Home / Publications / Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties

Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties

Dmitry Valentinovich Konarev 1
Dmitry Valentinovich Konarev
10.1016/j.mencom.2020.05.001
Published 2020-04-30
Focus articleVolume 30, Issue 3, 249-261
14
Share
Cite this
GOST
 | 
Cite this
GOST Copy
Konarev D. V. Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties // Mendeleev Communications. 2020. Vol. 30. No. 3. pp. 249-261.
GOST all authors (up to 50) Copy
Konarev D. V. Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties // Mendeleev Communications. 2020. Vol. 30. No. 3. pp. 249-261.
RIS
 | 
Cite this
RIS Copy
TY - JOUR
DO - 10.1016/j.mencom.2020.05.001
UR - https://mendcomm.colab.ws/publications/10.1016/j.mencom.2020.05.001
TI - Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties
T2 - Mendeleev Communications
AU - Konarev, Dmitry Valentinovich
PY - 2020
DA - 2020/04/30
PB - Mendeleev Communications
SP - 249-261
IS - 3
VL - 30
ER -
BibTex
 | 
Cite this
BibTex (up to 50 authors) Copy
@article{2020_Konarev,
author = {Dmitry Valentinovich Konarev},
title = {Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties},
journal = {Mendeleev Communications},
year = {2020},
volume = {30},
publisher = {Mendeleev Communications},
month = {Apr},
url = {https://mendcomm.colab.ws/publications/10.1016/j.mencom.2020.05.001},
number = {3},
pages = {249--261},
doi = {10.1016/j.mencom.2020.05.001}
}
MLA
Cite this
MLA Copy
Konarev, Dmitry Valentinovich. “Radical anion and coordination compounds of polyconjugated molecules:potential organic materials with unusual magnetic, conducting and optical properties.” Mendeleev Communications, vol. 30, no. 3, Apr. 2020, pp. 249-261. https://mendcomm.colab.ws/publications/10.1016/j.mencom.2020.05.001.
Views / Downloads
1 / 7

Keywords

Charge transfer
charge transfer complex
fullerene
low dimension organic conductor
magnetic ordering of spins
organic electronics
phthalocyanine
porphyrin
radical anion salt
π-conjugated material

Abstract

Radical anion salts and coordination complexes of fullerenes, macrocycles and organic dyes obtained by reduction are considered. The reduction transfers an electron to these molecules enabling their participation in magnetic coupling of spins and/or high conductivity as well as modifies essentially their optical properties. Different types of electron transfer between the components have also been observed for these compounds. This review presents new approaches to the syntheses of these salts and complexes as well as their structural and physiochemical properties. Prospects for the development of this area are discussed.

References

1.
Organic Solar Cells: A Review of Materials, Limitations, and Possibilities for Improvement
Abdulrazzaq O.A., Saini V., Bourdo S., Dervishi E., Biris A.S.
Particulate Science and Technology, 2013
2.
The role of chemical design in the performance of organic semiconductors
Bronstein H., Nielsen C.B., Schroeder B.C., McCulloch I.
Nature Reviews Chemistry, 2020
3.
Organic–Inorganic Hybrid Nanomaterials
Ananikov V.P.
Nanomaterials, 2019
5.
Polyconjugated Materials, ed. G. Zerbi, (European Materials Research Society Symposia Proceedings, vol. 30), Elsevier, Amsterdam, 1992.
6.
Donor?acceptor complexes and radical ionic salts based on fullerenes
Konarev D.V., Lyubovskaya R.N.
Russian Chemical Reviews, 1999
8.
Fullerene complexes with coordination assemblies of metalloporphyrins and metal phthalocyanines
Konarev D.V., Khasanov S.S., Lyubovskaya R.N.
Coordination Chemistry Reviews, 2014
9.
New approaches to the synthesis of transition-metal complexes of fullerenes C60 and C70
Konarev D.V., Lyubovskaya R.N.
Russian Chemical Reviews, 2016
10.
