Grain Alignment and Dust Evolution Physics with Polarisation (GRADE-POL). I. Dust Polarisation Modelling for Isolated Starless Cores

The polarisation of light induced by aligned interstellar dust serves as a significant tool in investigating cosmic magnetic fields, dust properties, and poses a challenge in characterising the polarisation of the cosmic microwave background and other sources. To establish dust polarisation as a reliable tool, the physics of the grain alignment process needs to be studied thoroughly. The Magnetically enhanced Radiative Torque (MRAT) alignment is the only mechanism that can induce highly efficient alignment of grains with magnetic fields required by polarisation observations of the diffuse interstellar medium. Here, we aim to test the MRAT mechanism in starless cores using the multiwavelength polarisation from optical/NIR to far-IR/submm. Our numerical modelling of dust polarisation using the MRAT theory demonstrated that the alignment efficiency of starlight polarisation (p_ ext/A_ V) and the degree of thermal dust polarisation (p_ em) first decrease slowly with increasing visual extinction (A_ V) and then falls steeply as ∝ A^-1_ V at large A_ V due to the loss of grain alignment, which explains the phenomenon known as polarisation holes. Visual extinction at the transition from shallow to steep slope (A^ loss_ V) increases with the maximum grain size. By applying physical profiles suitable for a starless core Pipe-109, our model successfully reproduces the existing observations of starlight polarisation at R-band (0.65 μm) and H-band (1.65 μm), as well as emission polarisation at submillimeter (850 μm). Successful modelling of observational data requires perfect alignment of large grains as evidence of the MRAT mechanism, and larger maximum size with higher elongation at higher A_ V. The latter reveals the first evidence for the new model of anisotropic grain growth induced by magnetic grain alignment.