Institute of Information Engineering, Automation, and Mathematics

Position:: Secretary of institute
Secretary of department
Lecturer
Department:: Department of Mathematics (DM)
Room:: NB 619
eMail:
Phone:: +421 259 325 344
Research activities:: quantum chemistry; programming: C/C++, python; parallel and GPU programming in an HPC environment; applied mathematics; neural networks
Availability:

Citations

Total citations 128

M. Malček – K. Čermáková – P. Rapta – M. Gall – L. Bučinský: Tailoring the hydrogen storage performance of the Cr-, Mn-, and Fe-doped circumcoronenes by the presence of N and B co-dopants: Computational study. International Journal of Hydrogen Energy, no. 47, vol. 81, 2022.

Number of citations 2

Sánchez-Rodríguez, E.P. – Santos-López, G. – Cruz-Martínez, H. – Calaminici, P. – Medina, D.I.: Pd2 and CoPd dimers/N-doped graphene sensors with enhanced sensitivity for CO detection: A first-principles study. Journal of Molecular Modeling, no. 8, vol. 29, 2023.
Belkhiria, S. – Briki, C. – Almoneef, M. – Dhaou, M.H. – Alresheedi, F. – Mbarek, M. – Jemni, A.: Experimental and numerical study of hydrogen absorption in the MmNi5−xMx compound. International Journal of Hydrogen Energy, vol. 51, pp. 29-40, 2024.

M. Jablonský – M. Štekláč – V. Majová – M. Gall – J. Matúška – M. Pitoňák – L. Bučinský: Molecular docking and machine learning affinity prediction of compounds identified upon softwood bark extraction to the main protease of the SARS-CoV-2 virus Slovenský názov:. Biophysical Chemistry, no. 106854, vol. 288, 2022.

Number of citations 3

Zhang, J. – Zhang, J. – Liang, L. – Sun, B. – Zhang, Y.: Identification and virtual screening of novel umami peptides from chicken soup by molecular docking. Food Chemistry, no. 134414, vol. 404, 2023.
Song, D. – Zhao, H. – Wang, L. – Wang, F. – Fang, L. – Zhao, X.: Ethanol extract of Sophora japonica flower bud, an effective potential dietary supplement for the treatment of hyperuricemia. Food Bioscience, no. 102457, vol. 52, 2023.
Wang, H. – Wang, W. – Zhang, S. – Hu, Z. – Yao, R. – Hadiatullah, H. – Li, P. – Zhao, G.: Identification of novel umami peptides from yeast extract and the mechanism against T1R1/T1R3. Food Chemistry, no. 136807, vol. 429, 2023.

L. Bučinský – D. Bortňák – M. Gall – J. Matúška – V. Milata – M. Pitoňák – M. Štekláč – D. Végh – D. Zajaček: Machine learning prediction of 3CL(pro) SARS-CoV-2 docking scores. Computational Biology and Chemistry, no. 107656, vol. 98, 2022.

Number of citations 4

Xiong, Y. – Wang, Y. – Wang, Y. – Li, C. – Yusong, P. – Wu, J. – Wang, Y. – Gu, L. – Butch, C.J.: Improving drug discovery with a hybrid deep generative model using reinforcement learning trained on a Bayesian docking approximation. Journal of Computer-Aided Molecular Design, no. 11, vol. 37, pp. 507-517, 2023.
Kidambi Raju, S. – Ramaswamy, S. – Eid, M.M. – Gopalan, S. – Karim, F.K. – Marappan, R. – Khafaga, D.S.: Evaluation of Mutual Information and Feature Selection for SARS-CoV-2 Respiratory Infection. Bioengineering, no. 7, vol. 10, 2023.
Tropsha, A. – Isayev, O. – Varnek, A. – Schneider, G. – Cherkasov, A.: Integrating QSAR modelling and deep learning in drug discovery: the emergence of deep QSAR. Nature Reviews Drug Discovery, 2023.
Zhang, W. – Huang, W. – Tan, J. – Guo, Q. – Wu, B.: Heterogeneous catalysis mediated by light, electricity and enzyme via machine learning: Paradigms, applications and prospects. Chemosphere, no. 136447, vol. 308, 2022.