Synthesis, Structures, and Properties of Crystalline Salts with Radical Anions of Metal-Containing and Metal-Free Phthalocyanines
Konarev D.V., Kuzmin A.V., Faraonov M.A., Ishikawa M., Khasanov S.S., Nakano Y., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Chemistry - A European Journal, 2014
11.
cis-Conformation of indigo in the coordination complex (indigo-O,O)(Cp*CrIICl)
Konarev D.V., Khasanov S.S., Kuzmin A.V., Shestakov A.F., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Dalton Transactions, 2016
12.
Optical and magnetic properties of trans-indigo˙− radical anions. Magnetic coupling between trans-indigo˙− (S = 1/2) mediated by intermolecular hydrogen N–H⋯OC bonds
Konarev D.V., Zorina L.V., Batov M.S., Khasanov S.S., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
New Journal of Chemistry, 2019
13.
Salts of Anionic Metal Carbonyl Clusters with Cryptand[2.2.2](Na+ ), DB-18-crown-6(Na+ ), and Paramagnetic Cp*2 Cr+ Cations Obtained by Reduction
Konarev D.V., Kuzmin A.V., Galkin R.S., Khasanov S.S., Kurbanov R.F., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Zeitschrift fur Anorganische und Allgemeine Chemie, 2019
14.
Electrolytic Reduction of Organic Compounds.
Popp F.D., Schultz H.P.
Chemical Reviews, 1962
15.
Chemical Redox Agents for Organometallic Chemistry
Connelly N.G., Geiger W.E.
Chemical Reviews, 1996
16.
The solid-state structure of K3C60(THF)14
Janiak C., Mühle S., Hemling H., Köhler K.
Polyhedron, 1996
17.
ESR spectra on single crystals of alkali metal fulleride complexes by means of wet-chemical synthesis
Moriyama H., Kobayashi H., Kobayashi A., Watanabe T.
Chemical Physics Letters, 1995
18.
A new method for the preparation of fullerene anion salts: synthesis and characterization of KC60(THF)
Chen J., Huang Z., Cai R., Shao Q., Chen S., Ye H.
Journal of the Chemical Society Chemical Communications, 1994
21.
A Main Group Metal Sandwich: Five Lithium Cations Jammed Between Two Corannulene Tetraanion Decks
Zabula A.V., Filatov A.S., Spisak S.N., Rogachev A.Y., Petrukhina M.A.
Science, 2011
22.
Superconductivity at 18 K in potassium-doped C60
Hebard A.F., Rosseinsky M.J., Haddon R.C., Murphy D.W., Glarum S.H., Palstra T.T., Ramirez A.P., Kortan A.R.
Nature, 1991
23.
Conducting and superconducting properties of alkali-metal C60 fullerides
Tanigaki K., Prassides K.
Journal of Materials Chemistry A, 1995
24.
Superconductivity in alkali-metal-doped picene
Mitsuhashi R., Suzuki Y., Yamanari Y., Mitamura H., Kambe T., Ikeda N., Okamoto H., Fujiwara A., Yamaji M., Kawasaki N., Maniwa Y., Kubozono Y.
Nature, 2010
25.
Superconductivity above 30 K in alkali-metal-doped hydrocarbon
Xue M., Cao T., Wang D., Wu Y., Yang H., Dong X., He J., Li F., Chen G.F.
Scientific Reports, 2012
26.
Potassium Phthalocyanine, KPc:  One-Dimensional Molecular Stacks Bridged by K+ Ions
Margadonna S., Prassides K., Iwasa Y., Taguchi Y., Craciun M.F., Rogge S., Morpurgo A.F.
Inorganic Chemistry, 2006
27.
Synthesis, Structure, and Magnetic Properties of Li-Doped Manganese-Phthalocyanine, Lix[MnPc] (0 ⩽ x ⩽ 4)
Taguchi Y., Miyake T., Margadonna S., Kato K., Prassides K., Iwasa Y.
Journal of the American Chemical Society, 2006
28.
Electrochemical evaluation of electron acceptor materials
Loutfy R.O., Hsiao C.K., Ong B.S., Keoshkerian B.
Canadian Journal of Chemistry, 1984
29.
10.1016/j.mencom.2020.05.001_bib0070
Vanýsek
CRC Handbook of Chemistry and Physics, 2012
30.
Probing Solvation and Ion-Pairing Effects on the Redox Behavior of Cyclopentadienyl Cobalt Dicarbonyl, CpCo(CO)2, in the presence of [B(C6F5)4]- anion
Nafady A., Alsalme A.M., AL-Farhan K.A., El Khatib R.M., Bhargava S.
