Crystal Engineering of Hybrid Coordination Networks: From Form to Function

Soumya Mukherjee; Michael J. Zaworotko

doi:10.1016/j.trechm.2020.02.013

Crystal Engineering of Hybrid Coordination Networks: From Form to Function

Research output: Contribution to journal › Review article › peer-review

Abstract

Crystal engineering, the field of chemistry that studies the design, properties, and applications of crystals, is exemplified by the emergence of coordination networks (CNs). CNs are comprised of metal cations or metal clusters linked into 2D or 3D networks by organic and/or inorganic ligands. Early studies on CNs tended to focus upon design using self-assembly and/or reticular chemistry, but interest in CNs has grown exponentially as a consequence of their potential utility in catalysis, purification, sensing, and gas storage. Whereas the use of organic ‘linker ligands’ has afforded >75 000 metal-organic frameworks (MOFs), hybrid CNs (HCNs) sustained by both inorganic and organic linkers remain understudied. We herein review design approaches to HCNs and recent developments concerning their exceptional gas-separation performance.

Original language	English
Pages (from-to)	506-518
Number of pages	13
Journal	Trends in Chemistry
Volume	2
Issue number	6
DOIs	https://doi.org/10.1016/j.trechm.2020.02.013
Publication status	Published - Jun 2020

Keywords

crystal engineering
gas separation
hybrid coordination network
physisorbent
ultramicroporous

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10.1016/j.trechm.2020.02.013

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title = "Crystal Engineering of Hybrid Coordination Networks: From Form to Function",

abstract = "Crystal engineering, the field of chemistry that studies the design, properties, and applications of crystals, is exemplified by the emergence of coordination networks (CNs). CNs are comprised of metal cations or metal clusters linked into 2D or 3D networks by organic and/or inorganic ligands. Early studies on CNs tended to focus upon design using self-assembly and/or reticular chemistry, but interest in CNs has grown exponentially as a consequence of their potential utility in catalysis, purification, sensing, and gas storage. Whereas the use of organic {\textquoteleft}linker ligands{\textquoteright} has afforded >75 000 metal-organic frameworks (MOFs), hybrid CNs (HCNs) sustained by both inorganic and organic linkers remain understudied. We herein review design approaches to HCNs and recent developments concerning their exceptional gas-separation performance.",

keywords = "crystal engineering, gas separation, hybrid coordination network, physisorbent, ultramicroporous",

author = "Soumya Mukherjee and Zaworotko, \{Michael J.\}",

note = "Publisher Copyright: {\textcopyright} 2020",

year = "2020",

month = jun,

doi = "10.1016/j.trechm.2020.02.013",

language = "English",

volume = "2",

pages = "506--518",

journal = "Trends in Chemistry",

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T1 - Crystal Engineering of Hybrid Coordination Networks

T2 - From Form to Function

AU - Mukherjee, Soumya

AU - Zaworotko, Michael J.

PY - 2020/6

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N2 - Crystal engineering, the field of chemistry that studies the design, properties, and applications of crystals, is exemplified by the emergence of coordination networks (CNs). CNs are comprised of metal cations or metal clusters linked into 2D or 3D networks by organic and/or inorganic ligands. Early studies on CNs tended to focus upon design using self-assembly and/or reticular chemistry, but interest in CNs has grown exponentially as a consequence of their potential utility in catalysis, purification, sensing, and gas storage. Whereas the use of organic ‘linker ligands’ has afforded >75 000 metal-organic frameworks (MOFs), hybrid CNs (HCNs) sustained by both inorganic and organic linkers remain understudied. We herein review design approaches to HCNs and recent developments concerning their exceptional gas-separation performance.

AB - Crystal engineering, the field of chemistry that studies the design, properties, and applications of crystals, is exemplified by the emergence of coordination networks (CNs). CNs are comprised of metal cations or metal clusters linked into 2D or 3D networks by organic and/or inorganic ligands. Early studies on CNs tended to focus upon design using self-assembly and/or reticular chemistry, but interest in CNs has grown exponentially as a consequence of their potential utility in catalysis, purification, sensing, and gas storage. Whereas the use of organic ‘linker ligands’ has afforded >75 000 metal-organic frameworks (MOFs), hybrid CNs (HCNs) sustained by both inorganic and organic linkers remain understudied. We herein review design approaches to HCNs and recent developments concerning their exceptional gas-separation performance.

KW - crystal engineering

KW - gas separation

KW - hybrid coordination network

KW - physisorbent

KW - ultramicroporous

UR - https://www.scopus.com/pages/publications/85083326885

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DO - 10.1016/j.trechm.2020.02.013

M3 - Review article

AN - SCOPUS:85083326885

SN - 2589-5974

VL - 2

SP - 506

EP - 518

JO - Trends in Chemistry

JF - Trends in Chemistry

IS - 6

ER -

Crystal Engineering of Hybrid Coordination Networks: From Form to Function

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