N. Krivoňáková – A. Šoltýsová – M. Tamáš – Z. Takáč – J. Krahulec – A. Ficek – M. Gál – M. Gall – M. Fehér – A. Krivjanská – I. Horáková – N. Belišová – A. Butor Škulcová – P. Bímová – T. Mackuľak: Mathematical modeling based on RT‑qPCR analysis of SARS‑CoV‑2 in wastewater as a tool for epidemiology. Scientific Reports, no. art. no. 19456, vol. 11, pp. 1–10, 2021.

Number of citations 16

Kilaru, Pruthvi – Hill, Dustin – Anderson, Kathryn – Collins, Mary B. – Green, Hyatt – Kmush, Brittany L. – Larsen, David A.: Wastewater Surveillance for Infectious Disease: A Systematic Review. American Journal of Epidemiology, 2022.
Lin, T. – Karthikeyan, S. – Satterlund, A. – Schooley, R. – Knight, R. – De Gruttola, V. – Martin, N. – Zou, J.: Optimizing campus-wide COVID-19 test notifications with interpretable wastewater time-series features using machine learning models. Scientific Reports, no. 1, vol. 13, 2023.
Acosta, N. – Dai, X. – Bautista, M.A. – Waddell, B.J. – Lee, J. – Du, K. – McCalder, J. – Pradhan, P. – Papparis, C. – Lu, X. – Chekouo, T. – Krusina, A. – Southern, D. – Williamson, T. – Clark, R.G. – Patterson, R.A. – Westlund, P. – Meddings, J. – Ruecker, N. – Lammiman, C. – Duerr, C. – Achari, G. – Hrudey, S.E. – Lee, B.E. – Pang, X. – Frankowski, K. – Hubert, C.R.J. – Parkins, M.D.: Wastewater-based surveillance can be used to model COVID-19-associated workforce absenteeism. Science of the Total Environment, no. 165172, vol. 900, 2023.
Torabi, F. – Li, G. – Mole, C. – Nicholson, G. – Rowlingson, B. – Smith, C.R. – Jersakova, R. – Diggle, P.J. – Blangiardo, M.: Wastewater-based surveillance models for COVID-19: A focused review on spatio-temporal models. Heliyon, no. 11, vol. 9, 2023.
Phan, T. – Brozak, S. – Pell, B. – Oghuan, J. – Gitter, A. – Hu, T. – Ribeiro, R.M. – Ke, R. – Mena, K.D. – Perelson, A.S. – Kuang, Y. – Wu, F.: Making waves: Integrating wastewater surveillance with dynamic modeling to track and predict viral outbreaks. Water Research, no. 120372, vol. 243, 2023.
Mattei, M. – Pintó, R.M. – Guix, S. – Bosch, A. – Arenas, A.: Analysis of SARS-CoV-2 in wastewater for prevalence estimation and investigating clinical diagnostic test biases. Water Research, no. 120223, vol. 242, 2023.
Polcz, P. – Tornai, K. – Juhász, J. – Cserey, G. – Surján, G. – Pándics, T. – Róka, E. – Vargha, M. – Reguly, I.Z. – Csikász-Nagy, A. – Pongor, S. – Szederkényi, G.: Wastewater-based modeling, reconstruction, and prediction for COVID-19 outbreaks in Hungary caused by highly immune evasive variants. Water Research, no. 120098, vol. 241, 2023.
Belmonte-Lopes, R. – Barquilha, C.E.R. – Kozak, C. – Barcellos, D.S. – Leite, B.Z. – da Costa, F.J.O.G. – Martins, W.L. – Oliveira, P.E. – Pereira, E.H.R.A. – Filho, C.R.M. – de Souza, E.M. – Possetti, G.R.C. – Vicente, V.A. – Etchepare, R.G.: 20-Month monitoring of SARS-CoV-2 in wastewater of Curitiba, in Southern Brazil. Environmental Science and Pollution Research, no. 31, vol. 30, pp. 76687-76701, 2023.
