A versatile messenger for chirality communication: asymmetric silica framework

Abstract

Asymmetric tetrahedral carbon is the basic structural unit of many organic compounds in life and its molecular chirality plays a key role in regulating biological functions. Silica (SiO2) is highly earth abundant and its basic unit is also the tetrahedral form of SiO4. However, much less attention has been paid to the molecular-scale chirality of SiO2 frameworks with repeating SiO4 units because it is challenging to enantioselectively control the molecular structures of SiO2. Research into the chiral molecular structures of SiO2 deserves to be a significant topic for understanding widespread chiral phenomena and for exploring the chiral properties hidden in inorganic matter. This review highlights the asymmetric synthesis strategies that endow SiO2 with chirality transferred from asymmetric carbon at the molecular scale. The chirality transfer ability of SiO2 is also demonstrated for the construction of various inorganic and/or organic chiral materials with a wide range of applications in asymmetric synthesis, circularly polarized luminescence and Raman scattering-based chiral recognition.