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Citácie

  • Celkový počet citácií       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, č. 47, zv. 81, 2022.
  • Počet citácií       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, č. 8, zv. 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, zv. 51, str. 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, č. 106854, zv. 288, 2022.
  • Počet citácií       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, č. 134414, zv. 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, č. 102457, zv. 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, č. 136807, zv. 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, č. 107656, zv. 98, 2022.
  • Počet citácií       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, č. 11, zv. 37, str. 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, č. 7, zv. 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, č. 136447, zv. 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, č. art. no. 19456, zv. 11, str. 1–10, 2021.
  • Počet citácií       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, č. 1, zv. 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, č. 165172, zv. 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, č. 11, zv. 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, č. 120372, zv. 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, č. 120223, zv. 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, č. 120098, zv. 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, č. 31, zv. 30, str. 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, č. 162953, zv. 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, č. 2, zv. 192, str. 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, č. 159326, zv. 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, č. 158967, zv. 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, č. 100241, zv. 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, č. 155828, zv. 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, č. 118070, zv. 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, č. 106998, zv. 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, č. 7, zv. 41, str. 698–714, 2020.
  • Počet citácií       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, č. 7, zv. 50, str. 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, č. 7, zv. 51, str. 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, č. 14, zv. 40, str. 4783–4791, 2020.
  • Počet citácií       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, č. 9, zv. 106, str. 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, č. 105647, zv. 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, č. 17, zv. 47, str. 23919-23926, 2021.
  • Emdadi, A. – Asle Zaeem, M.: Phase-field modeling of crack propagation in polycrystalline materials. Computational Materials Science, č. 110057, zv. 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, č. 108696, zv. 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, č. 2, zv. 48, str. 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, č. 1, zv. 20, str. 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, č. 3, zv. 11, str. 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, č. 6, zv. 74, str. 681–692, 2018.
  • Počet citácií       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, č. 23, zv. 141, str. 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, č. 37, zv. 8, str. 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, č. 213388, zv. 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, č. 37, zv. 8, str. 12840-12847, 2020.
  • Torubaev, Y.V. – Skabitsky, I.V.: A new supramolecular heterosynthon [C-IOC(carboxylate)] at work: Engineering copper acetate cocrystals. CrystEngComm, č. 40, zv. 22, str. 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, č. 2, zv. 33, str. 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, č. 23, zv. 141, str. 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, č. 138470, zv. 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, zv. 79, str. 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, č. 2, zv. 61, str. 950-967, 2022.
  • Reinholdt, A. – Staples, O. – Mindiola, D.J.: Chromium(II) complexes, zv. 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, zv. 8, str. 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, zv. 76, str. 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, str. 1458–1474, 2013.
  • Počet citácií       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, zv. 51, str. 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, č. 32, zv. 43, str. 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, č. 2, zv. 39, str. 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, č. 2, zv. 111, str. 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, č. 22, zv. 17, str. 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, č. 14, zv. 44, str. 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, č. 11, zv. 45, str. 1334-1341, 2015.
  • Das, O. – Paine, T.K.: Copper catalysts for aerobic oxidation of alcohols. RSC Green Chemistry, č. 28, zv. 2015-January, str. 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, č. 4, zv. 59, str. 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, zv. 203, str. 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, č. 26, zv. 2016, str. 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, č. 3, zv. 21, str. 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, č. 8, zv. 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, zv. 72, str. 17-22, 2016.
  • Clarke, R.M. – Herasymchuk, K. – Storr, T.: Electronic structure elucidation in oxidized metal–salen complexes. Coordination Chemistry Reviews, zv. 352, str. 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, zv. 469, str. 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, zv. 470, str. 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, č. 6927675, zv. 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, zv. 455, str. 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, zv. 205, str. 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, zv. 160, str. 876-885, 2018.
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