Ciannella, S. – González-Fernández, C. – Gomez-Pastora, J.: Recent progress on wastewater-based epidemiology for COVID-19 surveillance: A systematic review of analytical procedures and epidemiological modeling. Science of the Total Environment, no. 162953, vol. 878, 2023.
Kilaru, P. – Hill, D. – Anderson, K. – Collins, M.B. – Green, H. – Kmush, B.L. – Larsen, D.A.: Wastewater Surveillance for Infectious Disease: A Systematic Review. American Journal of Epidemiology, no. 2, vol. 192, pp. 305-322, 2023.
Phan, T. – Brozak, S. – Pell, B. – Gitter, A. – Xiao, A. – Mena, K.D. – Kuang, Y. – Wu, F.: A simple SEIR-V model to estimate COVID-19 prevalence and predict SARS-CoV-2 transmission using wastewater-based surveillance data. Science of the Total Environment, no. 159326, vol. 857, 2023.
Hopkins, L. – Persse, D. – Caton, K. – Ensor, K. – Schneider, R. – McCall, C. – Stadler, L.B.: Citywide wastewater SARS-CoV-2 levels strongly correlated with multiple disease surveillance indicators and outcomes over three COVID-19 waves. Science of the Total Environment, no. 158967, vol. 855, 2023.
Sridhar, J. – Parit, R. – Boopalakrishnan, G. – Rexliene, M.J. – Praveen, R. – Viswananathan, B.: Importance of wastewater-based epidemiology for detecting and monitoring SARS-CoV-2. Case Studies in Chemical and Environmental Engineering, no. 100241, vol. 6, 2022.
Reynolds, L.J. – Gonzalez, G. – Sala-Comorera, L. – Martin, N.A. – Byrne, A. – Fennema, S. – Holohan, N. – Kuntamukkula, S.R. – Sarwar, N. – Nolan, T.M. – Stephens, J.H. – Whitty, M. – Bennett, C. – Luu, Q. – Morley, U. – Yandle, Z. – Dean, J. – Joyce, E. – O\\\'Sullivan, J.J. – Cuddihy, J.M. – McIntyre, A.M. – Robinson, E.P. – Dahly, D. – Fletcher, N.F. – Carr, M. – De Gascun, C. – Meijer, W.G.: SARS-CoV-2 variant trends in Ireland: Wastewater-based epidemiology and clinical surveillance. Science of the Total Environment, no. 155828, vol. 838, 2022.
Xiao, A. – Wu, F. – Bushman, M. – Zhang, J. – Imakaev, M. – Chai, P.R. – Duvallet, C. – Endo, N. – Erickson, T.B. – Armas, F. – Arnold, B. – Chen, H. – Chandra, F. – Ghaeli, N. – Gu, X. – Hanage, W.P. – Lee, W.L. – Matus, M. – McElroy, K.A. – Moniz, K. – Rhode, S.F. – Thompson, J. – Alm, E.J.: Metrics to relate COVID-19 wastewater data to clinical testing dynamics. Water Research, no. 118070, vol. 212, 2022.
Cluzel, N. – Courbariaux, M. – Wang, S. – Moulin, L. – Wurtzer, S. – Bertrand, I. – Laurent, K. – Monfort, P. – Gantzer, C. – Guyader, S.L. – Boni, M. – Mouchel, J.-M. – Maréchal, V. – Nuel, G. – Maday, Y.: A nationwide indicator to smooth and normalize heterogeneous SARS-CoV-2 RNA data in wastewater. Environment International, no. 106998, vol. 158, 2022.

M. Malček – B. Vénosová – I. Jelemenská – J. Kožíšek – M. Gall – L. Bučinský: Coordination bonding in dicopper and dichromium tetrakis(mu-acetato)-diaqua complexes: Nature, strength, length, and topology. Journal of Computational Chemistry, no. 7, vol. 41, pp. 698–714, 2020.

