Home / Publications / Coordination polymers derived from magnesium and barium complexes of redox-active ligands

Coordination polymers derived from magnesium and barium complexes of redox-active ligands

Natalia L'vovna Bazyakina 1
Natalia L'vovna Bazyakina
Valentin Mikhailovich Makarov 1
Valentin Mikhailovich Makarov
Mikhail Vladimirovich Moskalev 1
Mikhail Vladimirovich Moskalev
Eugeny Vladimirovich Baranov 1
Eugeny Vladimirovich Baranov
Artem Stepanovich Bogomyakov 2
Artem Stepanovich Bogomyakov
Victor Ivanovich Ovcharenko 2
Victor Ivanovich Ovcharenko
Igor Leonidovich Fedushkin 1
Igor Leonidovich Fedushkin
10.1016/j.mencom.2022.11.017
Published 2022-10-21
CommunicationVolume 32, Issue 6, 759-762
5
Share
Cite this
GOST
 | 
Cite this
GOST Copy
Bazyakina N. L. et al. Coordination polymers derived from magnesium and barium complexes of redox-active ligands // Mendeleev Communications. 2022. Vol. 32. No. 6. pp. 759-762.
GOST all authors (up to 50) Copy
Bazyakina N. L., Makarov V. M., Moskalev M. V., Baranov E. V., Bogomyakov A. S., Ovcharenko V. I., Fedushkin I. L. Coordination polymers derived from magnesium and barium complexes of redox-active ligands // Mendeleev Communications. 2022. Vol. 32. No. 6. pp. 759-762.
RIS
 | 
Cite this
RIS Copy
TY - JOUR
DO - 10.1016/j.mencom.2022.11.017
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.11.017
TI - Coordination polymers derived from magnesium and barium complexes of redox-active ligands
T2 - Mendeleev Communications
AU - Bazyakina, Natalia L'vovna
AU - Makarov, Valentin Mikhailovich
AU - Moskalev, Mikhail Vladimirovich
AU - Baranov, Eugeny Vladimirovich
AU - Bogomyakov, Artem Stepanovich
AU - Ovcharenko, Victor Ivanovich
AU - Fedushkin, Igor Leonidovich
PY - 2022
DA - 2022/10/21
PB - Mendeleev Communications
SP - 759-762
IS - 6
VL - 32
ER -
BibTex
 | 
Cite this
BibTex (up to 50 authors) Copy
@article{2022_Bazyakina,
author = {Natalia L'vovna Bazyakina and Valentin Mikhailovich Makarov and Mikhail Vladimirovich Moskalev and Eugeny Vladimirovich Baranov and Artem Stepanovich Bogomyakov and Victor Ivanovich Ovcharenko and Igor Leonidovich Fedushkin},
title = {Coordination polymers derived from magnesium and barium complexes of redox-active ligands},
journal = {Mendeleev Communications},
year = {2022},
volume = {32},
publisher = {Mendeleev Communications},
month = {Oct},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.11.017},
number = {6},
pages = {759--762},
doi = {10.1016/j.mencom.2022.11.017}
}
MLA
Cite this
MLA Copy
Bazyakina, Natalia L'vovna, et al. “Coordination polymers derived from magnesium and barium complexes of redox-active ligands.” Mendeleev Communications, vol. 32, no. 6, Oct. 2022, pp. 759-762. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2022.11.017.

Keywords

barium complexes
magnesium complexes
metal–organic coordination polymers
redox-active ligands
X-ray diffraction

Abstract

The reactions of monomeric complexes [(dpp-bian)M(THF)n](M = Mg, n = 3; M = Ba, n = 5; dpp-bian = 1,2-bis[(2,6-di-isopropylphenyl)imino]acenaphthene) with 4,4'-bipyridine (4,4'-bipy) in THF proceed with electron transfer from dpp- bian2– to 4,4'-bipy0 to afford 1D coordination polymers [(dpp-bian)M(4,4'-bipy)(THF)n]m (M = Mg, n = 1; M = Ba, n = 2) that contain simultaneously radical anion ligands dpp-bian– and 4,4'-bipy . Addition of DME to coordination polymer [(dpp-bian)Mg(4,4'-bipy)(THF)n]m results in fragmentation of polymeric chains to give dinuclear magnesium species [{(dpp-bian)Mg(DME)}2(4,4'-bipy)]. Barium analogue [{(dpp-bian)Ba(DME)2}2(4,4'-bipy)] has been prepared by reacting of complex [(dpp-bian)Ba(DME)2.5] with 4,4'-bipy in DME.

