On the Radio Detectability of Circumplanetary Discs

TL;DR

This paper investigates the radio detectability of circumplanetary discs using simple disc models, highlighting optimal wavelengths, detection thresholds, and the importance of dust replenishment for observing these discs around young planets.

Contribution

It provides quantitative estimates for detecting CPDs at millimetre and centimetre wavelengths, considering dust dynamics and observational strategies, which advances understanding of planet formation observations.

Findings

ALMA Band 7 can detect small dust masses in CPDs at 140 pc.

Detection is possible for CPDs around Jupiter-mass planets at 20 AU with certain accretion rates.

Dust drift timescales are short, requiring replenishment or specific conditions for detectability.

Abstract

Discs around young planets, so-called circumplanetary discs (CPDs), are essential for planet growth, satellite formation, and planet detection. We study the millimetre and centimetre emission from accreting CPDs by using the simple $\alpha$ disc model. We find that it is easier to detect CPDs at shorter radio wavelengths (e.g. $\lambda\lesssim$ 1 mm). For example, if the system is 140 pc away from us, deep observations (e.g. 5 hours) at ALMA Band 7 (0.87 mm) are sensitive to as small as 0.03 lunar mass of dust in CPDs. If the CPD is around a Jupiter mass planet 20 AU away from the host star and has $\alpha\lesssim 0.001$, ALMA can detect this disc when it accretes faster than $10^{-10} M_{\odot}/yr$. ALMA can also detect the "minimum mass sub-nebulae" disc if such a disc exists around a young planet in YSOs. However, to distinguish the embedded compact CPD from the circumstellar disc material, we should observe circumstellar discs with large gaps/cavities using the highest resolution possible. We also calculate the CPD fluxes at VLA bands, and discuss the possibility of detecting radio emission from jets/winds launched in CPDs. Finally we argue that, if the radial drift of dust particles is considered, the drifting timescale for millimetre dust in CPDs can be extremely short. It only takes 10$^2$-10$^{3}$ years for CPDs to lose millimetre dust. Thus, for CPDs to be detectable at radio wavelengths, mm-sized dust in CPDs needs to be replenished continuously, or the disc has a significant fraction of micron-sized dust or a high gas surface density so that the particle drifting timescale is long, or the radial drift is prevented by other means (e.g. pressure traps).