Number of citations 2

Dong, Z.-Q. – Yang, J.-H. – Liu, B.: Chromous carbonates containing a square-grid layer of {Cr2(CO3)4}: N 4 n -Based on a dichromium(ii,ii) paddlewheel core. Dalton Transactions, no. 7, vol. 50, pp. 2387-2392, 2021.
Liu, X. – Zhang, M. – Liu, Y. – Wu, S. – Su, Z.: A supported Cr-Cr sextuple bond in an all-metal cluster. Dalton Transactions, no. 7, vol. 51, pp. 2664-2668, 2022.

T. Csanádi – M. Gall – M. Vojtko – A. Kovalčíková – M. Hnatko – J. Dusza – P. Šajgalík: Micro scale fracture strength of grains and grain boundaries in polycrystalline La-doped β-Si3N4 ceramics. Journal of the European Ceramic Society, no. 14, vol. 40, pp. 4783–4791, 2020.

Number of citations 8

Tanabe, M. – Tatami, J. – Iijima, M. – Yahagi, T. – Takahashi, T. – Nakano, H. – Ohji, T.: Deformation behaviors and fracture strength of -Si3N4 single crystals. Journal of the American Ceramic Society, no. 9, vol. 106, pp. 5431-5439, 2023.
Lee, C.-E. – Kim, M.-J. – Park, Y.-J. – Ko, J.-W. – Kim, H.-N. – Bae, S.: The effect of silicon particle size on the characteristics of porous sintered reaction bonded silicon nitride. International Journal of Refractory Metals and Hard Materials, no. 105647, vol. 101, 2021.
Yang, P. – Wu, S. – Wu, H. – Lu, D. – Zou, W. – Chu, L. – Shao, Y. – Wu, S.: Prediction of bending strength of Si3N4 using machine learning. Ceramics International, no. 17, vol. 47, pp. 23919-23926, 2021.
Emdadi, A. – Asle Zaeem, M.: Phase-field modeling of crack propagation in polycrystalline materials. Computational Materials Science, no. 110057, vol. 186, 2021.
Hirshikesh, H. – Alankar, A.: On the interplay of elastic anisotropy and fracture toughness anisotropy in fracture of single and multiphase polycrystals. Engineering Fracture Mechanics, no. 108696, vol. 273, 2022.
Mollaei, Z. – Kermani, F. – Moosavi, F. – Kargozar, S. – Khakhi, J.V. – Mollazadeh, S.: In silico study and experimental evaluation of the solution combustion synthesized manganese oxide (MnO2) nanoparticles. Ceramics International, no. 2, vol. 48, pp. 1659-1672, 2022.
Kuwabara, A. – Gao, X. – Riedel, R. – Ionescu, E. – Ikuhara, Y.: Defect structures and dopant solution states of Hf-doped Si3N4 ceramics. International Journal of Applied Ceramic Technology, no. 1, vol. 20, pp. 190-196, 2023.
Yan, S. – Men, S. – Zou, H. – Wang, H. – Zhang, Z. – Wang, C. – Sui, T. – Lin, B.: Carbon fiber cannot always reduce the wear of PEEK for orthopedic implants under DPPC lubrication. Friction, no. 3, vol. 11, pp. 395-409, 2023.

P. Herich – L. Bučinský – M. Breza – M. Gall – M. Fronc – V. Petříček – J. Kožíšek: Electronic structure of two isostructural “paddle-wheel” complexes: a comparative study.. Acta Crystallographica Section B-Structural Science, no. 6, vol. 74, pp. 681–692, 2018.

