Solution Chemistry Group

Current projects

Liquid-phase synthesis of new metal-organic frameworks. Solvent as a tool to manage this synthesis

Project leader — Mikhail Skripkin, PhD

Synthesis and study of properties of metal-organic frameworks (MOFs) is one of the most rapidly developed fields of modern Coordination Chemistry. It was shown earlier that formation of MOFs is affected by numerous factors like the kind of organic linkers, coordination ability of metal ions, pH, duration of process, temperature, reagents ratio and solvent applied. The set of methods to obtain these compounds has been elaborated like slow evaporation, solvothermal synthesis, microwave synthesis, sonochemical, mechanochemical reactions etc. Extremely wide field of application of this kind of compounds have been shown — they can be applied as the containers for gas storage, materials for gas separation (including hydrocarbons), catalytic systems for fine organic synthesis and synthesis of biologically active compounds, luminescent materials. But still so important aspect like the proper choice of the solvent for the synthesis is not resolved. At the same time the solvent affect significantly on the crystallization speed, crystallinity of material obtained, pore size, sorption ability of compound. Therefore, it seems to be very actual to reveal the solvent effect on the formation of metal-organic frameworks. The aim of present project is to reveal the solvent effect on the formation of metal-organic frameworks upon slow evaporation and solvothermal synthesis and to study its effect on the compound’s properties.

Formation of mixed solvates of transition metal salts in ternary systems containing a mixed solvent or several salts

Project leader — Nikita Bogachev, PhD

The project is devoted to the problem of the relationship between the properties of multicomponent solutions including three-component systems with competing solvation and the composition and structure of crystallizing solids. The principal fundamental goal of the project is to reveal the effect of interactions in solutions on the formation of solid phase (crystallosolvates) in the systems d-element salt — binary organic solvent. This study is at the boundary of several actual fields of pure and applied chemistry. First of all, it provides new experimental data concerning properties of multicomponent solutions containing mixed organic solvent, that promotes further development of the theory of condensed state and especially the theory of solutions. Moreover, solvates of d-elements’ salts that can be easily obtained can be the substituents of the expensive catalysts based on platinum metal complexes. Therefore, the establishment of main regularities of formation of non-aqueous solvated of transition metal compounds can become the basis for the elaboration of the new methods of energy — and resource-saving liquid-phase synthesis of new catalysts and sorbents with easily varied properties. The aim of this project is to reveal the effect of mixed solvent, its composition and properties on the formation of homo- and hetero- crystallosolvates and on the structure of these compounds. The principal goal of the project is to show the effect of competing processes of solvation and complexation on the solid phase formation in ternary systems containing two organic solvents and d-element salt.

Study of structure, micro- and macroproperties of multicomponent aqueous solutions of electrolytes

Project leader — Ol’ga Pestova, PhD

Electrolyte solutions are the complex systems where a variety of chemical species present in equilibrium state. The study of chemical species formed by ions in solutions including solvo- and acidocomplexes allows to develop further the models of solution structure that in turn promotes the establishment of general regularities of the effect of solution microstructure on its macroproperties. The study of structural zones in solutions and of their dependence on the concentration of solute is of great importance for the development of methods of the extraction of components from brines that are utilized in chemical technology of salt production. The aim of this project is to study the regularities of solution’s structure formation depending on the chemical nature of ions and concentration of solution.

Publications

2020

1. Khvorost, T. A., Beliaev, L. Y., Potalueva, E., Laptenkova, A. V., Selyutin, A. A., Bogachev, N. A., Skripkin, M. Y., Ryazantsev, M. N., Tkachenko, N., Mereshchenko, A. S., 2020, Journal of Physical Chemistry B. 124, 18, p. 3724–3733
2. Ivanov, M., Sizov, V., Kudrev, A., 2020, Journal of Molecular Structure. 1202, 127365.