International Journal of Electrochemical Science, 2014
31.
Effect of One- and Two-Electron Reduction of Terbium(III) Double-Decker Phthalocyanine on Single-Ion Magnet Behavior and NIR Absorption
Konarev D.V., Khasanov S.S., Batov M.S., Martynov A.G., Nefedova I.V., Gorbunova Y.G., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Inorganic Chemistry, 2019
32.
Ionic fullerene complex (DMI+)3·(C60˙−)·(I−)2 with 2H-hexagonal fullerene packing and 3-D DMI+-I− network
Konarev D.V., Khasanov S.S., Otsuka A., Saito G., Lyubovskaya R.N.
CrystEngComm, 2009
33.
Structure and magnetic properties of the ionic fullerene salt (TMP+)·(C60˙−)·C6H5CN containing layers of monomeric C60˙− radical anions
Konarev D.V., Kuzmin A.V., Khasanov S.S., Ishikawa M., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
New Journal of Chemistry, 2013
34.
Ionic complexes simultaneously containing fullerene anions and coordination structures of metal phthalocyanines with I− and EtS− anions
Konarev D.V., Zorina L.V., Khasanov S.S., Khakimova E.U., Lyubovskaya R.N.
Russian Chemical Bulletin, 2011
38.
Experimental observation of C60 LUMO splitting in the C602− dianions due to the Jahn–Teller effect. Comparison with the C60˙− radical anions
Konarev D.V., Kuzmin A.V., Simonov S.V., Yudanova E.I., Khasanov S.S., Saito G., Lyubovskaya R.N.
Physical Chemistry Chemical Physics, 2013
39.
Crystalline salts of metal phthalocyanine radical anions [M(Pc˙3−)]˙− (M = CuII, PbII, VIVO, SnIVCl2) with cryptand(Na+) cations: structure, optical and magnetic properties
Konarev D.V., Faraonov M.A., Kuzmin A.V., Khasanov S.S., Nakano Y., Norko S.I., Batov M.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
New Journal of Chemistry, 2017
40.
Ionic compound containing iron phthalocyanine (FeIPc)− anions and (C70−)2 dimers. Optical and magnetic properties of (FeIPc)− in the solid state
Konarev D.V., Kuzmin A.V., Simonov S.V., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Dalton Transactions, 2012
41.
cis-Thioindigo (TI) – a new ligand with accessible radical anion and dianion states. Strong magnetic coupling in the {[TI-(μ2-O),(μ-O)]Cp*Cr}2dimers
Konarev D.V., Khasanov S.S., Shestakov A.F., Fatalov A.M., Batov M.S., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Dalton Transactions, 2017
43.
Tetrabutylammonium Salts of Aluminum(III) and Gallium(III) Phthalocyanine Radical Anions Bonded with Fluoren-9-olato−Anions and Indium(III) Phthalocyanine Bromide Radical Anions
Konarev D.V., Khasanov S.S., Ishikawa M., Nakano Y., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Chemistry - An Asian Journal, 2017
45.
Synthesis, Structure, and Properties of the Fullerene C60Salt of Crystal Violet, (CV+)(C60.−)⋅0.5 C6H4Cl2, which Contained Closely Packed Zigzagged C60.−Chains
Konarev D.V., Kuzmin A.V., Khasanov S.S., Ishikawa M., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Chemistry - An Asian Journal, 2016
48.
Solid State Structure, and Optical and Magnetic Properties, of Free Base Tetra(4-pyridyl)porphyrin {H2T(4-Py)P}•– Radical Anions
Konarev D.V., Kuzmin A.V., Khasanov S.S., Shestakov A.F., Yudanova E.I., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Journal of Organic Chemistry, 2018
49.
Distortion and electronic structure of ordered C60•− radical anions in the salt with {CoI(dppe)2CO}+ cations (dppe: 1,2-bis(diphenylphosphino)ethane)
Konarev D.V., Kuzmin A.V., Andronov M.G., Khasanov S.S., Batov M.S., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Inorganica Chimica Acta, 2018
50.