Number of citations 14

Scatena, R. – Guntern, Y.T. – Macchi, P.: Electron Density and Dielectric Properties of Highly Porous MOFs: Binding and Mobility of Guest Molecules in Cu3(BTC)2 and Zn3(BTC)2. Journal of the American Chemical Society, no. 23, vol. 141, pp. 9382-9390, 2019.
Scatena, R. – Johnson, R.D. – Manuel, P. – Macchi, P.: Formate-mediated magnetic superexchange in the model hybrid perovskite [(CH3)2NH2]Cu(HCOO)3. Journal of Materials Chemistry C, no. 37, vol. 8, pp. 12840-12847, 2020.
Healy, C. – Patil, K.M. – Wilson, B.H. – Hermanspahn, L. – Harvey-Reid, N.C. – Howard, B.I. – Kleinjan, C. – Kolien, J. – Payet, F. – Telfer, S.G. – Kruger, P.E. – Bennett, T.D.: The thermal stability of metal-organic frameworks. Coordination Chemistry Reviews, no. 213388, vol. 419, 2020.
Scatena, R. – Johnson, R.D. – Manuel, P. – Macchi, P.: Formate-mediated magnetic superexchange in the model hybrid perovskite [(CH3)2NH2]Cu(HCOO)3. Journal of Materials Chemistry C, no. 37, vol. 8, pp. 12840-12847, 2020.
Torubaev, Y.V. – Skabitsky, I.V.: A new supramolecular heterosynthon [C-IOC(carboxylate)] at work: Engineering copper acetate cocrystals. CrystEngComm, no. 40, vol. 22, pp. 6661-6673, 2020.
Sarmah, N. – Baruah, S. – Malakar, A. – Chakrabortty, M. – Banik, B. – Das, B.K.: Synthesis, characterization and antimicrobial properties of [Cu2(μ-O2CC9H19)4(4-CNpy)2]. Asian Journal of Chemistry, no. 2, vol. 33, pp. 453-458, 2021.
Scatena, R. – Guntern, Y.T. – Macchi, P.: Electron Density and Dielectric Properties of Highly Porous MOFs: Binding and Mobility of Guest Molecules in Cu3(BTC)2 and Zn3(BTC)2. Journal of the American Chemical Society, no. 23, vol. 141, pp. 9382-9390, 2019.
Chen, B. – Zeng, X. – Liu, Y. – Xiao, F. – Huang, M. – Bing Tan, K. – Cai, D. – Huang, J. – Zhan, G.: Thermal decomposition kinetics of M−BTC (M = Cu, Co, Zn, and Ce) and M−BTC/Pt composites under oxidative and reductive environments. Chemical Engineering Journal, no. 138470, vol. 450, 2022.
Pinto, C.B. – Dos Santos, L.H.R. – Rodrigues, B.L. – Nangia, A.: Experimental charge density and topological analysis of tetraaquabis(hydrogenmaleato)nickel(II): a comparison with Hirshfeld atom refinement. Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials, vol. 79, pp. 281-295, 2023.
Khan, M.S. – Ansari, M.A.H. – Khalid, M. – Shahid, M. – Ahmad, M.: Synthesis, characterization, single-crystal X-ray study and sensing properties of a designed dinuclear Cu(II) system. Inorganic and Nano-Metal Chemistry, 2023.
Stepanenko, I. – Mizetskyi, P. – Orlowska, E. – Bučinský, L. – Zalibera, M. – Vénosová, B. – Clémancey, M. – Blondin, G. – Rapta, P. – Novitchi, G. – Schrader, W. – Schaniel, D. – Chen, Y.-S. – Lutz, M. – Kožíšek, J. – Telser, J. – Arion, V.B.: The Ruthenium Nitrosyl Moiety in Clusters: Trinuclear Linear μ-Hydroxido Magnesium(II)-Diruthenium(II), μ3-Oxido Trinuclear Diiron(III)-Ruthenium(II), and Tetranuclear μ4-Oxido Trigallium(III)-Ruthenium(II) Complexes. Inorganic Chemistry, no. 2, vol. 61, pp. 950-967, 2022.
Reinholdt, A. – Staples, O. – Mindiola, D.J.: Chromium(II) complexes, vol. 1-9, 2021.
Koziskova, J.A. – Breza, M. – Valko, M. – Herich, P. – Bucinsky, L. – Kozisek, J.: Electronic structure of Schiff-base peroxo{2,2′-[1,2-phenylenebis(nitrilomethanylylidene)]bis(6-methoxyphenolato)}titanium(IV) monohydrate: A possible model structure of the reaction center for the theoretical study of hemoglobin. IUCrJ, vol. 8, pp. 295-304, 2021.
Vénosová, B. – Koziskova, J. – Kozísek, J. – Herich, P. – Luspai, K. – Petricek, V. – Hartung, J. – Muller, M. – Hubschle, C.B. – Van Smaalen, S. – Bucinsky, L.: Charge density of 4-methyl-3-[(tetrahydro-2Hpyran- 2-yl)oxy]thiazole-2(3H)-thione. A comprehensive multipole refinement, maximum entropy method and density functional theory study. Acta Crystallographica Section B: Structural Science, Crystal Engineering and Materials, vol. 76, pp. 450-468, 2020.

