$ K $ < T < 6000$ K, the temperature range for which our method is optimized. We additionally characterize the companion for the first time in two previously single-lined binary systems and one binary identified with speckle interferometry. This method provides an inexpensive way to use small-aperture telescopes to detect binary companions with moderate mass-ratios, and is competitive with high-resolution imaging techniques inside $\sim 100-200$ mas.