2019

1. Bogachev, N. A., Gorbunov, A. O., Skripkin, M. Y., Nikol’skii, A. B., 2019, Russian Journal of General Chemistry. 89, 6, p. 1142–1153
2. Skripkin, M. Y., Chernykh, L. V., Pestova, O. N., Baranauskaite, V. E., Burkov, K. A., Zamyatin, I. V., Stepakova, L. V., Gusev, I. M., Gorbunov, A. O., Bogachev, N. A., Starova, G. L., 2019, Russian Journal of General Chemistry. 89, 6, p. 1085–1101
3. Bogachev, N. A., Tsyrul’nikov, N. A., Makarova, A. A., Tolmachev, M. V., Starova, G. L., Skripkin, M. Y., Nikol’skii, A. B., 2019, Russian Journal of General Chemistry. 89, 5, p. 859–864
4. Krapivin, M. A., Ivanov, N. S., Kondratiev, Y. V., Pestova, O. N., Khripun, V. D., 2019,: Russian Journal of General Chemistry. 89, 4, p. 856–858
5. Kudrev, A. G., 2019, Russian Journal of General Chemistry. 89, 6, p. 1115–1128
6. Baranauskaite, V., Pestova, O., Vovk, M., Matveev, V., Lähderanta, E., 2019, Physical Chemistry Chemical Physics. 21, 41, p. 22895–22901

2018

1. Stepashkin N.A., Chernenko M.K., Khripun V.D., Ivanov N.S., Sukhodolov N.G. 2018, Thin Solid Films., 661, p. 1–6
2. N.A. Stepashkin, M.K. Chernenko, V.D. Khripun, N.S. Ivanov, N.G. Sukhodolov 2018, Reviews on Advanced Materials Science. 56, p. 215–223
3. Scheme of the Complex Formation of DNA Telomeric Sequence with TMPyP4 Porphyrine
4. Kudrev, A. G., 2018, Russian Journal of General Chemistry. 88, 12, p. 2578–2588
5. Olshin, P. K., Myasnikova, O. S., Kashina, M. V., Gorbunov, A. O., Bogachev, N. A., Kompanets, V. O., Mereshchenko, A. S. (2018). The electronic spectra and the structures of the individual copper(II) chloride and bromide complexes in acetonitrile according to steady-state absorption spectroscopy and DFT/TD-DFT calculations. Chemical Physics, 503, 14-19. doi: 10.1016/j.chemphys.2018.01.020
6. Bogachev, N. A., Lyubichev, D. A., Starova, G. L., Nikolskii, A. B., & Skripkin, M. Y. (2018). Solubility of copper(II) chloride in mixed organic oxygen-containing solvents. Russian Journal of General Chemistry, 88(4), 617-621. doi: 10.1134/S1070363218040011
7. Bogachev, N. A., Starova, G. L., Razzhivin, A. V., Skripkin, M. Y., & Nikolskii, A. B. (2018). Solubility of d-element salts in organic and Aqueous–Organic solvents: VI.1Structure and thermal stability of cadmium iodide and bromide solvates with dimethylacetamide and dimethylformamide. Russian Journal of General Chemistry, 88(1) doi: 10.1134/S1070363218010012
8. Pestova, O. N., Bukesova, V. A., Kondrat’ev, Y. V., Khripun, V. D., & Baranauskaite, V. E. (2018). Energy characteristics of Lithium–Cesium binary chloride dissolution in water. Russian Journal of General Chemistry, 88(3), 596-597. doi: 10.1134/S1070363218030325
9. Kondrat’ev, Y. V., Butlak, A. V., Kazakov, I. V., Krasnova, I. S., Chislov, M. V., & Timoshkin, A. Y. (2018). Heat effects of the thermal decomposition of amidoboranes of potassium, calcium, and strontium. Russian Journal of Physical Chemistry A, 92(4), 640-645. doi: 10.1134/S0036024418040143
10. Stepashkin, N. A., Chernenko, M. K., Khripun, V. D., Ivanov, N. S., & Sukhodolov, N. G. (2018). Electrochemical properties of langmuir-blodgett films containing cobalt hexacyanoferrate nanoparticles. Thin Solid Films, 661, 1-6. doi: 10.1016/j.tsf.2018.06.052