A. Soroceanu – M. Cazacu – S. Shova – C. Turta – J. Kožíšek – M. Gall – M. Breza – P. Rapta – T. Mac Leod – A. Pombeiro – J. Telser – A. Dobrov – V. Arion: Copper(II) Complexes with Schiff Bases Containing a Disiloxane Unit: Synthesis, Structure, Bonding Features and Catalytic Activity for Aerobic Oxidation of Benzyl Alcohol. European Journal of Inorganic Chemistry, pp. 1458–1474, 2013.

Number of citations 35

Zhang, G. – Li, L. – Yang, C. – Liu, E. – Golen, J.A. – Rheingold, A.L.: Copper(II) complexes derived from bidentate N,O-ligands for catalytic aerobic oxidation. Inorganic Chemistry Communications, vol. 51, pp. 13-16, 2015.
Zhang, G. – Proni, G. – Zhao, S. – Constable, E.C. – Housecroft, C.E. – Neuburger, M. – Zampese, J.A.: Chiral tetranuclear and dinuclear copper(ii) complexes for TEMPO-mediated aerobic oxidation of alcohols: Are four metal centres better than two?. Dalton Transactions, no. 32, vol. 43, pp. 12313-12320, 2014.
Guan, J. – Liu, J.: A Copper(II) Schiff base complex immobilized onto SBA-15 silica for selective oxidation of benzyl alcohol. Transition Metal Chemistry, no. 2, vol. 39, pp. 233-238, 2014.
Guan, J. – Liu, J.: Bis(8-quinolinolato)copper(II) immobilized onto amino-modified SBA-15 for the selective oxidation of benzyl alcohol. Reaction Kinetics, Mechanisms and Catalysis, no. 2, vol. 111, pp. 751-761, 2014.
Freitag, L. – Knecht, S. – Keller, S.F. – Delcey, M.G. – Aquilante, F. – Bondo Pedersen, T. – Lindh, R. – Reiher, M. – González, L.: Orbital entanglement and CASSCF analysis of the Ru-NO bond in a Ruthenium nitrosyl complex. Physical Chemistry Chemical Physics, no. 22, vol. 17, pp. 14383-14392, 2015.
Gaona, M.A. – Montilla, F. – Álvarez, E. – Galindo, A.: Synthesis, characterization and structure of nickel and copper compounds containing ligands derived from keto-enehydrazines and their catalytic application for aerobic oxidation of alcohols. Dalton Transactions, no. 14, vol. 44, pp. 6516-6525, 2015.
Chen, T. – Cai, C.: Selective Oxidation of Benzyl Alcohols to Aldehydes with a Salophen Copper(II) Complex and tert-Butyl Hydroperoxide at Room Temperature. Synthetic Communications, no. 11, vol. 45, pp. 1334-1341, 2015.
Das, O. – Paine, T.K.: Copper catalysts for aerobic oxidation of alcohols. RSC Green Chemistry, no. 28, vol. 2015-January, pp. 40-69, 2015.
Han, S. – Wang, Y.: Synthesis, structural characterization and catalytic oxidation property of schiff base copper(II) complexes. Journal of the Chilean Chemical Society, no. 4, vol. 59, pp. 2753-2755, 2015.
Lu, P. – Yu, Y.-H. – Chen, Z.-J. – Hou, G.-F. – Chen, Y.-M. – Ma, D.-S. – Gao, J.-S. – Gong, X.-F.: Syntheses, structures, catalytic and antitumor activities of a series of pyrimidine derivatives coordination complexes. Synthetic Metals, vol. 203, pp. 164-173, 2015.
Huidobro-Meezs, I.L. – Segovia-Poncelis, M. – Barquera-Lozada, J.E.: The Role of Bulkiness in Haptotropic Shifts of Metal–Cumulene Complexes. European Journal of Inorganic Chemistry, no. 26, vol. 2016, pp. 4226-4233, 2016.
Novak, M.S. – Büchel, G.E. – Keppler, B.K. – Jakupec, M.A.: Biological properties of novel ruthenium- and osmium-nitrosyl complexes with azole heterocycles. Journal of Biological Inorganic Chemistry, no. 3, vol. 21, pp. 347-356, 2016.
Castellarin, A. – Zorzet, S. – Bergamo, A. – Sava, G.: Pharmacological activities of ruthenium complexes related to their NO scavenging properties. International Journal of Molecular Sciences, no. 8, vol. 17, 2016.
Benferrah, N. – Hammadi, M. – Philouze, C. – Berthiol, F. – Thomas, F.: Copper(II) complex of a Schiff base of dehydroacetic acid: Characterization and aerobic oxidation of benzyl alcohol. Inorganic Chemistry Communications, vol. 72, pp. 17-22, 2016.
Clarke, R.M. – Herasymchuk, K. – Storr, T.: Electronic structure elucidation in oxidized metal–salen complexes. Coordination Chemistry Reviews, vol. 352, pp. 67-82, 2017.
