Molecular simulation of Mn(II)-substituted aluminophosphate MnAPO-14

Ji Yang Li; Ji Hong Yu; Ru Ren Xu

Molecular simulation of Mn(II)-substituted aluminophosphate MnAPO-14

Ji Yang Li^*, Ji Hong Yu, Ru Ren Xu

^*Corresponding author for this work

Juin University

Research output: Contribution to journal › Article › peer-review

Abstract

The structure of manganese(II)-substituted aluminophosphate MnAPO-14 with AFN zeotype has been investigated by computational simulation in Cerius ² package. Starting from reported structure of MnAPO-14, total 28 theoretical models of Mn-substituted AFN have been built and optimized to obtain their stable conformation. In terms of the host-guest non-bonding interaction and the framework energies, the Mn(II)-substituted sites and the bonded sites of two H₂O molecules can be well predicted for MnAPO-14. The simulated structure is in good a-greement with that of experimental MnAPO-14. Calculation results suggest that the replacement site of Al by Mn(II) atom in AFN is dramatically effected by the guest molecules of organic templating resided in the channels, which is corresponding to the host-guest charge-density matching principle. This work will be helpful for the better understanding the structures of metal-substituted microporous materials.

Original language	English
Pages (from-to)	889-892
Number of pages	4
Journal	Chinese Journal of Inorganic Chemistry
Volume	21
Issue number	6
Publication status	Published - 1 Jun 2005
Externally published	Yes

Keywords

AFN
Computational simulation
Host-guest interaction
Manganese(II)-substitution

Cite this

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title = "Molecular simulation of Mn(II)-substituted aluminophosphate MnAPO-14",

abstract = "The structure of manganese(II)-substituted aluminophosphate MnAPO-14 with AFN zeotype has been investigated by computational simulation in Cerius 2 package. Starting from reported structure of MnAPO-14, total 28 theoretical models of Mn-substituted AFN have been built and optimized to obtain their stable conformation. In terms of the host-guest non-bonding interaction and the framework energies, the Mn(II)-substituted sites and the bonded sites of two H2O molecules can be well predicted for MnAPO-14. The simulated structure is in good a-greement with that of experimental MnAPO-14. Calculation results suggest that the replacement site of Al by Mn(II) atom in AFN is dramatically effected by the guest molecules of organic templating resided in the channels, which is corresponding to the host-guest charge-density matching principle. This work will be helpful for the better understanding the structures of metal-substituted microporous materials.",

keywords = "AFN, Computational simulation, Host-guest interaction, Manganese(II)-substitution",

author = "Li, {Ji Yang} and Yu, {Ji Hong} and Xu, {Ru Ren}",

year = "2005",

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day = "1",

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journal = "Chinese Journal of Inorganic Chemistry",

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TY - JOUR

T1 - Molecular simulation of Mn(II)-substituted aluminophosphate MnAPO-14

AU - Li, Ji Yang

AU - Yu, Ji Hong

AU - Xu, Ru Ren

PY - 2005/6/1

Y1 - 2005/6/1

N2 - The structure of manganese(II)-substituted aluminophosphate MnAPO-14 with AFN zeotype has been investigated by computational simulation in Cerius 2 package. Starting from reported structure of MnAPO-14, total 28 theoretical models of Mn-substituted AFN have been built and optimized to obtain their stable conformation. In terms of the host-guest non-bonding interaction and the framework energies, the Mn(II)-substituted sites and the bonded sites of two H2O molecules can be well predicted for MnAPO-14. The simulated structure is in good a-greement with that of experimental MnAPO-14. Calculation results suggest that the replacement site of Al by Mn(II) atom in AFN is dramatically effected by the guest molecules of organic templating resided in the channels, which is corresponding to the host-guest charge-density matching principle. This work will be helpful for the better understanding the structures of metal-substituted microporous materials.

AB - The structure of manganese(II)-substituted aluminophosphate MnAPO-14 with AFN zeotype has been investigated by computational simulation in Cerius 2 package. Starting from reported structure of MnAPO-14, total 28 theoretical models of Mn-substituted AFN have been built and optimized to obtain their stable conformation. In terms of the host-guest non-bonding interaction and the framework energies, the Mn(II)-substituted sites and the bonded sites of two H2O molecules can be well predicted for MnAPO-14. The simulated structure is in good a-greement with that of experimental MnAPO-14. Calculation results suggest that the replacement site of Al by Mn(II) atom in AFN is dramatically effected by the guest molecules of organic templating resided in the channels, which is corresponding to the host-guest charge-density matching principle. This work will be helpful for the better understanding the structures of metal-substituted microporous materials.

KW - AFN

KW - Computational simulation

KW - Host-guest interaction

KW - Manganese(II)-substitution

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M3 - Article

AN - SCOPUS:20444471180

SN - 1001-4861

VL - 21

SP - 889

EP - 892

JO - Chinese Journal of Inorganic Chemistry

JF - Chinese Journal of Inorganic Chemistry

IS - 6

ER -

Molecular simulation of Mn(II)-substituted aluminophosphate MnAPO-14

Abstract

Keywords

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