2017

1. Bogachev, N. A., Tsyrulnikov, N. A., Starova, G. L., Skripkin, M. Y., & Nikolskii, A. B. (2017). Solubility of salts of d-elements in organic and water-organic solvents: V. inner-sphere chalcogen S–S contacts in the [Ni(DMSO)₄(H₂O)₂]Cl₂ solvate. Russian Journal of General Chemistry, 87(11), 2748-2749. doi: 10.1134/S1070363217110378
2. Gorbunov, A. O., Lindqvist-Reis, P., Mereshchenko, A. S., & Skripkin, M. Y. (2017). Solvation and complexation of europium(III) ions in triflate and chloride aqueous-organic solutions by TRLF spectroscopy. Journal of Molecular Liquids, 240, 25-34. doi: 10.1016/j.molliq.2017.04.136
3. Mereshchenko, A. S., Myasnikova, O. S., Panov, M. S., Kochemirovsky, V. A., Skripkin, M. Y., Budkina, D. S., & Tarnovsky, A. N. (2017). Solvent effects on nonradiative relaxation dynamics of low-energy ligand-field excited states: A CuCl₄^2- complex. Journal of Physical Chemistry B, 121(17), 4562-4568. doi: 10.1021/acs.jpcb.7b02015
4. Pestova, O. N., Efimov, A. Y., Myund, L. A., Kudrev, A. G., Khripun, V. D., Davidian, A. G., & Baranauskaite, V. E. (2017). Structural inhomogeneity in electrolyte solutions: The calcium Perchlorate–Water system. Journal of Solution Chemistry, 46(9-10), 1854-1870. doi: 10.1007/s10953-017-0662-3
5. Kudrev, A. G. (2017). Spectrophotometric study of melting of double stranded poly[A]·Poly[U] in the aqueous solution. Russian Journal of General Chemistry, 87(4), 788-794. doi: 10.1134/S107036321704020X
6. Ovsepyan, G. K., Kudrev, A. G., Shumilova, G. I., Starikova, A. A., Semeikin, A. S., & Pendin, A. A. (2017). Protolytic properties of water-soluble magnesium 5,10,15,20-tetra(1-methylpyridin-1-ium-4-yl)porphyrinate tetraperchlorate MgTMPyP4. Russian Journal of General Chemistry, 87(12), 2906-2908. doi: 10.1134/S1070363217120295
7. Kudrev, A. G. (2017). The evidence of cooperative binding of a ligand to G4 DNA. Journal of Analytical Methods in Chemistry, 2017 doi: 10.1155/2017/6780521
8. Panov, M. S., Vereshchagina, O. A., Ermakov, S. S., Tumkin, I. I., Khairullina, E. M., Skripkin, M. Y., Kochemirovsky, V. A. (2017). Non-enzymatic sensors based on in situ laser-induced synthesis of copper-gold and gold nano-sized microstructures. Talanta, 167, 201-207. doi: 10.1016/j.talanta.2017.01.089

2016

1. Efimov, A. Y., Khripun, M. K., Myund, L. A., & Pestova, O. N. (2016). Mobile nanostructures (cybotactic groups) as a basis of generalised phenomenological model of aqueous electrolyte solutions. International Journal of Nanotechnology, 13(1-3), 95-111. doi: 10.1504/IJNT.2016.074526
2. Pestova, O. N., Baranauskaite, V. E., & Khripun, M. K. (2016). Formation of binary salts in the system LiCl–CsCl–H₂O. Russian Journal of General Chemistry, 86(4), 767-770. doi: 10.1134/S1070363216040010
3. Khripun, V. D., Krapivin, M. A., Tsyleva, K. S., Sukhodolov, N. G., & Kondrat'Ev, Y. V. (2016). State of molybdenum clusters in solutions: III. formation enthalpies of intermediate products of stepwise K₂[Mo₂(SO₄)₄] oxidation in 1 M H₂SO₄ solution. Russian Journal of General Chemistry, 86(1), 5-8. doi: 10.1134/S1070363216010023
4. Tolstykh, G., Sizov, V., & Kudrev, A. (2016). Surface complex of ZnTMPyP₄ metalloporphyrin with double-stranded poly(A)-poly(U). Journal of Inorganic Biochemistry, 161, 83-90. doi: 10.1016/j.jinorgbio.2016.05.004
5. Kudrev, A. G. (2016). Model of cooperative interaction of TMPyP₄ porphyrine with DNA quadruplex. Russian Journal of General Chemistry, 86(6), 1353-1363. doi: 10.1134/S1070363216060219
6. Mereshchenko, A. S., Olshin, P. K., Myasnikova, O. S., Panov, M. S., Kochemirovsky, V. A., Skripkin, M. Y., Tarnovsky, A. N. (2016). Ultrafast photochemistry of copper(II) monochlorocomplexes in methanol and acetonitrile by broadband deep-UV-to-near-IR femtosecond transient absorption spectroscopy. Journal of Physical Chemistry A, 120(11), 1833-1844. doi: 10.1021/acs.jpca.5b12509
7. Bogachev, N. A., Tsyrulnikov, N. A., Gorbunov, A. O., Nikolskii, A. B., Skripkin, M. Y., & Burkov, K. A. (2016). Solubility of d-elements salts in organic and aqueous-organic solvents: IV. solubility of cadmium chloride. Russian Journal of General Chemistry, 86(11), 2405-2409. doi: 10.1134/S1070363216110013
8. Gorbunov, A. O., Tsyrul’nikov, N. A., Tikhomirova, A. A., Bogachev, N. A., Skripkin, M. Y., Nikolskii, A. B., & Pestova, O. N. (2016). Solubility of d-element salts in organic and aqueous–organic solvents: II. effect of halocomplex formation on solubility of cobalt bromide and chloride and nickel chloride. Russian Journal of General Chemistry, 86(4), 771-777. doi: 10.1134/S1070363216040022
9. Bogachev, N. A., Gorbunov, A. O., Nikolskii, A. B., & Skripkin, M. Y. (2016). Solubility of d-elements salts in organic and aqueous-organic solvents: III. influence of intermolecular association on solubility of cadmium bromide and iodide. Russian Journal of General Chemistry, 86(7), 1539-1544. doi: 10.1134/S107036321607001X

