Hydrogen Isotope Separation in Confined Nanospaces: Carbons, Zeolites, Metal–Organic Frameworks, and Covalent Organic Frameworks

• Published in: Advanced materials (Weinheim) Vol. 31; no. 20; pp. e1805293 - n/a
• Main Authors: Kim, Jin Yeong, Oh, Hyunchul, Moon, Hoi Ri
• Format: Journal Article
• Language: English
• Published: Germany Wiley Subscription Services, Inc 01.05.2019
• Subjects: chemical affinity quantum sieving; Chemical properties; Deuterium; Hydrogen isotopes; Isotope separation; Isotopes; kinetic quantum sieving; Materials science; Metal-organic frameworks; Organic chemistry; Porous materials; Purity; Tritium; Zeolites; hydrogen isotopes; chemical affinity quantum sieving; porous materials; isotope separation; kinetic quantum sieving
• ISSN: 0935-9648; 1521-4095
• DOI: 10.1002/adma.201805293

One of the greatest challenges of modern separation technology is separating isotope mixtures in high purity. The separation of hydrogen isotopes can create immense economic value by producing valuable deuterium (D) and tritium (T), which are irreplaceable for various industrial and scientific applications. However, current separation methods suffer from low separation efficiency owing to the similar chemical properties of isotopes; thus, high‐purity isotopes are not easily achieved. Recently, nanoporous materials have been proposed as promising candidates and are supported by a newly proposed separation mechanism, i.e., quantum effects. Herein, the fundamentals of the quantum sieving effect of hydrogen isotopes in nanoporous materials are discussed, which are mainly kinetic quantum sieving and chemical‐affinity quantum sieving, including the recent advances in the analytical techniques. As examples of nanoporous materials, carbons, zeolites, metal–organic frameworks, and covalent organic frameworks are addressed from computational and experimental standpoints. Understanding the quantum sieving effect in nanospaces and the tailoring of porous materials based on it will open up new opportunities to develop a highly efficient and advanced isotope separation systems. The separation of a physicochemically almost identical isotopic mixture is the grandest challenge in modern separation technology. Recent advances of hydrogen‐isotope separation in a confined nanospace based on separation mechanisms of quantum effects, as well as computational and experimental studies on carbons, zeolites, metal–organic frameworks, and covalent organic frameworks, are discussed. Future perspectives are also suggested for realistic isotope separation platforms.