Syntheses and electronic structures of decamethylmetallocenes
Robbins J.L., Edelstein N., Spencer B., Smart J.C.
Journal of the American Chemical Society, 1982
51.
10.1016/j.mencom.2020.05.001_bib0130
Konarev
Dalton Trans., 2018
52.
10.1016/j.mencom.2020.05.001_bib0135
Meites
1977
53.
Mechanism of electrolytic reduction of carbon-halogen bond. II. A rho sigma study
Sease J.W., Burton F.G., Nickol S.L.
Journal of the American Chemical Society, 1968
54.
Discrete Fulleride Anions and Fullerenium Cations
Reed C.A., Bolskar R.D.
Chemical Reviews, 2000
55.
Polymeric fullerene chains in RbC60 and KC60
Stephens P.W., Bortel G., Faigel G., Tegze M., Jánossy A., Pekker S., Oszlanyi G., Forró L.
Nature, 1994
56.
Metallic conductivity and metal-insulator transition in (AC60)n(A=K, Rb, and Cs) linear polymer fullerides
Bommeli F., Degiorgi L., Wachter P., Legeza Ö., Jánossy A., Oszlanyi G., Chauvet O., Forro L.
Physical Review B, 1995
57.
Lattice structure of the fullerene ferromagnet TDAE–C60
Stephens P.W., Cox D., Lauher J.W., Mihaly L., Wiley J.B., Allemand P., Hirsch A., Holczer K., Li Q., Thompson J.D., Wudl F.
Nature, 1992
58.
Ionic fullerene compounds containing negatively charged dimers and coordinatively bound anions
Konarev D.V., Khasanov S.S., Lyubovskaya R.N.
Russian Chemical Bulletin, 2007
59.
Polymer and Dimer Phases in Doped Fullerenes
Prassides K.
Physics and Chemistry of Materials with Low-Dimensional Structures, 2000
61.
Formation of Single-Bonded (C60-)2 and (C70-)2 Dimers in Crystalline Ionic Complexes of Fullerenes
Konarev D.V., Khasanov S.S., Saito G., Otsuka A., Yoshida Y., Lyubovskaya R.N.
Journal of the American Chemical Society, 2003
62.
Dimerization of C60˙– in multi-component ionic complexes with bis(ethylenedithio)tetrathiafulvalene: (cation+)2·ET·(C60˙–)2
Konarev D.V., Khasanov S.S., Saito G., Otsuka A., Lyubovskaya R.N.
Journal of Materials Chemistry A, 2007
65.
Effect of the Cooling Rate on Dimerization of C60•– in Fullerene Salt (DMI+)2·(C60•–)·{Cd(Et2NCS2)2I–}
Konarev D.V., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Inorganic Chemistry, 2012
66.
The formation of a single-bonded (C70−)2dimer in a new ionic multicomponent complex of cyclotriveratrylene: (Cs+)2(C70−)2·CTV·(DMF)7(C6H6)0.75
Konarev D.V., Khasanov S.S., Vorontsov I.I., Saito G., Antipin M.Y., Otsuka A., Lyubovskaya R.N.
Chemical Communications, 2002
67.
A crystalline anionic complex of scandium nitride endometallofullerene: experimental observation of single-bonded (Sc3N@Ih-C80–)2 dimers
Konarev D.V., Zorina L.V., Khasanov S.S., Popov A.A., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Chemical Communications, 2016
69.
Negatively charged singly-bonded dimers of C1-[C70(CF3)10] and bare C70 fullerene
Konarev D.V., Khasanov S.S., Goryunkov A.A., Troyanov S.I., Brotsman V.A., Ioffe I.N., Lyubovskaya R.N.
New Journal of Chemistry, 2019
70.
Magnetic Coupling and Optical Properties of theS6-Dodecakis(trifluoromethyl)fullerene Radical Anions in the Layered Salt (PPN+)[C60(CF3)12.−]
Konarev D.V., Romanova N.A., Panin R.A., Goryunkov A.A., Troyanov S.I., Lyubovskaya R.N.
Chemistry - A European Journal, 2014
71.
The Interaction of C60, C70, and C60(CN)2 radical anions with cobalt(II) tetraphenylporphyrin in solid multicomponent complexes.
