Pore space partition: Via secondary metal ions entrapped by pyrimidine hooks: Influences on structural flexibility and carbon dioxide capture

Zhiyong Lu; Jianfeng Zhang; Jingui Duan; Liting Du; Cheng Hang

doi:10.1039/c7ta02852k

Pore space partition: Via secondary metal ions entrapped by pyrimidine hooks: Influences on structural flexibility and carbon dioxide capture

Zhiyong Lu, Jianfeng Zhang, Jingui Duan, Liting Du, Cheng Hang

College of Chemical Engineering

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27 Scopus citations

Abstract

A new way of pore space partition via secondary metal ions entrapped by pyrimidine hooks is implemented on flexible metal-organic frameworks. The new resulting (3, 4, 6)-connected MOF, HHU-2 (HHU for Hohai University), whose pore space was partitioned by additional metal ions and flexibility was confined under specific pressure and temperature, exhibits promising CO₂ uptake capacity (17.5 wt% at 1 bar and 298 K), strong CO₂ adsorption enthalpy (30.0 kJ mmol^-1), and high CO₂ selectivity towards N₂ (47.3 at 298 K). Importantly, this is the first example of simultaneously achieving high CO₂ selectivity as well as high CO₂ uptake capacity in MOFs by flexibility confinement through the introduction of secondary metal sites.

Original language	English
Pages (from-to)	17287-17292
Number of pages	6
Journal	Journal of Materials Chemistry A
Volume	5
Issue number	33
DOIs	https://doi.org/10.1039/c7ta02852k
State	Published - 2017

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abstract = "A new way of pore space partition via secondary metal ions entrapped by pyrimidine hooks is implemented on flexible metal-organic frameworks. The new resulting (3, 4, 6)-connected MOF, HHU-2 (HHU for Hohai University), whose pore space was partitioned by additional metal ions and flexibility was confined under specific pressure and temperature, exhibits promising CO2 uptake capacity (17.5 wt% at 1 bar and 298 K), strong CO2 adsorption enthalpy (30.0 kJ mmol-1), and high CO2 selectivity towards N2 (47.3 at 298 K). Importantly, this is the first example of simultaneously achieving high CO2 selectivity as well as high CO2 uptake capacity in MOFs by flexibility confinement through the introduction of secondary metal sites.",

author = "Zhiyong Lu and Jianfeng Zhang and Jingui Duan and Liting Du and Cheng Hang",

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T1 - Pore space partition

T2 - Via secondary metal ions entrapped by pyrimidine hooks: Influences on structural flexibility and carbon dioxide capture

AU - Lu, Zhiyong

AU - Zhang, Jianfeng

AU - Duan, Jingui

AU - Du, Liting

AU - Hang, Cheng

PY - 2017

Y1 - 2017

N2 - A new way of pore space partition via secondary metal ions entrapped by pyrimidine hooks is implemented on flexible metal-organic frameworks. The new resulting (3, 4, 6)-connected MOF, HHU-2 (HHU for Hohai University), whose pore space was partitioned by additional metal ions and flexibility was confined under specific pressure and temperature, exhibits promising CO2 uptake capacity (17.5 wt% at 1 bar and 298 K), strong CO2 adsorption enthalpy (30.0 kJ mmol-1), and high CO2 selectivity towards N2 (47.3 at 298 K). Importantly, this is the first example of simultaneously achieving high CO2 selectivity as well as high CO2 uptake capacity in MOFs by flexibility confinement through the introduction of secondary metal sites.

AB - A new way of pore space partition via secondary metal ions entrapped by pyrimidine hooks is implemented on flexible metal-organic frameworks. The new resulting (3, 4, 6)-connected MOF, HHU-2 (HHU for Hohai University), whose pore space was partitioned by additional metal ions and flexibility was confined under specific pressure and temperature, exhibits promising CO2 uptake capacity (17.5 wt% at 1 bar and 298 K), strong CO2 adsorption enthalpy (30.0 kJ mmol-1), and high CO2 selectivity towards N2 (47.3 at 298 K). Importantly, this is the first example of simultaneously achieving high CO2 selectivity as well as high CO2 uptake capacity in MOFs by flexibility confinement through the introduction of secondary metal sites.

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M3 - 文章

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SN - 2050-7488

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SP - 17287

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JO - Journal of Materials Chemistry A

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IS - 33

ER -

Pore space partition: Via secondary metal ions entrapped by pyrimidine hooks: Influences on structural flexibility and carbon dioxide capture

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