2015

1. Bogachev, N. A., Gorbunov, A. O., Tikhomirova, A. A., Pushikhina, O. S., Skripkin, M. Y., & Nikolskii, A. B. (2015). Solubility of d-elements salts in organic and aqueous-organic solvents: I. copper, cobalt, and cadmium sulfates. Russian Journal of General Chemistry, 85(11), 2509-2512. doi: 10.1134/S107036321511002X
2. Kochemirovsky, V. A., Skripkin, M. Y., Tveryanovich, Y. S., Mereshchenko, A. S., Gorbunov, A. O., Panov, M. S., Safonov, S. V. (2015). Laser-induced copper deposition from aqueous and aqueous–organic solutions: State of the art and prospects of research. Russian Chemical Reviews, 84(10), 1059-1075. doi: 10.1070/RCR4535
3. Tolstykh, G., & Kudrev, A. (2015). Mutual influence between contiguous TMPyP4 ligands when bound to a synthetic double-stranded poly(A)-poly(U). Journal of Molecular Structure, 1098, 342-350. doi: 10.1016/j.molstruc.2015.06.031
4. Khripun, V. D., Krapivin, M. A., Tsyleva, K. S., Sukhodolov, N. G., & Kondrat'Ev, Y. V. (2015). State of molybdenum clusters in solutions: II. thermodynamics of formation of dimolybdenum(II) tetrakis(trifluoroacetate) complexes with hexamethylphosphotriamide in 1,2-dichloroethane. Russian Journal of General Chemistry, 85(10), 2227-2232. doi: 10.1134/S1070363215100023
5. Mereshchenko, A. S., Olshin, P. K., Karabaeva, K. E., Panov, M. S., Wilson, R. M., Kochemirovsky, V. A., Tarnovsky, A. N. (2015). Mechanism of formation of copper(II) chloro complexes revealed by transient absorption spectroscopy and DFT/TDDFT calculations. Journal of Physical Chemistry B, 119(28), 8754-8763. doi: 10.1021/acs.jpcb.5b03889

