Role of NH3 Binding Energy in the Early Evolution of Protostellar Cores
Abstract
NH3(ammonia) plays a critical role in the chemistry of star and planet formation, yet uncertainties in its binding energy (BE) values complicate accurate estimates of its abundances. Recent research suggests a multi-binding energy approach, challenging the previous single-value notion. In this work, we use different values of NH3 binding energy to examine its effects on the NH3 abundances and, consequently, in the early evolution of protostellar cores. Using a gas-grain chemical network, we systematically vary the values of NH3 binding energies in a model Class 0 protostellar core and study the effects of these binding energies on the NH3 abundances. Our simulations indicate that abundance profiles of NH3 are highly sensitive to the binding energy used, particularly in the warmer inner regions of the core. Higher binding energies lead to lower gas-phase NH3 abundances, while lower values of binding energy have the opposite effect. Furthermore, this BE-dependent abundance variation of NH3 significantly affects the formation pathways and abundances of key species such as HNC, HCN, and CN. Our tests also reveal that the size variation of the emitting region due to binding energy becomes discernible only with beam sizes of 10 arcsec or less. These findings underscore the importance of considering a range of binding energies in astrochemical models and highlight the need for higher resolution observations to better understand the subtleties of molecular cloud chemistry and star formation processes.
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