| Novel carbon nanoparticles derived from Bougainvillea modulate vegetative growth via auxin–cytokinin signaling in Arabidopsis |
4733 |
– |
4750 |
| Raviraj B. Barot, Nilesh D. Gawande, Satya Omprabha, Charli Kaushal, Subhojit Ghosh, Jhuma Saha, Dhiraj Bhatia, and Subramanian Sankaranarayanan |
Vol. 78, 8 |
| Spectrofluorimetric determination of Alogliptin benzoate through condensation with ninhydrin and phenylacetaldehyde: application to dosage form and rat plasma |
5049 |
– |
5060 |
| Samia M. El-Gizawy, Noha N. Atia, Doaa H. Rushdy, and Marwa F. B. Ali |
Vol. 78, 8 |
| Determination of sulfur in petroleum coke by ion chromatography after pyrohydrolysis sample preparation and Box–Behnken design optimization |
1947 |
– |
1957 |
| Renan G. Marim, Amauri P. A. Rosa, Tatiane A. Maranhão, and Eduardo S. Chaves |
Vol. 78, 3 |
| Mössbauer study of thermal behavior of CL20ES and CL50WS steel powders used in selective laser melting |
7289 |
– |
7302 |
| Tatiana Ivanova, Michal Kořenek, Miroslav Mashlan, and Veronika Svačinová |
Vol. 77, 12 |
| Fabrication, characterization and structure activity relationship of Co and Mn encapsulated on magnetic nanocomposite and its application in one-pot tandem synthesis of various tetrazoles and vitamin K3 |
3581 |
– |
3605 |
| Fatemeh Ashouri, Ali Reza Faraji, Zahra Hekmatian, and Alireza Farahanipour |
Vol. 76, 6 |
| Chemical functionalization and thermal destruction of persistent organic pollutants: polychlorinated biphenyls |
3899 |
– |
3908 |
| Tatiana Kulikova, Anna Maiorova, Tatiana Gorbunova, Roza Gulyaeva, Alexander Safronov, and Marina Pervova |
Vol. 76, 6 |
| Synthesis, antimicrobial and α-glucosidase inhibition of new benzimidazole-1,2,3-triazole-indoline derivatives: a combined experimental and computational venture |
7607 |
– |
7622 |
| Laxmi Deswal, Vikas Verma, Devinder Kumar, Yogesh Deswal, Ashwani Kumar, Rajnish Kumar, Mahavir Parshad, and Meenakshi Bhatia |
Vol. 76, 12 |
| A simple and efficient method for simultaneous quantification of levodopa and carbidopa based on controlled oxidation process |
3091 |
– |
3102 |
| Ângela L. Andrade, Thaís D. Cardoso, Sérgio S. Thomasi, Meiry E. Alvarenga, Mirra A. N. da Silva, Elisângela J. Magalhães, Hélio A. Duarte, and Katia J. de Almeida |
Vol. 75, 7 |
| LaF3: Tb3+ nanoparticles show adaptability to targeted therapy for a safer cancer cell treatment |
5793 |
– |
5801 |
| Ghazaleh Rafatian, Seyed Jalal Zargar, Shahrokh Safarian, Susan Sadjadpour, and Najmeh Mozdoori |
Vol. 75, 11 |
| Theoretical investigations on the structural products of the amphiphilic copolymer of N-vinylpyrrolidone with triethylene glycol dimethacrylate and the μ-S–C–N type binuclear tetranitrosyl iron complex interaction |
95 |
– |
104 |
| Tatiana N. Rudneva, Nina S. Emel’yanova, and Svetlana V. Kurmaz |
Vol. 73, 1 |
| Kinetic study of growth, lipid and carotenoid formation in β-carotene producing Rhodotorula glutinis |
1193 |
– |
1203 |
| Jana Tkáčová, Tatiana Klempová, and Milan Čertík |
Vol. 72, 5 |
| DFT studies on coordination models for adsorption essays of Cu(II) and Ni(II) solutions in modified silica gel with iminodiacetic groups |
1019 |
– |
1030 |
| Alexander Carreño, Eduardo Schott, Ximena Zarate, Juan Manuel Manriquez, Juan C. Vega, Miguel Mardones, Alan H. Cowley, Ivonne Chavez, Juan P. Hinestroza, and Ramiro Arratia-Perez |
