Wide Separation Planets In Time (WISPIT): Discovery of a Gap H$\alpha$ Protoplanet WISPIT 2b with MagAO-X

TL;DR

This paper reports the discovery of an accreting protoplanet, WISPIT 2b, in the transitional disk of star WISPIT 2 using high-resolution H-alpha imaging, providing insights into planet formation and accretion processes.

Contribution

First direct imaging detection of an H-alpha emitting protoplanet with detailed characterization, including mass, accretion rate, and system inclination, suggesting a possible preferred accretion inclination range.

Findings

WISPIT 2b is a ~5.3 Mjup accreting protoplanet at ~54 au.

The system inclination (~44°) is similar to other H-alpha protoplanets.

A potential inner dusty companion candidate was also identified.

Abstract

Excellent (<25 mas) H$_{\alpha}$ images of the star TYC 5709-354-1 led to the discovery of a rare H$_{\alpha}$ protoplanet. This star was discovered by the WISPIT survey to have a large multi-ring transitional disk, and is hereafter WISPIT 2. Our H$_{\alpha}$ images of 2025, April 13 and April 16 discovered an accreting (H$_{\alpha}$ in emission) protoplanet: WISPIT 2b (r=309.43$\pm$1.56 mas; (~54 au deprojected), PA=242.21$\pm$0.41 degrees) likely clearing a dust-free gap between the two brightest dust rings in the transitional disk. Our SNR=12.5 detection gave an H$_{\alpha}$ ASDI contrast of (6.5$\pm$0.5)x10$^{-4}$ and a H$_{\alpha}$ line flux of (1.29$\pm$0.28)x10$^{-15}$ erg/s/cm$^2$. We also present L' photometry from LBT/LMIRcam of the planet (L'=15.30$\pm$0.05 mag) which, when coupled with an age of 5.1$^{+2.4}_{-1.3}$ Myr, yields a planet mass estimate of 5.3$\pm$1.0 Mjup from the DUSTY evolutionary models. WISPIT 2b is accreting at 2.25$^{-0.17}_{+3.75}$x10$^{-12}$ Msun/yr. WISPIT 2b is very similar to the other H$_{\alpha}$ protoplanets in terms of mass, age, flux, and accretion rate. The inclination of the system (${\it i}$=44 degrees) is also, surprisingly, very similar to the other known H$\alpha$ protoplanet systems which all cluster from 37$\leq{\it i}\leq$52 degrees. We argue this clustering has only a ~1.0% (2.6 sigma) probability of occurring randomly, and so we speculate that magnetospherical accretion might have a preferred inclination range (~37-52 degrees) for the direct (cloud free, low extinction) line of sight to the H-alpha line formation/shock region. We also find at 110mas (~15au deprojected) a close companion candidate (CC1) which may be consistent with an inner dusty 9$\pm$4 Mjup planet.