Physical characterisation of low delta-V asteroid (175706) 1996 FG3

TL;DR

This study characterizes the physical properties of asteroid 1996 FG3, including size, albedo, and thermal inertia, using thermal IR and optical observations, to inform its potential for a sample-return mission.

Contribution

The paper provides detailed thermal and optical measurements of asteroid 1996 FG3, applying advanced models to derive its physical properties with implications for its binary formation.

Findings

Effective diameter ~1.7 km

Low surface thermal inertia (~120 J m^-2 s^-1/2 K^-1)

Predicted Yarkovsky drift of -60 m/yr

Abstract

Asteroid (175706) 1996 FG3 is a binary asteroid and the baseline target for the proposed MarcoPolo-R sample-return mission. We present thermal IR photometry obtained with the ESO VLT+VISIR together with optical photometry obtained with the ESO NTT+EFOSC2 . An absolute visual magnitude H_V = 17.833 \pm 0.024 and phase parameter G = -0.041 \pm 0.005 is derived. The Near-Earth Asteroid Thermal Model (NEATM) has been fitted to the measured fluxes to derive a geometric visual albedo p_v = 0.046 \pm 0.014, effective diameter at the observed aspect D_eff = 1.68 \pm 0.25 km, and beaming parameter {\eta} = 1.15 for phase angle {\alpha} = 11.7{\deg}. The Advanced Thermophysical Model (ATPM) has been fitted to the measured fluxes to derive a more accurate effective diameter D_eff = 1.71 \pm 0.07 km and albedo p_v = 0.044 \pm 0.004. Based on the ATPM results, assuming the same albedo for primary and secondary, we derive a primary mean spherical diameter D_p = (1.69 +0.18/-0.12) km, secondary diameter D_s = 0.51 \pm 0.03 km, and a secondary orbital semi-major axis a = (2.8 +1.7/-0.7) km. A low surface thermal inertia {\Gamma} = 120 \pm 50 J m^-2 s^-1/2 K^-1 was also derived, suggesting a dusty surface and raising questions as to the binary formation mechanism of this asteroid. These physical properties are used to predict a Yarkovsky drift in semi-major axis of (-60 +31/-45) m yr-1.