Antony, R. – Marimuthu, R. – Vishnoi, P. – Murugavel, R.: Ethoxysilane appended M(II) complexes and their SiO2/MCM-41 supported forms as catalysts for efficient oxidation of secondary alcohols. Inorganica Chimica Acta, vol. 469, pp. 173-182, 2018.
del Mar Conejo, M. – Cantero, J. – Pastor, A. – Álvarez, E. – Galindo, A.: Synthesis, structure and properties of nickel and copper complexes containing N,O-hydrazone Schiff base ligand. Inorganica Chimica Acta, vol. 470, pp. 113-118, 2018.
Chaudhary, N.K. – Mishra, P.: Metal Complexes of a Novel Schiff Base Based on Penicillin: Characterization, Molecular Modeling, and Antibacterial Activity Study. Bioinorganic Chemistry and Applications, no. 6927675, vol. 2017, 2017.
Conejo, M.D.M. – Ávila, P. – Álvarez, E. – Galindo, A.: Synthesis and structure of nickel and copper complexes containing the N-allyl-o-hydroxyacetophenoniminato ligand and the application of copper complex as catalyst for aerobic alcohol oxidations. Inorganica Chimica Acta, vol. 455, pp. 638-644, 2017.
Racles, C. – Zaltariov, M.-F. – Iacob, M. – Silion, M. – Avadanei, M. – Bargan, A.: Siloxane-based metal–organic frameworks with remarkable catalytic activity in mild environmental photodegradation of azo dyes. Applied Catalysis B: Environmental, vol. 205, pp. 78-92, 2017.
do Pim, W.D. – Ribeiro-Santos, T.A. – Jardim, I.S. – de Castro, M.C.M. – Braga, A.H. – do Nascimento, G.M. – Binatti, I. – Stumpf, H.O. – Lorençon, E. – Araujo, M.H. – Pereira, C.L.M.: Bistable copper(II) metallosurfactant as molecular machine for the preparation of hybrid silica-based porous materials. Materials and Design, vol. 160, pp. 876-885, 2018.
Mohapatra, R.K. – Das, P.K. – Pradhan, M.K. – Maihub, A.A. – El-ajaily, M.M.: Biological aspects of Schiff base–metal complexes derived from benzaldehydes: an overview. Journal of the Iranian Chemical Society, no. 10, vol. 15, pp. 2193-2227, 2018.
Saxena, P. – Murugavel, R.: Bulky 2,6-dibenzhydryl-4-methylphenyl β-diiminato derived complexes of Pd(II) and Cu(II): Efficient catalysts for Suzuki coupling and alcohol oxidation. Journal of Organometallic Chemistry, vol. 868, pp. 76-85, 2018.
Mahmoud, W.H. – Mohamed, G.G. – El-Sayed, O.Y.: Coordination compounds of some transition metal ions with new Schiff base ligand derived from dibenzoyl methane. Structural characterization, thermal behavior, molecular structure, antimicrobial, anticancer activity and molecular docking studies. Applied Organometallic Chemistry, no. 2, vol. 32, 2018.
Miller, S.A. – Bisset, K.A. – Leadbeater, N.E. – Eddy, N.A.: Catalytic Oxidation of Alcohols Using a 2,2,6,6-Tetramethylpiperidine-N-hydroxyammonium Cation. European Journal of Organic Chemistry, no. 6, vol. 2019, pp. 1413-1417, 2019.
Beyramabadi, S.A. – Saadat-Far, M. – Faraji-Shovey, A. – Javan-Khoshkholgh, M. – Morsali, A.: Synthesis, experimental and computational characterizations of a new quinoline derived Schiff base and its Mn(II), Ni(II) and Cu(II) complexes. Journal of Molecular Structure, no. 127898, vol. 1208, 2020.
Yavari, M. – Beyramabadi, S.A. – Morsali, A. – Reza Bozorgmehr, M.: (E)-4-(((2-Amino-5-chlorophenyl)imino)methyl)-5-(hydroxymethyl)-2-methylpyridin-3-ol and its Cu(II) complex: Synthesis, DFT calculations and AIM analysis. Journal of the Serbian Chemical Society, no. 8, vol. 85, pp. 1033-1046, 2020.
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L. Bučinský – G. Büchel – R. Ponec – P. Rapta – M. Breza – J. Kožíšek – M. Gall – S. Biskupič – M. Fronc – K. Schiessl – O. Cuzan – D. Prodius – C. Turta – S. Shova – D. Zajac – V. Arion: On the electronic structure of mer,trans-[RuCl3(1H-indazole)2(NO)], a hypothetical metabolite of the antitumor drug sandidate KP1019: an experimental and DFT study. European Journal of Inorganic Chemistry, pp. 2505–2519, 2013.

