A bright inner disk and structures in the transition disk around the very low-mass star CIDA 1

Observations of protoplanetary disks around very low mass stars and Brown Dwarfs remain challenging and little is known about the properties of these disks. The disk around CIDA 1 ($\sim$0.1-0.2 $M_\odot$) is one of the very few known disks that hosts a large cavity (20 au radius in size) around a very low mass star. We present new ALMA observations at Band 7 (0.9 mm) and Band 4 (2.1 mm) of CIDA 1 with a resolution of $\sim 0.05''\times 0.034''$. These new ALMA observations reveal a very bright and unresolved inner disk, a shallow spectral index of the dust emission ($\sim2$), and a complex morphology of a ring located at 20 au. We also present X-Shooter (VLT) observations that confirm a high value of the accretion rate of CIDA 1 of $\dot{M}_{\rm acc}$ = 1.4 $~\times~10^{-8} M_\odot$/yr. This high value of $\dot{M}_{\rm acc}$, the observed inner disk, and the large cavity of 20 au exclude models of photo-evaporation as potential origin of the observed cavity. When comparing these observations with models that combine planet-disk interaction, dust evolution, and radiative transfer, we exclude planets more massive than 0.5 $M_{\rm{Jup}}$ as the potential origin of the large cavity because otherwise it is difficult to maintain a long-lived and bright inner disk. Even in this planet mass regime, an additional physical process may be needed to stop the particles to migrate inwards and maintain a bright inner disk at million-years timescales. Such mechanisms include a trap formed by a very close-in extra planet or the inner edge of a dead zone. The low spectral index of the disk around CIDA 1 is difficult to explain and challenges our current dust evolution models, in particular processes like fragmentation, growth, and diffusion of particles inside pressure bumps.