Konarev D.V., Khasanov S.S., Saito G., Lyubovskaya R.N., Yoshida Y., Otsuka A.
Chemistry - A European Journal, 2003
75.
Structure, Optical, and Magnetic Properties of (PPN+)2(C702−)⋅2 C6H4Cl2, which Contains Dianionic Polymeric (C702−)nChains
Konarev D.V., Troyanov S.I., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Chemistry - An Asian Journal, 2013
76.
Negatively charged pi-(C60-)2 dimer with biradical state at room temperature.
Konarev D.V., Khasanov S.S., Otsuka A., Saito G., Lyubovskaya R.N.
Journal of the American Chemical Society, 2006
77.
Magnetic properties and stability of negatively charged doubly bonded C1202− dimers
Konarev D.V., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
New Journal of Chemistry, 2011
78.
Tightly Bound Double-Caged [60]Fullerene Derivatives with Enhanced Solubility: Structural Features and Application in Solar Cells
Brotsman V.A., Ioutsi V.A., Rybalchenko A.V., Markov V.Y., Belov N.M., Lukonina N.S., Troyanov S.I., Ioffe I.N., Trukhanov V.A., Galimova G.K., Mannanov A.A., Zubov D.N., Kemnitz E., Sidorov L.N., Magdesieva T.V., et. al.
Chemistry - An Asian Journal, 2017
79.
Synthesis and X-ray structure of dumb-bell-shaped C120
Wang G., Komatsu K., Murata Y., Shiro M.
Nature, 1997
80.
Electronic Communication betweenS=1/2 Spins in Negatively‐charged Double‐caged Fullerene C60Derivative Bonded by Two Single Bonds and Pyrrolizidine Bridge
Konarev D.V., Kuzmin A.V., Khasanov S.S., Goryunkov A.A., Brotsman V.A., Ioffe I.N., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Chemistry - An Asian Journal, 2019
81.
Metallic conductivity versus charge disproportionation in C60 complexes with noninteger average charges on fullerene
Konarev D.V., Khasanov S.S., Ishikawa M., Yudanova E.I., Shevchun A.F., Mikhailov M.S., Stuzhin P.A., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
ChemistrySelect, 2016
82.
A Two-Dimensional Organic Metal Based on Fullerene
Konarev D., Khasanov S., Otsuka A., Maesato M., Saito G., Lyubovskaya R.
Angewandte Chemie - International Edition, 2010
83.
Fullerene and endometallofullerene Kagome lattices with symmetry-forced spin frustration
Konarev D.V., Khasanov S.S., Shimizu Y., Kuzmin A.V., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Physical Chemistry Chemical Physics, 2019
84.
Spin liquid state in an organic Mott insulator with a triangular lattice.
Shimizu Y., Miyagawa K., Kanoda K., Maesato M., Saito G.
Physical Review Letters, 2003
85.
Gapless Quantum Spin Liquid in an Organic Spin-1/2 Triangular-Latticeκ−H3(Cat-EDT-TTF)2
Isono T., Kamo H., Ueda A., Takahashi K., Kimata M., Tajima H., Tsuchiya S., Terashima T., Uji S., Mori H.
Physical Review Letters, 2014
87.
10.1016/j.mencom.2020.05.001_sbref0260a
Itou
J. Phys.: Condens. Matter, 2007
88.
Quantum spin liquid: design of a quantum spin liquid next to a superconducting state based on a dimer-type ET Mott insulator
Hiramatsu T., Yoshida Y., Saito G., Otsuka A., Yamochi H., Maesato M., Shimizu Y., Ito H., Kishida H.
Journal of Materials Chemistry C, 2015
89.
10.1016/j.mencom.2020.05.001_bib0265
Konarev
Chem – Eur. J., 2014
90.
Design of Spin-Frustrated Monomer-Type C60•− Mott Insulator
Otsuka A., Konarev D., Lyubovskaya R., Khasanov S., Maesato M., Yoshida Y., Saito G.
Crystals, 2018
92.
Metal complexes of buckminsterfullerene (C60)
Fagan P.J., Calabrese J.C., Malone B.
Accounts of Chemical Research, 1992
95.