References

1.
10.1016/j.mencom.2022.11.017_b0005
The Chemistry of Metal-Organic Frameworks
Synthesis, Characterization, and Applications, ed, 2016
2.
The Chemistry and Applications of Metal-Organic Frameworks
Furukawa H., Cordova K.E., O’Keeffe M., Yaghi O.M.
Science, 2013
3.
Industrial applications of metal–organic frameworks
Czaja A.U., Trukhan N., Müller U.
Chemical Society Reviews, 2009
4.
Metal-organic framework structures: Adsorbents for natural gas storage
Tsivadze A.Y., Aksyutin O.E., Ishkov A.G., Knyazeva M.K., Solovtsova O.V., Men’shchikov I.E., Fomkin A.A., Shkolin A.V., Khozina E.V., Grachev V.A.
Russian Chemical Reviews, 2019
5.
Multifunctional Metal–Organic Frameworks Based on Redox-Active Rhenium Octahedral Clusters
Litvinova Y.M., Gayfulin Y.M., Kovalenko K.A., Samsonenko D.G., van Leusen J., Korolkov I.V., Fedin V.P., Mironov Y.V.
Inorganic Chemistry, 2018
6.
10.1016/j.mencom.2022.11.017_b0030
Bláha
J. Phys. Chem., 2020
7.
Functional coordination polymers based on redox-active tetrathiafulvalene and its derivatives
Wang H., Cui L., Xie J., Leong C.F., D’Alessandro D.M., Zuo J.
Coordination Chemistry Reviews, 2017
8.
Iodine Adsorption in a Redox-Active Metal–Organic Framework: Electrical Conductivity Induced by Host−Guest Charge-Transfer
Zhang X., da Silva I., Fazzi R., Sheveleva A.M., Han X., Spencer B.F., Sapchenko S.A., Tuna F., McInnes E.J., Li M., Yang S., Schröder M.
Inorganic Chemistry, 2019
9.
High Ammonia Adsorption in MFM-300 Materials: Dynamics and Charge Transfer in Host–Guest Binding
Han X., Lu W., Chen Y., da Silva I., Li J., Lin L., Li W., Sheveleva A.M., Godfrey H.G., Lu Z., Tuna F., McInnes E.J., Cheng Y., Daemen L.L., MPherson L.J., et. al.
Journal of the American Chemical Society, 2021
10.
10.1016/j.mencom.2022.11.017_b0050
Cai
Comprehensive Nanoscience and Nanotechnology, 2019
11.
Switching in Metal–Organic Frameworks
Bigdeli F., Lollar C.T., Morsali A., Zhou H.
Angewandte Chemie - International Edition, 2019
12.
Redox-active metal–organic frameworks for energy conversion and storage
Calbo J., Golomb M.J., Walsh A.
Journal of Materials Chemistry A, 2019
13.
Rare‐Earth Metal Tetrathiafulvalene Carboxylate Frameworks as Redox‐Switchable Single‐Molecule Magnets
Su J., Yuan S., Li J., Wang H., Ge J., Drake H.F., Leong C.F., Yu F., D'Alessandro D.M., Kurmoo M., Zuo J., Zhou H.
Chemistry - A European Journal, 2020
14.
Unconventional Method for Fabricating Valence Tautomeric Materials: Integrating Redox Center within a Metal–Organic Framework
Li B., Zhao Y., Kirchon A., Pang J., Yang X., Zhuang G., Zhou H.
Journal of the American Chemical Society, 2019
15.
Rogovoy M.I., Tomilenko A.V., Samsonenko D.G., Nedolya N.A., Rakhmanova M.I., Artem’ev A.V.
Mendeleev Communications, 2020
17.
Metal–Organic Frameworks Derived from Calcium and Strontium Complexes of a Redox-Active Ligand
Bazyakina N.L., Makarov V.M., Ketkov S.Y., Bogomyakov A.S., Rumyantcev R.V., Ovcharenko V.I., Fedushkin I.L.
Inorganic Chemistry, 2021
18.
Main-group metal complexes of α-diimine ligands: structure, bonding and reactivity
Zhang R., Wang Y., Zhao Y., Redshaw C., Fedushkin I.L., Wu B., Yang X.
Dalton Transactions, 2021
19.
Reduction of Disulfides with Magnesium(II) and Gallium(II) Complexes of a Redox‐Active Diimine Ligand
Fedushkin I.L., Nikipelov A.S., Skatova A.A., Maslova O.V., Lukoyanov A.N., Fukin G.K., Cherkasov A.V.
European Journal of Inorganic Chemistry, 2009
21.
Monomeric Magnesium and Calcium Complexes Containing the Bidentate, Dianionic 1,2‐Bis[(2,6‐diisopropylphenyl)imino]acenaphthene Ligand
Fedushkin I., Skatova A., Chudakova V., Fukin G., Dechert S., Schumann H.
European Journal of Inorganic Chemistry, 2003
23.
Addition of Nitriles to Alkaline Earth Metal Complexes of 1,2-Bis[(phenyl)imino]acenaphthenes
Fedushkin I.L., Morozov A.G., Rassadin O.V., Fukin G.K.
Chemistry - A European Journal, 2005
27.
Coordination polymers derived from alkali metal complexes of redox-active ligands
Bazyakina N.L., Moskalev M.V., Cherkasov A.V., Makarov V.M., Fedushkin I.L.
CrystEngComm, 2022
28.
SAINT, Data Reduction and Correction Program, Version 8.38A, Bruker AXS, Madison, WI, 2017.
29.
Comparison of silver and molybdenum microfocus X-ray sources for single-crystal structure determination
Krause L., Herbst-Irmer R., Sheldrick G.M., Stalke D.
Journal of Applied Crystallography, 2015
30.
SHELXT– Integrated space-group and crystal-structure determination
Sheldrick G.M.
Acta Crystallographica Section A: Foundations and Advances, 2015
31.
Crystal structure refinement withSHELXL
Sheldrick G.M.
Acta crystallographica. Section C, Structural chemistry, 2015
32.
G. M. Sheldrick, SHELXTL, Version 6.14, Structure Determination Software Suite, Bruker AXS, Madison, WI, 2003.