Searching for planet-induced radio signal from the young close-in planet host star HIP 67522

TL;DR

This study conducted an extensive radio monitoring campaign of the young star HIP 67522, searching for signatures of magnetic star-planet interactions, but found no definitive orbital modulation despite indications of planet-induced flaring activity.

Contribution

First long-term radio observation campaign targeting a young star with close-in planets, providing constraints on star-planet magnetic interactions and emission mechanisms.

Findings

Radio emission is active and variable, with frequent bursts and quiescent periods.

No detectable orbital modulation or persistent polarization was observed.

Upper limit on circular polarization suggests low efficiency of star-planet magnetic energy conversion.

Abstract

HIP 67522 is a 17 Myr old 1.2$M_\odot$ dwarf, and the only such young star known to host two close-in gas giant planets. The inner planet likely orbits close enough to its host to power magnetic star-planet interactions. In the radio domain, magnetic star-planet interaction is expected to produce a unique signature: electron cyclotron maser emission (ECME), beamed in phase with the orbit of the close-in planet. We conducted the longest radio monitoring campaign of a G dwarf host star to date to search for ECME, totaling $135\,$h on HIP 67522 over a period of five months with the Australia Telescope Compact Array (ATCA) between $1.1-3.1$GHz. We find that HIP 67522 is active in the radio, with emission that varies stochastically, with a duty cycle of $69\%$ above $0.24$mJy, and frequent bursts. Both the bursts and the quiescent emission are consistent with the canonical G\"udel-Benz relation, and show a positive spectral index and brightness temperatures $\geq 10^{10}$K, indicating likely a flaring origin. Our observations cover $61\%$ of the innermost planet's orbit, including multiple visits of the quadrature where planet-induced ECME detection is most likely for this system. However, no orbital modulation or persistent polarization of the radio emission was detected. Our upper limit on circularly polarized emission from HIP 67522 suggests a $<0.7\%$ conversion efficiency of the magnetic power generated in the star-planet interaction into radio waves, unless the emission was missed by our phase or frequency coverage, or was absorbed in the circumstellar plasma. HIP 67522 is a system with one of the highest expected powers of star-planet interaction among known systems and shows strong indication of planet-induced flaring, motivating observations at other wavelengths to probe for further dissipation pathways.