2014

1. Kinzhalov, M. A., Borozdinova, A. M., Boyarskaya, I. A., Skripkin, M. Y., & Boyarskii, V. P. (2014). Reversible chelating in acyclic diaminocarbene palladium complex containing hydrazide fragment. Russian Journal of General Chemistry, 84(11), 2138-2141. doi: 10.1134/S1070363214110164
2. Mereshchenko, A. S., Olshin, P. K., Karimov, A. M., Skripkin, M. Y., Burkov, K. A., Tveryanovich, Y. S., & Tarnovsky, A. N. (2014). Photochemistry of copper(II) chlorocomplexes in acetonitrile: Trapping the ligand-to-metal charge transfer excited staterelaxations pathways. Chemical Physics Letters, 615(1), 105-110. doi: 10.1016/j.cplett.2014.10.016
3. Pestova, O. N., David'yan, A. G., Myund, L. A., Khripun, M. K., & Efimov, A. Y. (2014). Solubility polytherms and eutectic concentrations of scandium, yttrium, and lanthanum perchlorate solutions. Russian Journal of General Chemistry, 84(10), 1899-1903. doi: 10.1134/S1070363214100053
4. Davidian, A. G., Kudrev, A. G., Myund, L. A., Khlynova, O. S., & Khripun, M. K. (2014). Structure of aqueous electrolyte solutions estimated by near infrared spectroscopy and chemometric analysis of spectral data. Russian Journal of General Chemistry, 84(10), 1877-1887. doi: 10.1134/S1070363214100028
5. Davidian, A. G., Kudrev, A. G., Myund, L. A., & Khripun, M. K. (2014). Detection of hydrate forms of lithium and sodium perchlorates in aqueous solutions using near infrared spectroscopy. Journal of Near Infrared Spectroscopy, 22(2), 121-128. doi: 10.1255/jnirs.1107
6. Davidian, A. G., Kudrev, A. G., Myund, L. A., & Khripun, M. K. (2014). Near infrared spectral studies of aqueous solutions of metal perchlorates in groups I A, II A, II B, III A and III B of the periodic table. Journal of Near Infrared Spectroscopy, 22(1), 27-34. doi: 10.1255/jnirs.1090
7. Kudrev, A. G. (2014). Calculation of equilibrium formation constants of complexes with a polydentate oligomer. Russian Journal of General Chemistry, 84(3), 424-432. doi: 10.1134/S1070363214030037
8. Khripun, V. D., Krapivin, M. A., Sukhodolov, A. O., & Kondrat'ev, Y. V. (2014). State of molybdenum clusters in solutions: I. stability of the [Mo₂(SO₄)₄]^4- ion in H₂SO₄ solutions. Russian Journal of General Chemistry, 84(12), 2393-2396. doi: 10.1134/S1070363214120068
9. Ivanov, N. S., Khripun, V. D., Trofimov, M. A., Sukhodolov, N. G., & Pendin, A. A. (2014). Synthesis of nanodimensional films based on hybrid materials and their application in the ion-selective electrodes. Reviews on Advanced Materials Science, 39(1), 34-40. Retrieved from www.scopus.com

2013

1. Kudrev, A. G. (2013). Calculation of cooperativity and equilibrium constants of ligands binding to G-quadruplex DNA in solution. Talanta, 116, 541-547. doi: 10.1016/j.talanta.2013.07.012
2. Kudrev, A. G. (2013). Cooperative binding of 2,2′-bipyridine into polynucleotide poly(A)-poly(U-) in an alkaline aqueous solution. Biopolymers, 99(9), 621-627. doi: 10.1002/bip.22227
3. Kudrev, A. G. (2013). Cooperativity during binding of a ligand to a multidentate oligomer. Polymer Science - Series A, 55(10), 586-594. doi: 10.1134/S0965545X13090022
4. David'Yan, A. G., Kudrev, A. G., Myund, L. A., & Khripun, M. K. (2013). Structure of aqueous solutions of group IIIA metals perchlorates by near infrared spectroscopy. Russian Journal of General Chemistry, 83(3), 415-422. doi: 10.1134/S107036321303002X
5. Lindqvist-Reis, P., Apostolidis, C., Walter, O., Marsac, R., Banik, N. L., Skripkin, M. Y., Morgenstern, A. (2013). Structure and spectroscopy of hydrated neptunyl(vi) nitrate complexes. Dalton Transactions, 42(43), 15275-15279. doi: 10.1039/c3dt51650d
6. Geranmayeh, S., Abbasi, A., Zarnani, A. -., & Skripkin, M. Y. (2013). A novel trinuclear zinc metal-organic network: Synthesis, X-ray diffraction structures, spectroscopic and biocompatibility studies. Polyhedron, 61, 6-14. doi: 10.1016/j.poly.2013.05.030

