Quantum Tunneling Could Enable Proton Transfer Reactions on Titan

TL;DR

This paper demonstrates that quantum tunneling enables proton transfer reactions on Titan's cold surface, potentially facilitating prebiotic chemistry through nuclear quantum effects at cryogenic temperatures.

Contribution

The study introduces the role of quantum tunneling in proton transfer reactions on Titan, highlighting its significance in low-temperature prebiotic chemistry modeling.

Findings

Proton transfer can occur via quantum tunneling at Titan's surface conditions.

Nuclear quantum effects can significantly increase reaction rates.

Quantum effects are important for understanding prebiotic chemistry on Titan.

Abstract

The surface of Titan, Saturn's largest moon, is rich in organics and is often suggested to model early Earth environments. Titan's surface is cold, at a temperature of approximately 90 K, which prohibits most thermally activated chemical reactions. However, quantum effects become more important at low temperatures and reactions that are classically prohibited can often proceed through quantum mechanical pathways. Using path integral molecular dynamics simulations, we investigate nuclear quantum effects on the thermodynamics of model proton transfer reactions in liquid ethane. We find that proton transfer can occur at Titan surface conditions through quantum tunneling. Consequently, we estimate that nuclear quantum effects can enhance reaction rates by many orders of magnitude. Our results suggest that nuclear quantum effects could facilitate prebiotic chemistry on Titan, and quantum effects should be considered in future investigations.