Chemical Differentiation and Temperature Distribution on a Few au Scale around the Protostellar Source B335

TL;DR

This study uses high-resolution ALMA observations to analyze chemical differentiation and temperature distribution within a few au of the protostar B335, revealing distinct molecular distributions and heating mechanisms.

Contribution

It presents the first detailed chemical and temperature mapping at such small scales around B335, highlighting differentiation between oxygen- and nitrogen-bearing molecules and proposing accretion shocks as a heating source.

Findings

Nitrogen-bearing molecules are more compact than oxygen-bearing ones.

Outer envelope molecules are heated by mechanisms other than protostellar radiation.

Temperature differences suggest accretion shocks as a heating mechanism.

Abstract

Resolving physical and chemical structures in the vicinity of a protostar is of fundamental importance for elucidating their evolution to a planetary system. In this context, we have conducted 1.2 mm observations toward the low-mass protostellar source B335 at a resolution of 0."03 with ALMA. More than 20 molecular species including HCOOH, NH2 CHO, HNCO, CH3 OH, CH2 DOH, CHD2 OH, and CH3 OD are detected within a few 10 au around the continuum peak. We find a systematic chemical differentiation between oxygen-bearing and nitrogen-bearing organic molecules by using the principal component analysis for the image cube data. The distributions of the nitrogen-bearing molecules are more compact than those of the oxygen-bearing ones except for HCOOH. The temperature distribution of the disk/envelope system is revealed by a multi-line analysis for each of HCOOH, NH2 CHO, CH3 OH, and CH2 DOH. The rotation temperatures at the radius of 0."06 along the envelope direction of CH3OH and CH2DOH are derived to be 150-165 K. On the other hand, those of HCOOH and NH2CHO, which have a smaller distribution, are 75-112 K, and are significantly lower than those for CH3OH and CH2DOH. This means that the outer envelope traced by CH3OH and CH2DOH is heated by additional mechanisms rather than the protostellar heating. We here propose the accretion shock as the heating mechanism. The chemical differentiation and the temperature structure on a few au scale provide us with key information to further understand chemical processes in protostellar sources.