2012

1. Gorbunov, A. O., Spektor, K. K., Skripkin, M. Y., & Tsyrulnikov, N. A. (2012). Solution-solid phase equilibrium in the systems copper(ii) halide-aprotic organic solvent-water. Russian Journal of General Chemistry, 82(6), 1053-1057. doi: 10.1134/S1070363212060023
2. Abbasi, A., Geranmayeh, S., Skripkin, M. Y., & Eriksson, L. (2012). Potassium ion-mediated non-covalent bonded coordination polymers. Dalton Transactions, 41(3), 850-859. doi: 10.1039/c1dt11698c
3. Geranmayeh, S., Abbasi, A., Skripkin, M. Y., & Badiei, A. (2012). A novel 2D zinc metal-organic framework: Synthesis, structural characterization and vibrational spectroscopic studies. Polyhedron, 45(1), 204-212. doi: 10.1016/j.poly.2012.07.013
4. Davidian, A. G., Pestova, O. N., Starova, G. L., Gurzhii, V. V., Myund, L. A., & Khripun, M. K. (2012). X-ray diffraction study of isomorphous crystal nonahydrates of aluminum, gallium, and scandium perchlorates. Russian Journal of General Chemistry, 82(4), 621-625. doi: 10.1134/S1070363212040019
5. Kudrev, A. G. (2012). [Model of cytosine-, thymine-containing olygodeoxyribonucleotide protonation in solution]. Biofizika, 57(3), 422-431. Retrieved from www.scopus.com
6. Timoshkin, A. Y., & Kudrev, A. G. (2012). Calculations of microconstants and equilibrium formation constants for platinum(II) and palladium(II) halide complexes in solution. Russian Journal of Inorganic Chemistry, 57(10), 1362-1370. doi: 10.1134/S0036023612100142
7. Kudrev, A. G. (2012). Model of cytosine-, thymine-containing oligodeoxyribonucleotide protonation in solution. Biophysics (Russian Federation), 57(3), 305-313. doi: 10.1134/S0006350912030104
8. Kudrev, A. G. (2012). Calculation of equilibrium binding constants and cooperativity of cu(II) mixed solvated complexes formation. Talanta, 101, 157-160. doi: 10.1016/j.talanta.2012.09.014

2011

1. Abbasi, A., Skripkin, M. Y., Eriksson, L., & Torapava, N. (2011). Ambidentate coordination of dimethyl sulfoxide in rhodium(iii) complexes. Dalton Transactions, 40(5), 1111-1118. doi: 10.1039/c0dt01026j
2. Gusev, I. M., & Skripkin, M. Y. (2011). Formation of complex and double salts in systems MX₂-NR₄X-H₂O [M = cd(II), cu(II), co(II), mg(II); X = cl, br; R = me, et, bu] at 25 °C. Russian Journal of Applied Chemistry, 84(1), 25-35. doi: 10.1134/S1070427211010046
3. Grigor'ev, Y. M., Gusev, I. M., & Skripkin, M. Y. (2011). Structure of NR₄BR-H₂O and CoBr₂-NR₄BR-H₂O solutions according to electronic and IR spectroscopy data. Russian Journal of General Chemistry, 81(7), 1424-1429. doi: 10.1134/S1070363211070048
4. Gusev, I. M., Skripkin, M. Y., Spektor, K. K., & Starova, G. L. (2011). Solution-solid phase equilibrium in the systems MgBr2-NR4Br-H2O at 25 °C (R = me, et, bu). Russian Journal of General Chemistry, 81(4), 623-627. doi: 10.1134/S1070363211040013
5. Tyutyunnik, A. P., Zubkov, V. G., Krasil'Nikov, V. N., Berger, I. F., Perelyaeva, L. A., Baklanova, I. V., Svensson, G. (2011). Crystal structure and vibrational spectra of M[VO2(SeO4)(H2O)2]·H2O (M = K, rb, NH4). Journal of Structural Chemistry, 52(2), 350-357. doi: 10.1134/S0022476611020156
6. Pestova, O. N., David'Yan, A. G., Myund, L. A., & Khripun, M. K. (2011). Solubility of aluminum, gallium, and indium perchlorates in water. Russian Journal of General Chemistry, 81(8), 1583-1587. doi: 10.1134/S1070363211080020
7. Kudrev, A. G. (2011). Calculation of equilibrium constants of ligand binding by a metal ion in solution using a chemometric procedure. Russian Journal of General Chemistry, 81(3), 456-462. doi: 10.1134/S1070363211030029

