Highly covalent molecular cage based porous organic polymer: pore size control and pore property enhancement

Zhen Wang; Yan-Qun Liu; Yu-Hang Zhao; Qing-Pu Zhang; Yu-Ling Sun; Bin-Bin Yang; Jian-Hua Bu; Chun Zhang

doi:10.1039/d2ra02343a

Highly covalent molecular cage based porous organic polymer: pore size control and pore property enhancement

RSC Adv. 2022 Jun 6;12(26):16486-16490. doi: 10.1039/d2ra02343a. eCollection 2022 Jun 1.

Authors

Zhen Wang¹, Yan-Qun Liu², Yu-Hang Zhao¹, Qing-Pu Zhang¹, Yu-Ling Sun¹, Bin-Bin Yang¹, Jian-Hua Bu³, Chun Zhang¹

Affiliations

¹ College of Life Science and Technology, National Engineering Research Center for Nanomedicine, Huazhong University of Science and Technology Wuhan 430074 China zhenwang89@hust.edu.cn chunzhang@hust.edu.cn.
² Henan Industry and Trade Vocational College Zhengzhou Henan 451191 China.
³ Xi'an Modern Chemistry Research Institute Xi'an Shanxi 710065 China bujianhua@gmail.com.

Abstract

It remains a great challenge to effectively control the pore size in porous organic polymers (POPs) because of the disordered linking modes. Herein, we used organic molecular cages (OMCs), possessing the properties of fixed intrinsic cavities, high numbers of reactive sites and dissolvable processability, as building blocks to construct a molecular cage-based POP (TPP-pOMC) with high valency through covalent cross coupling reaction. In the formed TPP-pOMC, the originating blocking pore channels of TPP-OMC were "turned on" and formed fixed pore channels (5.3 Å) corresponding to the connective intrinsic cavities of cages, and intermolecular pore channels (1.34 and 2.72 nm) between cages. Therefore, TPP-pOMC showed significant enhancement in Brunauer-Emmett-Teller (BET) surface area and CO₂ adsorption capacity.