Coordination Complexes of Fullerene C60 with Rhodium {Cp*RhII(μ-Cl)}2(η2,η2-C60) and (Bu4N+){Cp*RhICl(η2-C60)}−. Temperature-Induced Charge Transfer from RhI to η2-C60
Konarev D.V., Kuzmin A.V., Khasanov S.S., Troyanov S.I., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Organometallics, 2017
96.
Coordination Complexes of Pentamethylcyclopentadienyl Iridium(III) Diiodide with Tin(II) Phthalocyanine and Pentamethylcyclopentadienyl Iridium(II) Halide with Fullerene C60– Anions
Konarev D.V., Troyanov S.I., Kuzmin A.V., Nakano Y., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Organometallics, 2015
97.
Anionic coordination complexes of C60 and C70 with cyclopentadienyl and pentamethylcyclopentadienyl molybdenum dicarbonyl
Konarev D.V., Kuzmin A.V., Troyanov S.I., Nakano Y., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Dalton Transactions, 2015
99.
Two Metal Centers Bridging Two C60 Cages as a Wide Passage for Efficient Interfullerene Electronic Interaction
Lee G., Cho Y., Park B.K., Lee K., Park J.T.
Journal of the American Chemical Society, 2003
100.
The First Fullerene−Metal Sandwich Complex:  An Unusually Strong Electronic Communication between Two C60 Cages
Lee K., Song H., Kim B., Park J.T., Park S., Choi M.
Journal of the American Chemical Society, 2002
102.
Magnetic Coupling in the Fullerene Dimer {Co(Ph3P)(C6H5CN)}2(μ2-η2:η2-C60)2 with Two Zerovalent Cobalt Atoms as Bridges
Konarev D.V., Troyanov S.I., Nakano Y., Ustimenko K.A., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Organometallics, 2013
103.
Formation of {Co(dppe)}2{μ2-η2:η2-η2:η2-[(C60)2]} Dimers Bonded by Single C–C Bonds and Bridging η2-Coordinated Cobalt Atoms
Konarev D.V., Troyanov S.I., Ustimenko K.A., Nakano Y., Shestakov A.F., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Inorganic Chemistry, 2015
104.
Spin Crossover in Anionic Cobalt-Bridged Fullerene (Bu4N+){Co(Ph3P)}2(μ2-Cl–)(μ2-η2,η2-C60)2 Dimers
Konarev D.V., Khasanov S.S., Shestakov A.F., Ishikawa M., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Journal of the American Chemical Society, 2016
105.
The η 2 Complex of Nickel Bis(diphenylphosphanyl)propane with Fullerene: {Ni(dppp)(η 2 ‐C 60 )}·(Solvent) Obtained by Reduction
Konarev D.V., Khasanov S.S., Yudanova E.I., Lyubovskaya R.N.
European Journal of Inorganic Chemistry, 2011
109.
Molecular structure and spectroscopic properties of a nickel-bridged {Ni(Ph3P)}2(μ2–η2, η2-C60)2 dimer
Konarev D.V., Troyanov S.I., Nakano Y., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Dalton Transactions, 2014
110.
Linear Coordination Fullerene C60 Polymer [{Ni(Me3P)2}(μ-η2,η2-C60)]∞ Bridged by Zerovalent Nickel Atoms
Konarev D.V., Khasanov S.S., Nakano Y., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Inorganic Chemistry, 2014
111.
Phthalocyanines and Phthalocyanine Analogues: The Quest for Applicable Optical Properties
Claessens C.G., Blau W.J., Cook M., Hanack M., Nolte R.J., Torres T., Wöhrle D.
Monatshefte fur Chemie, 2001
112.
Self-Organized Porphyrinic Materials
Drain C.M., Varotto A., Radivojevic I.
Chemical Reviews, 2009
113.
Safonova E.A., Meshkov I.N., Polovkova M.A., Volostnykh M.V., Tsivadze A.Y., Gorbunova Y.G.
Mendeleev Communications, 2018
114.
Platonova Y.B., Morozov A.S., Burtsev I.D., Korostei Y.S., Ionidi V.Y., Romanovsky B.V., Tomilova L.G.
Mendeleev Communications, 2018
116.
PhthalocyaninesVersatile Components of Molecular Conductors
Inabe T., Tajima H.
Chemical Reviews, 2004
117.