2010

1. Gusev, I. M., Skripkin, M. Y., & Burkov, K. A. (2010). Solution-solid phase equilibrium in the systems MBr2-NR4Br-H2O (M = cd, cu, co; R = me, et, bu) at 25°C. Russian Journal of General Chemistry, 80(8), 1563-1567. doi: 10.1134/S1070363210080049
2. Gusev, I. M., Skripkin, M. Y., & Burkov, K. A. (2010). Anion influence on the solution-solid phase equilibria in the MX2-NEt4X-H2O systems (M = cd, cu, co; X = cl, br) at 25°C. Russian Journal of General Chemistry, 80(9), 1729-1732. doi: 10.1134/S107036321009001X
3. Bucek, P., Gargallo, R., & Kudrev, A. (2010). Spectrometric study of the folding process of i-motif-forming DNA sequences upstream of the c-kit transcription initiation site. Analytica Chimica Acta, 683(1), 69-77. doi: 10.1016/j.aca.2010.10.008
4. Gargallo, R., Eritja, R., & Kudrev, A. G. (2010). Spectrometric study of the oligodeoxyribonucleotide protonation in aqueous solution. Russian Journal of General Chemistry, 80(3), 485-492. doi: 10.1134/S1070363210030205
5. Kudrev, A. G. (2010). Calculation of the equilibrium constants and cooperative parameters of formation of cu(II) chloride complexes in nonaqueous solvents. Russian Journal of Coordination Chemistry/Koordinatsionnaya Khimiya, 36(9), 704-710. doi: 10.1134/S1070328410090113
6. Kudrev, A. G. (2010). Alternative complex formation model based of spectrophotometry data for the cu(II)-bromide ion system in solution. Russian Journal of Inorganic Chemistry, 55(5), 814-819. doi: 10.1134/S0036023610050268
7. Starova, G. L., Skripkin, M. Y., & Gusev, I. M. (2010). Structure of complex bromides crystallizing in MBr2-NEt4Br-H2O systems (M = cd, cu, co) at 25°C. Russian Journal of General Chemistry, 80(7), 1236-1241. doi: 10.1134/S1070363210070030
8. Mink, J., Hajba, L., Pápai, I., Mihály, J., Neméth, C., Skripkin, M. Y., & Sandström, M. (2010). Vibrational spectroscopic and theoretical studies of urea derivatives with biochemical interest: N,N'-dimethylurea, N,N,N',N'-tetramethylurea, and N,N'-dimethylpropyleneurea. Applied Spectroscopy Reviews, 45(4), 274-326. doi: 10.1080/05704928.2010.483670
9. Mink, J., Hajba, L., Pápai, I., Mihály, J., Neméth, C., Skripkin, M. Y., & Sandström, M. (2010). Raman, infrared, far-infrared and theoretical studies of urea derivatives with biological interest. Paper presented at the AIP Conference Proceedings, 1267 605-606. doi: 10.1063/1.3482702 Retrieved from www.scopus.com

2009

1. Gusev, I. M., & Skripkin, M. Y. (2009). Comparative analysis of the solubility in the systems CuBr 2-NR4Br-H2O at 25°C. Russian Journal of Applied Chemistry, 82(2), 222-227. doi: 10.1134/S1070427209020116
2. Risberg, E. D., Mink, J., Abbasi, A., Skripkin, M. Y., Hajba, L., Lindqvist-Reis, P., Sandström, M. (2009). Ambidentate coordination in hydrogen bonded dimethyl sulfoxide, (CH3)2SO⋯H3O+, and in dichlorobis(dimethyl sulfoxide) palladium(ii) and platinum(ii) solid solvates, by vibrational and sulfur K-edge X-ray absorption spectroscopy. Dalton Transactions, (8), 1328-1338. doi: 10.1039/b814252a
3. Stepakova, L. V., Skripkin, M. Y., Korneeva, V. V., Grigoriev, Y. M., & Burkov, K. A. (2009). Organic solvent effect on the solution-solid phase equilibria in the systems CuCl2-L-H2O (L = DMSO, DMF, acetonitrile) at 25°C. Russian Journal of General Chemistry, 79(6), 1053-1056. doi: 10.1134/S1070363209060012
4. Kudrev, A. G. (2009). Calculation of the equilibrium constants and binding cooperativity parameters of ammonia with group II metal cations in solution. Russian Journal of General Chemistry, 79(10), 2087-2095. doi: 10.1134/S1070363209100028