Vol. 71, 6 |
| Antioxidant and cytotoxic properties of riboflavin in PEG/BSA systems |
1107 |
– |
1117 |
| Mariana Voicescu, Georgiana Neacsu, Adrian Beteringhe, Oana Craciunescu, Rodica Tatia, and Lucia Moldovan |
Vol. 71, 6 |
| Diarylheptanoid-rich extract of grey and black alder barks: an effective dietary antioxidant in mayonnaise |
1007 |
– |
1012 |
| Maris Lauberts, Galina Telysheva, Petras Rimantas Venskutonis, Liga Lauberte, Tatiana Dizhbite, Rita Kazernavičiūte, and Audrius Pukalskas |
Vol. 71, 5 |
| Poly(4-amino-2,1,3-benzothiadiazole) films: preparation, characterization and applications |
359 |
– |
366 |
| Gabriela Broncová, Tatiana V. Shishkanova, Marcela Dendisová, Martin Člupek, David Kubáč, and Pavel Matějka |
Vol. 71, 2 |
| Influence of surface properties on the deposition of a polyaniline film and detection of tumor markers |
489 |
– |
494 |
| Tatiana V. Shishkanová, Klára Řezanková, and Pavel Řezanka |
Vol. 71, 2 |
| Chemical reactivity descriptors evaluation for determining catalytic activity, redox potential, and oxygen binding of metallophthalocyanines |
2185 |
– |
2194 |
| Cristian Linares-Flores, Ramiro Arratia-Pérez, and Desmond MacLeod Carey |
Vol. 71, 11 |
| X-ray diffraction and relativistic DFT studies on the molecular biomarker fac-Re(CO)3(4,4′-dimethyl-2,2′-bpy)(E-2-((3-amino-pyridin-4-ylimino)-methyl)-4,6-di-tert-butylphenol)(PF6) |
2011 |
– |
2022 |
| Alexander Carreño, Manuel Gacitúa, Elies Molins, and Ramiro Arratia-Pérez |
Vol. 71, 10 |
| Low-temperature enzymatic hydrolysis resolution in mini-emulsion media |
810 |
– |
816 |
| Nuno M. T. Lourenço, Sara C. Matias, Margarida C. Altas, and Luis P. Fonseca |
Vol. 69, 6 |
| Structure and vibrational spectra of copper(II) 2-pyridylmethanolate tetrahydrate |
940 |
– |
949 |
| Anton Gatial, Marcela Múdra, Ján Moncoľ, Marta Danková, Peter Lönnecke, and Martin Breza |
Vol. 68, 7 |
| Assessment of the fate of some household micropollutants in urban wastewater treatment plant |
601 |
– |
612 |
| Laure Pasquini, Jean-François Munoz, Nicole Rimlinger, Xavier Dauchy, Xavier France, Marie-Noëlle Pons, and Tatiana Görner |
Vol. 67, 6 |
| Aquaculture by-product: a source of proteolytic enzymes for detergent additives |
662 |
– |
669 |
| Chirleanny M. Mendes, Marília A. Brito, Tatiana S. Porto, Ana L. F. Porto, Ranilson S. Bezerra, Luiz B. Carvalho, Ana M. A. Caneiro-Leão, and Maria G. Carneiro-da-Cunha |
Vol. 63, 6 |
| Synthesis of 2-[3-(trifluoromethyl)phenyl]furo[3,2-c]pyridine derivatives |
586 |
– |
591 |
| Ivana Bradiaková, Tatiana Ďurčeková, Naďa Prónayová, Anton Gatial, and Alžbeta Krutošíková |
Vol. 63, 5 |
| QSAR analysis of 1,3-diaryl-2-propen-1-ones and their indole analogs for designing potent antibacterial agents |
456 |
– |
463 |
| Neela M. Bhatia, Kakasaheb R. Mahadik, and Manish S. Bhatia |
Vol. 63, 4 |
| Chemometrical analysis of computed QSAR parameters and their use in biological activity prediction |
84 |
– |
91 |
| Peter Nemeček, Tatiana Ďurčeková, Ján Mocák, and Karel Waisser |
Vol. 63, 1 |
| Synthesis and reactions of 2-[3-(trifluoromethyl)phenyl]furo[3,2-
c
]pyridine |
428 |
– |
434 |
| Ivana Bradiaková, Naďa Prónayová, Anton Gatial, and Alžbeta Krutošíková |
Vol. 62, 4 |
