1. Fedotov S.S., Kabanova N.A., Kabanov A.A., Blatov V.A., Khasanova N.R., Antipov E.V. Crystallochemical tools in search for cathode materials of rechargeable Na-ion batteries and analysis of their transport properties. Solid State Ionics, 2018, 314, 129-140.
2. Akhmetshina T.G., Blatov V.A., Proserpio D.M., Shevchenko A.P. Topology of intermetallic structures: from statistics to rational design. Acc. Chem. Res., 2018, 51, 21–30.
3. Zheng T.-R., Blatov V. A., Zhang Y.-Q., Yang C.-H., Qian L.-L., Li B.-L., Wu B. An unusual (3,10)-coordinated 3D network coordination polymer as a potential luminescent sensor for detection of nitroaromatics and ferric ion. J. Lumin., 2018, 199, 126–132.
4. Zheng T.-R., Blatov V. A., Qian L.-L., Tang D.-Y., Zhang Y.-Q., Wang Z.-X., Li B.-L., Wu B. An unusual (4,6)-coordinated coordination polymer: High efficient degradation of organic dyes under visible light irradiation and electrochemical properties. Polyhedron, 2018, 148, 81-87.
5. Kuznetsova E.D., Blatova O.A., Blatov V.A. Predicting new zeolites: a combination of thermodynamic and kinetic factors. Chem. Mater., 2018, 30, 2829–2837.
6. Zhang Y.-Q., Blatov V. A., Zheng T.-R., Yang C.-H., Qian L.-L., Li K., Li B.-L., Wu B. A luminescent zinc(II) coordination polymer with unusual (3,4,4)-coordinated self-catenated 3D network for selective detection of nitroaromatics and ferric and chromate ions: a versatile luminescent sensor. Dalton Trans., 2018, 47, 6189-6198.
7. Bonneau C., O’Keeffe M., Proserpio D. M., Blatov V. A., Batten S. R., Bourne S. A., Soo Lah M., Eon J.-G., Hyde S. T., Wiggin S. B., Öhrström L. Deconstruction of Crystalline Networks into Underlying Nets: Relevance for Terminology Guidelines and Crystallographic Databases. Cryst. Growth Des., 2018, 18, 3411–3418.
8. Zhang Y.-Q., Blatov V. A., Lv X.-X., Yang C.-H., Qian L.-L., Li K., Li B.-L., Wu B. Construction of five zinc coordination polymers with 4-substituted bis(trizole) and multicarboxylate ligands: Syntheses, structures and properties. Polyhedron, 2018, 155, 223–231.
9. Eremin R.A., Kabanov N.A., Morkhova Ye.A., Golov A.A., Blatov V.A. High-throughput search for potential potassium ion conductors: A combination of geometrical-topological and density functional theory approaches. Solid State Ionics, 2018, 326, 188–199.
10. Meutzner F., Nestler T., Zschornak M., Canepa P., Gautam G. S., Leoni S., Adams S., Leisegang T., Blatov V. A., Meyer D. C. Computational analysis and identification of battery materials. Phys. Sci. Rev., 2019, 4, 20180044.
11. Bushlanov P. V., Blatov V. A., Oganov A. R. Topology-based crystal structure generator. Comp. Phys. Comm., 2019, 236, 1-7.
12. Kang W.-C., Liu D., Blatov V. A., Cui G.-H. Unique self-catenated 3D Cd(II)-MOF with a rare (3,3,9)-connected underlying network exhibiting high photocatalytic activities. Inorg. Chem. Commun., 2019, 102, 126-129.
13. Blatov V. A., Golov A.A., Yang C., Zeng Q., Kabanov A. A. Network topological model of reconstructive solid-state transformations. Sci. Rep., 2019, 9, 6007.
14. Qian L.-L., Blatov V. A., Wang Z.-X., Ding J.-G., Zhu L.-M., Li K., Li B.-L., Wu B. Sonochemical synthesis and characterization of four nanostructural nickel coordination polymers and photocatalytic degradation of methylene blue. Ultrason. Sonochem., 2019, 56, 213-228.
15. Leisegang T., Meutzner F., Zschornak M., Münchgesang W., Schmid R., Nestler T., Eremin R., Kabanov A.A., Blatov V. A., Meyer D. C. The aluminum-ion battery: A sustainable and seminal concept? Front. Chem., 2019, 7, 268.
16. Alexandrov E.V., Shevchenko A.P., Blatov V.A. Topological databases: why do we need them for design of coordination polymers? Cryst. Growth Des., 2019, 19, 2604-2614.
17. Zhang Y.-Q., Blatov V. A., Lv, X.-X.,Tang D.-Y., Qian L.-L., Li K., Li B.-L. Construction of (3,8)-connected three-dimensional cobalt (II) and copper(II) coordination polymers with 1,3-bis(1,2,4-triazol-4-ylmethyl)benzene and 1,3,5-benzenetricarboxylate ligands. Acta Cryst. 2019, C75, 960-968.