Cooperative magnetic behavior of ?- and ?-manganese(III) phthalocyanine tetracyanoethenide (1:1), [MnIIIPc]�?[TCNE]�?
Miller J.S., Vazquez C., Calabrese J.C., McLean R.S., Epstein A.J.
Advanced Materials, 1994
118.
Manganese(ii) octabutoxynaphthalocyanine and its ferrimagnetic electron-transfer salt with TCNE
Rittenberg D.K., Baars-Hibbe L., Böhm A., Miller J.S.
Journal of Materials Chemistry A, 2000
119.
Strong Correlations in Electron Doped Phthalocyanine Conductors Near Half Filling
Tosatti E., Fabrizio M., Tóbik J., Santoro G.E.
Physical Review Letters, 2004
121.
10.1016/j.mencom.2020.05.001_bib0365
Kadish
The Porphyrin Handbook. Volume 9. Database of Redox Potentials and Binding Constants, 2000
124.
Systematic investigation of phthalocyanines, naphthalocyanines, and their aza-analogues. Effect of the isosteric aza-replacement in the core
Novakova V., Reimerova P., Svec J., Suchan D., Miletin M., Rhoda H.M., Nemykin V.N., Zimcik P.
Dalton Transactions, 2015
125.
10.1016/j.mencom.2020.05.001_sbref0380
1989
126.
Magnetic and Optical Properties of Layered (Me4P+)[MIVO(Pc•3–)]•–(TPC)0.5·C6H4Cl2 Salts (M = Ti and V) Composed of π-Stacking Dimers of Titanyl and Vanadyl Phthalocyanine Radical Anions
Konarev D.V., Nakano Y., Khasanov S.S., Kuzmin A.V., Ishikawa M., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Crystal Growth and Design, 2017
127.
Salts with titanyl and vanadyl phthalocyanine radical anions. Molecular design and effect of cations on the structure and magnetic and optical properties
Konarev D.V., Kuzmin A.V., Khasanov S.S., Batov M.S., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
CrystEngComm, 2018
128.
Radical anion and dianion salts of titanyl macrocycles with acceptor substituents or an extended π-system
Faraonov M.A., Konarev D.V., Fatalov A.M., Khasanov S.S., Troyanov S.I., Lyubovskaya R.N.
Dalton Transactions, 2017
129.
Molecular structure, optical and magnetic properties of the {SnIVPc(3-)Cl2}•- radical anions containing negatively charged Pc ligands
Konarev D.V., Troyanov S.I., Faraonov M.A., Ishikawa M., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Journal of Porphyrins and Phthalocyanines, 2015
130.
Layered Salts with Iron Hexadecachlorophthalocyanine Anions – The Formation of [{FeCl 16 Pc} 2 ] 3– Dimers Containing [Fe I Cl 16 Pc(2–)] – and Diamagnetic [Fe 0 Cl 16 Pc(2–)] 2–
Konarev D.V., Kuzmin A.V., Ishikawa M., Nakano Y., Faraonov M.A., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
European Journal of Inorganic Chemistry, 2014
131.
The Salts of Copper Octafluoro- and Hexadecafluorophthalocyanines Containing [CuII(F8Pc)4–]2– Dianions and [CuF16Pc]− Monoanions
Konarev D.V., Troyanov S.I., Kuzmin A.V., Nakano Y., Ishikawa M., Faraonov M.A., Khasanov S.S., Litvinov A.L., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Inorganic Chemistry, 2017
133.
Molecular Structure, Optical and Magnetic Properties of Dianionic Free-Base Tetrapyrazinoporphyrazine Macrocycle
Konarev D.V., Faraonov M.A., Kuzmin A.V., Fatalov A.M., Osipov N.G., Khasanov S.S., Shestakov A.F., Lyubovskaya R.N.
ChemistrySelect, 2018
134.
Molecular structures, and optical and magnetic properties of free-base tetrapyrazinoporphyrazine in various reduction states
Konarev D.V., Faraonov M.A., Kuzmin A.V., Osipov N.G., Khasanov S.S., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
New Journal of Chemistry, 2019
136.