| Conformational analysis of aminomethylene- and (1-aminoethylidene)propanedinitriles |
367 |
– |
371 |
| V. Milata, A. Gatial, L. Zalibera, S. Biskupic, and D. Scheller |
Vol. 51, 6B |
| Physicochemical properties of the molten system Na3AlF6-K3AlF6-Al2O3. 1. The temperature of primary crystallization |
677 |
– |
684 |
| P. Fellner, M. Chrenková, J. Gabčová, and K. Matiašovský |
Vol. 44, 5 |
| Fusibility and structure of the NaF-rich melts in the NaF-NaAlSi3O8 and NaF-KAlSi3O8 systems |
685 |
– |
691 |
| K. Grjotheim, V. Daněk, K. Matiašovský, and J. Stubergh |
Vol. 44, 5 |
| The electrical conductance and the structure of the NaF AlF3 melts |
743 |
– |
751 |
| J. Šiška, V. Daněk, K. Matiašovský, and A. Silný |
Vol. 42, 6 |
| Volume properties of the melts of the system KF-KCl-K2TiF6 |
753 |
– |
761 |
| V. Daněk, J. Šiška, and K. Matiašovský |
Vol. 42, 6 |
| Electrolytic metal-coating in molten-salts |
527 |
– |
565 |
| K. Matiašovský, P. Fellner, M. Chrenková-Paučírová, Ž. Lubyová, and A. Silný |
Vol. 41, 4 |
| Chemical and phase compositions of boride layers grown on steel bases in molten-salts |
153 |
– |
166 |
| M. Chrenková-Paučírová, P. Fellner, K. Matiašovský, and J. Krištín |
Vol. 40, 2 |
| Simultaneous addition of lithium fluoride and magnesium fluoride in the aluminum electrolysis |
409 |
– |
424 |
| K. Grjotheim and K. Matiašovský |
Vol. 37, 3 |
| On thermal dehydrochlorination of model compounds for poly(vinyl chloride). V. Frequency factor calculations |
611 |
– |
626 |
| P. Kovařík, L. Valko, and A. Gatial |
Vol. 36, 5 |
| Electrical conductivity of molten LiCl—NaCl—KCl and LiCl—NaCl—KCl—AICI3 mixtures |
433 |
– |
440 |
| K. Matiašovský, G. Bräeutigam, M. Chrenková-Paučírová, P. Fellner, and G. Schulze |
Vol. 34, 4 |
| Calculation of the phase diagrams of multicomponent systems containing cryolite |
805 |
– |
812 |
| P. Fellner, M. Chrenková-Paučírová, and K. Matiašovský |
Vol. 30, 6 |
| Phase diagram of the ternary system KBF4—NaCl—KCl |
841 |
– |
846 |
| V. Daněk, I. Votava, M. Chrenková-Paučírová, and K. Matiašovský |
Vol. 30, 6 |
| Reactions of potassium tetrafluoroborate in molten alkali chlorides |
377 |
– |
383 |
| V. Daněk, I. Votava, and K. Matiašovský |
Vol. 30, 3 |
| Study of the system V205—Na20. II. Physicochemical properties of the molten V205—NaV03 mixtures |
728 |
– |
732 |
| V. Daněk, I. Votava, K. Matiašovský, and J. Balajka |
Vol. 28, 6 |
| Multiple coordinates of the reference points of the concentration diagrams of multicomponent systems |
468 |
– |
477 |
| M. Malinovský and K. Matiašovský |
Vol. 28, 4 |
| Cryometry in eutectic mixtures |
201 |
– |
203 |
| P. Fellner and K. Matiašovský |
Vol. 28, 2 |
| Chemical reactions in molten Na3AlF6—Si02—Al203—AlF3 mixtures |
737 |
– |
741 |
| P. Fellner and K. Matiašovský |
Vol. 27, 6 |
| Electrical conductivity of molten binary Na3AlF6—NaCl and Na3AlF6—BaCl2 mixtures |
742 |
– |
747 |
| K. Matiašovský and V. Daněk |
Vol. 27, 6 |
| Study of the system V205—Na20. I. Phase diagram of the system V205-NaV03 |
748 |
– |
751 |
| V. Daněk, J. Balajka, and K. Matiašovský |
Vol. 27, 6 |
| Measurement of viscosity of fused salts. II. Viscosity of molten binary mixtures with a cryolite base |
582 |
– |
587 |
| I. Votava and K. Matiašovský |
Vol. 27, 5 |
| Phase diagram of the system Li3AlF6—KCl. II.