18. Meutzner F., Zschornak M., Kabanov A.A., Nestler T., Leisegang T., Blatov V. A., Meyer D. C. Sulphur- and selenium-containing compounds potentially exhibiting Al ion mobility. Chem. Eur. J. 2019, 25, 8623-8629.
19. Blatova O. A., Golov A.A., Blatov V. A. Natural tilings and free space in zeolites: models, statistics, correlations, prediction. Z. Kristallogr. 2019, 234, 421–436.
20. Alexandrov E.V., Goltsev A.V., Eremin R.A., Blatov V.A. Anisotropy of Elastic Properties of Metal-Organic Frameworks and the Breathing Phenomenon. J. Phys. Chem. C, 2019, 123, 24651−24658.
21. Blatov I.A., Kitaeva E.V., Shevchenko A.P., Blatov V.A. A universal algorithm for finding the shortest distance between systems of points. Acta Cryst., 2019, A75, 827-832.
22. Shevchenko V.Ya., Medrish I.V., Ilyushin G.D., Blatov V.A. From clusters to crystals: scale chemistry of intermetallics. Struct. Chem., 2019, 30, 2015-2027.
23. Golov A.A., Blatova O.A., Blatov V.A. Perceiving Zeolite Self-Assembly: a Combined Top-Down and Bottom-Up Approach within the Tiling Model. J. Phys. Chem. C, 2020, 124, 1523−1528.
24. Blatov V.A., Blatova O.A., Daeyaert F., Deem M.W. Nanoporous materials with predicted zeolite topologies. RSC Adv., 2020, 10, 17760–17767.
25. Fu M.-M., Qu Y.-H., Blatov V. A., Li Y.-H., Cui G.-H. Two d10 metal coordination polymers as dual functional luminescent probes for sensing of Fe3+ ions and acety-lacetone with high selectivity and sensitivity. J. Solid State Chem., 2020, 289, 121460.
26. Shevchenko A.P., Alexandrov E.V., Golov A.A., Blatova O.A., Duyunova A.S., Blatov V.A. Topology versus porosity: what can reticular chemistry tell us about free space in metal-organic frameworks? Chem. Commun., 2020, 56, 9616-9619.
27. Gulino V., Wolczyk A., Golov A.A., Eremin R.A., Palumbo M., Nervi C., Blatov V.A., Proserpio D.M., Baricco M. Combined DFT and Geometrical-Topological Analysis of Li-ion conductivity in Complex Hydrides. Inorg. Chem. Front., 2020, 7, 3115-3125.
28. Medrish I.V., Eremin R.A., Blatov V.A. From Simple to Complex: Design of Inorganic Crystal Structures with a Topologically Extended Zintl-Klemm Concept. J. Phys. Chem. Lett., 2020, 11, 8114–8120.
29. Bykov E., Kopytin K., Onuchak L.A., Blatov V.A. Monolayer Self-Organization of Cyclodextrins on Carbon Surface. J. Chin. Chem. Soc., 2020, 67, 1778–1782.
30. Shevchenko A.P., Eremin R.A., Blatov V.A. The CSD and knowledge databases: from answers to questions. CrystEngComm, 2020, 22, 7298–7307.
31. Blatov V. A., Yang C., Tang D., Zeng Q., Golov A.A., Kabanov A. A. High-throughput systematic topological generation of low-energy carbon allotropes. npj Comp. Mater., 2021, 7, 15.
32. Hill A. R., Cubillas P., Gebbie-Rayet J. T., Trueman M., de Bruyn N., al Harthi Z., Pooley R. J.S., Attfield M. P., Blatov V. A., Proserpio D. M., Gale J. D., Ak-poriaye D., Arstade B., Anderson M. W. CrystalGrower: A Generic Computer Pro-gram for Monte Carlo Modelling of Crystal Growth. Chem. Sci., 2021, 12, 1126-1146.
33. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. The Symmetric and Topological Code of the Cluster Self-Assembly of the Icosahedral Structure of (Rb13)(Rb2O)3 (Fm-3c, cF184) Metal Oxide. Glass Phys. Chem., 2018, 44, 55–61.
34. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: Two-Layer Quasi-Spherical Nanocluster Precursors K69 and K26 in the Crystal Structure of Li26Na58Ba38 (cF488). Glass Phys. Chem., 2018, 44, 261-268.
35. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: Cs6 and Cs4 Metal Clusters and Cs11O3 Metal–Oxygen Cluster for the Self-Assembly of the (Cs4)(Cs6)(Cs11O3) Crystal Structure. Glass Phys. Chem., 2018, 44, 375-380.
36. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: New 143-Atom Icosahedral Nanocluster-Precursor and the Self-Assembly of a Crystalline Framework (Ba,Ca)46Li102 (R-3c, hR888). Glass Phys. Chem., 2018, 44, 503–510.
37. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: 124-Icosahedral Three-Layered Cluster 0@12(Ga12)@32(Ga12Na20)@80(Ga60Na6K14) for the Self-Assembly of the Crystalline Framework of Na26K8Ga104 (R-3m, R414). Glass Phys. Chem., 2018, 44, 511–517.
38. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Symmetrical and Topological Self-Assembly Code of the Crystalline Structure of a New Aluminosilicate Zeolite ISC-1 from Templated t-plg Suprapolyhedral Precursors. Glass Phys. Chem., 2019, 45, 85–90.
39. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: 0@12(Ga12)@24(Na12Ga12)@72(Rb4Na8Ga60) 108-Atom Three-Layer Icosahedral Cluster and 0@12(Ga12)@32(Na20Ga12) 44-Atom Two-Layer Icosahedral Cluster for Rb24Na200Ga696-oF920 Crystal Structure Self-Assembly. Glass Phys. Chem., 2019, 45, 151-160.
40. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems. New Cluster Presursor (InNa5)(AuAu5) and Primary Chain with the 5m Symmetry for the Self-Assembly of the Na32Au44In24–oP100 Crystal Structure. Glass Phys. Chem., 2019, 45, 245-250.
41. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Modeling the Processes of Self-Organization in Crystal-Forming Systems: New Two-Layer Clusters–Precursors 0@(Na2Cd6)@(Na12Cd26) and 0@(Na3Cd6)@(Na6Cd35) for the Self-Assembly of the Na26Cd141–hP168 Crystal Structure. Glass Phys. Chem., 2019, 45, 311-316.
42. Morkhova E.A., Kabanov A.A., Blatov V.A. Modeling of Ionic Conductivity in Inorganic Compounds with Multivalent Cations. Russ. J. Electrochem., 2019, 55, 762–777.
43. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Modeling Self-Organization Processes in Crystal-Forming Systems: Suprapolyedic Na18Hg157 Precursor Clusters for the Self-Assembly of the Na99Hg468–hP567 Crystal Structure. Glass Phys. Chem., 2019, 45, 399-404.
44. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Modeling Self-Organization Processes in Crystal-Forming Systems: New Two-Layer Cluster–Precursor K44 = 0@8(Na2In6)@36(In6Cd6K6)2 for the Self-Assembly of the K23Na8Cd12In48–hP91 Crystal Structure. Glass Phys. Chem., 2019, 45, 405-411.
45. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: New Two-Layer Cluster-Precursor K46 = 0@8(Ca2Hg6)@38(Hg6 + CaHg6)2(Ca6Hg6) for Self-Assembly of the Crystal Structure of Ca11Hg54–hP65. Glass Phys. Chem., 2020, 46, 1-5.
46. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: New Precursor Cluster 0@8(Sr2Au6) for Self-Assembly of the Crystal Structure of (Sr2Au6)(Ga3)–hR66. Glass Phys. Chem., 2020, 46, 6-12.
47. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: Three-Layer Icosahedral Nanoclusters K132 = 0@12(In6Tl6)@30(In6Na6K18)@90(In72Na12K6) and K116 = 0@12(In6Tl6)@26(In12K14)@78(In36Tl20K12) for the Self-Assembly of the K52Na12Tl36In122-hP224 Crystalline Structure. Glass Phys. Chem., 2020, 46, 195-202.
48. Shevchenko V. Ya., Ilyushin G. D., Medrish I.V., Blatov V. A. Cluster Self-Organization of Intermetallic Systems: Role of K5 = 0@5, K9 = 1@8 and K11 = 0@11 Clusters in the Self-Assembly of Crystal Structures. Glass Phys. Chem., 2020, 46, 277-284.
49. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: New Three-Layer Cluster K142 for the Self-Assembly of the K44In80-hR366 Crystal Structure and the Bergman Tetracluster K141 for the Self-Assembly of the K34In82-cF464 Crystal Structure. Glass Phys. Chem., 2020, 46, 370-377.
50. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster-Precursors and Self-Assembly Li36Ca4Sn24-oS64 and LiMgEu2Sn3-oS28 Crystalline Structures. Glass Phys. Chem., 2020, 46, 441–447.
51. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: New Two-Layer Nanocluster Precursors K64 = 0@8(Sn4Ba4)@56(Na4Sn52) and K47 = Na@Sn16@Na30 in the Crystal Structure of Na52Ba4Sn80-cF540. Glass Phys. Chem., 2020, 46, 448–454.
52. Shevchenko V. Ya., Blatov V. A., Ilyushin G. D. Cluster Self-Organization of Intermetallic Systems: New Three-Layer Cluster Precursor K136 = 0@Zn12@32(Mg20Zn12)@92(Zr12Zn80) and a New Two-Layer Cluster Precursor K30 = 0@Zn6@Zn24 in the Crystal Structure of Zr6Mg20Zn128-cP154. Glass Phys. Chem., 2020, 46, 455–461.