Molecular Structure, Optical, and Magnetic Properties of Free-Base Naphthalocyanine Dianions
Konarev D.V., Khasanov S.S., Nakano Y., Shestakov A.F., Ishikawa M., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
European Journal of Organic Chemistry, 2018
137.
Double‐Decker Paramagnetic {(K)(H 3 Hhp) 2 } ⋅2− Radical Dianions Comprising Two [30]Trithia‐2,3,5,10,12,13,15,20,22,23,25,30‐Dodecaazahexaphyrins and a Potassium Ion
Konarev D.V., Khasanov S.S., Islyaikin M.K., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N., Ivanov E.N., Koifman O.I., Zhabanov Y.A.
Chemistry - An Asian Journal, 2019
138.
Structure and magnetic properties of ionic compound (Cp*2Cr+)·(FeIPc−)·(C6H4Cl2)4containing negatively charged iron phthalocyanine
Konarev D.V., Zorina L.V., Khasanov S.S., Hakimova E.U., Lyubovskaya R.N.
New Journal of Chemistry, 2012
140.
Lanthanide Double-Decker Complexes Functioning as Magnets at the Single-Molecular Level
Ishikawa N., Sugita M., Ishikawa T., Koshihara S., Kaizu Y.
Journal of the American Chemical Society, 2003
142.
10.1016/j.mencom.2020.05.001_sbref0435c
Tang
Lanthanide Single Molecule Magnets, 2015
143.
Cleavage of the C–H Bond in Bu3MeP+ by Zinc Porphyrin Dianions: Formation of {ZnII(CH2PBu3)(TPyPH)}− Containing Zn–C(ylide) Bond and the (TPyPH)3– Macrocycle Showing Strong NIR Absorption
Konarev D.V., Kuzmin A.V., Khasanov S.S., Shestakov A.F., Litvinov A.L., Sobov P.A., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Inorganic Chemistry, 2020
145.
Radical Anions of Free‐Base Tetraphenyl‐ and Tetrakis(pentafluorophenyl)porphyrins: Effect of Substituents on the Properties and Charge Disproportionation in {Cryptand[2.2.2](Cs + )}(H 2 TPP ·– )
Konarev D.V., Kuzmin A.V., Khasanov S.S., Shestakov A.F., Nazarov D.I., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
European Journal of Inorganic Chemistry, 2020
146.
Coordination Complexes of Transition Metals (M = Mo, Fe, Rh, and Ru) with Tin(II) Phthalocyanine in Neutral, Monoanionic, and Dianionic States.
Konarev D.V., Kuzmin A.V., Nakano Y., Faraonov M.A., Khasanov S.S., Otsuka A., Yamochi H., Saito G., Lyubovskaya R.N.
Inorganic Chemistry, 2016
147.
Salt of Ring‐Reduced Iron(II) Octaethyltetrapyrazinoporphyrazine Containing Trimetallic Dianions with Peripherally Coordinated ZnCl 2 Units: {Fe II (TPyzPzEt 8 ) 4– (ZnCl 2 ) 2 } 2–
Faraonov M.A., Romanenko N.R., Kuzmin A.V., Konarev D.V., Shestakov A.F., Stuzhin P.A., Khasanov S.S., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
European Journal of Inorganic Chemistry, 2019
150.
Two isomorphous complexes: dichloro[phthalocyaninato(2–)]tin(IV) and dichloro[phthalocyaninato(2–)]germanium(IV)
Janczak J., Kubiak R.
Acta Crystallographica Section C Crystal Structure Communications, 2003
152.
Interligand Charge Transfer in a Complex of Deprotonated cis-Indigo Dianions and Tin(II) Phthalocyanine Radical Anions with Cp*IrIII
Konarev D.V., Zorina L.V., Khasanov S.S., Shestakov A.F., Fatalov A.M., Otsuka A., Yamochi H., Kitagawa H., Lyubovskaya R.N.
Inorganic Chemistry, 2017
153.
Coordination Complexes of Titanium(IV) and Indium(III) Phthalocyanines with Carbonyl-Containing Dyes: The Formation of Singly Bonded Anionic Squarylium Dimers
Konarev D.V., Kuzmin A.V., Khasanov S.S., Fatalov A.M., Yudanova E.I., Lyubovskaya R.N.
Chemistry - A European Journal, 2018