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M. Gall – M. Breza: QTAIM study of transition metal complexes with cyclophosphazene-based multisite ligands I: Zinc(II) and nickel(II) complexes. Polyhedron, vol. 28, pp. 521–524, 2009.

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M. Gall – M. Breza: On electronic structure of tris(dimethylamino)sulphonium heptafluoro-oxocyclotetraphosphazenate. Journal of Molecular Structure: THEOCHEM, vol. 894, pp. 32–35, 2009.

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Naseh, M. – Sedaghat, T. – Tarassoli, A. – Shakerzadeh, E.: DFT studies of ONO Schiff bases, their anions and diorganotin(IV) complexes: Tautomerism, NBO and AIM analysis. Computational and Theoretical Chemistry, vol. 1005, pp. 53-57, 2013.
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M. Gall – M. Breza: On the structure of hexahydroxocyclotriphosphazene. Journal of Molecular Structure: THEOCHEM, vol. 861, pp. 33–38, 2008.

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Zhang, J. – Zheng, H. – Zhang, T. – Wu, M.: Theoretical study for high-energy-density compounds derived from cyclophosphazene. IV. DFT studies on 1,1-diamino-3,3,5,5,7,7- hexaazidocyclotetraphosphazene and its isomers. International Journal of Molecular Sciences, no. 8, vol. 10, pp. 3502-3516, 2009.
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