Highly-Controlled Soft-Templating Synthesis of Hollow ZIF-8 Nanospheres for Selective CO Separation and Storage

Overview

Journal ACS Appl Mater Interfaces

Publisher American Chemical Society

Specialties Biomedical Engineering
Biotechnology

Date 2023 Jun 22

PMID 37345663

Authors

Fraz Saeed Butt

Allana Lewis

Riccardo Rea

Nurul A Mazlan

Ting Chen

Norbert Radacsi

Enzo Mangano

Xianfeng Fan

Yaohao Yang

Shuiqing Yang

Yi Huang

Affiliations

Soon will be listed here.

Abstract

Global warming is an ever-rising environmental concern, and carbon dioxide (CO) is among its major causes. Different technologies, including adsorption, cryogenic separation, and sequestration, have been developed for CO separation and storage/utilization. Among these, carbon capture using nano-adsorbents has the advantages of excellent CO separation and storage performance as well as superior heat- and mass-transfer characteristics due to their large surface area and pore volume. In this work, an environmentally friendly, facile, bottom-up synthesis of ZIF-8 hollow nanospheres (with reduced chemical consumption) was developed for selective CO separation and storage. During this soft-templating synthesis, a combined effect of ultra-sonication and low-temperature hydrothermal synthesis showed better control over an oil-in-water microemulsion formation and the subsequent growth of large-surface-area hollow ZIF-8 nanospheres having excellent particle size distribution. Systematic studies on the synthesis parameters were also performed to achieve fine-tuning of the ZIF-8 crystallinity, hollow structures, and sphere size. The optimized hollow ZIF-8 nanosphere sample having uniform size distribution exhibited remarkable CO adsorption capability (∼2.24 mmol g at 0 °C and 1.75 bar), a CO/N separation selectivity of 12.15, a good CO storage capacity (1.5-1.75 wt %), and an excellent cyclic adsorption/desorption performance (up to four CO adsorption/desorption cycles) at 25 °C. In addition, the samples showed exceptional structural stability with only ∼15% of overall weight loss up to 600 °C under a nitrogen environment. Therefore, the hollow ZIF-8 nanospheres as well as their highly controlled soft-templating synthesis method reported in this work are useful in the course of the development of nanomaterials with optimized properties for future CO capture technologies.

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