Experimental results |
301 |
– |
305 |
| K. Matiašovský, I. Koštenská, and M. Malinovský |
Vol. 27, 3 |
| Some aspects of the electrolytic preparation of silicon alloys |
165 |
– |
171 |
| K. Grjotheim, K. Matiašovský, and P. Fellner |
Vol. 27, 2 |
| Measurement of viscosity of fused salts. I. Method of measurement. Viscosity of Li3AlF6 and Na3AlF6 |
172 |
– |
182 |
| I. Votava and K. Matiašovský |
Vol. 27, 2 |
| Phase Diagram of the System Li3AlF6—KCl. I. Theory |
31 |
– |
35 |
| M. Malinovský and K. Matiašovský |
Vol. 26, 1 |
| Double Layer Capacity Measurements in Molten Salts |
36 |
– |
40 |
| P. Fellner and K. Matiašovský |
Vol. 26, 1 |
| Chemical Reactions in the System Na3AlF6—Si02—Al |
249 |
– |
252 |
| K. Grjotheim and K. Matiašovský |
Vol. 25, 4 |
| Physico-Chemical Properties of the System Na3AlF6—NaCl—Ti02 |
253 |
– |
258 |
| T. P. Madhavan, K. Matiašovský, and V. Daněk |
Vol. 25, 4 |
| Measurement of the decomposition potential of aluminum oxide in trisodium aluminum fluoride-aluminum oxide and tripotassium aluminum fluoride-aluminum oxide melts |
561 |
– |
573 |
| A. Silný, M. Malinovský, and K. Matiašovský |
Vol. 23, 8 |
| Liquidus Curve and Density of the Molten System Li3AlF6—Na3AlF6 |
27 |
– |
34 |
| M. Malinovský, M. Paučírová, and K. Matiašovský |
Vol. 23, 1 |
| Electrical conductivity of fused salts in the lithium fluoride-aluminum fluoride and lithium fluoride-sodium aluminum fluoride systems |
641 |
– |
647 |
| V. Daněk, M. Malinovský, and K. Matiašovský |
Vol. 22, 9 |
| Method for measuring electrical conductivity in molten fluorides |
707 |
– |
714 |
| V. Daněk, M. Malinovský, and K. Matiašovský |
Vol. 22, 9 |
| Phase diagram of the NaF-LiF-AlF3-Al2O3 system. II. The LiF-AlF3 system |
794 |
– |
805 |
| M. Malinovský, I. Čakajdová, and K. Matiašovský |
Vol. 21, 11 |
| Simultaneous flame photometric determination of lithium and sodium |
839 |
– |
849 |
| Ž. Lubyová, M. Malinovský, and K. Matiašovský |
Vol. 21, 11 |
| Phase diagram in the NaF-LiF-AlF3-Al2O3 system. I. System NaF-LiF |
513 |
– |
520 |
| K. Matiašovský, I. Čakajdová, and M. Malinovský |
Vol. 19, 7 |
| The absorption of hydrofluoric acid in aqueous solutions |
456 |
– |
461 |
| M. Paučírová, K. Matiašovský, and M. Malinovský |
Vol. 19, 6 |
| Liquidus of the cryolyte corner of the Na3AlF6-Al2O3-Na2SO4 system |
41 |
– |
45 |
| K. Matiašovský and M. Malinovský |
Vol. 19, 1 |
| Electrical conductivity of melts of the system Na3AlF6-AlF3-Al2O3-NaCl |
140 |
– |
143 |
| K. Matiašovský, S. Ordzovensky, and M. Malinovský |
Vol. 18, 2 |
| Physicochemical analyses of some systems important in aluminum production. VIII. The density of melts of the system Na3AlF6-Al2O3-NaCl |
605 |
– |
615 |
| K. Matiašovský, A. Jászová, and M. Malinovský |
Vol. 17, 9 |
| Wetting carbon with molten cryolite |
181 |
– |
188 |
| K. Matiašovský, M. Paučírová, and M. Malinovský |
Vol. 17, 3 |
| The application of microanalysis for the measurement of critical current density at the electrolysis of cryolite fusions |
211 |
– |
216 |
| K. Matiašovský, V. Daněk, and M. Malinovský |
Vol. 17, 3 |
| Physicochemical analyses of some systems important in the production of aluminum. IX. Electric conductivity of cryolite and Na3AlF6-Al2O3 and Na3AlF6-NaCl |
839 |
– |
847 |
| K. Matiašovský, Š. Ordzovensky, and M. Malinovský |
Vol. 17, 12 |
| The density of melts in the system Na3AlF6-AlF3-Al2O3-NaCl |
848 |
– |
851 |
| K. Matiašovský, A. Jászová, and M. Malinovský |
Vol. 17, 12 |
| Pyrohydrolytic determination of fluorides. III. Optimum conditions of pyrohydrolysis |
808 |
– |
817 |
| K. Matiašovský and C. Kubík |
Vol. 16, 11 |
| Pyrohydrolytic determination of fluorides. II. The effect of temperature on the time of the hydrolysis |
741 |
– |
757 |
| K. Matiašovský and C. Kubík |
Vol. 16, 10 |
| The pyrohydrolytic determination of fluoride. I. The effect of activators on the temperature at the beginning of hydrolysis |
128 |
– |
134 |
| K. Matiašovský and C. Kubík |
Vol. 16, 1-2 |
| A theory for rationally describing the location of cross sections and points on a figure in multicomponent systems. II. Simple second-order cross sections |
617 |
– |
624 |
| M. Malinovský, K. Matiašovský, and C. Kubík |
Vol. 15, 9 |
| A theory for rationally describing the location of cross sections and points on a figure in multicomponent systems. I. Simple first-order cross sections |
529 |
– |
546 |
| M. Malinovský, K. Matiašovský, and C. Kubík |
Vol. 15, 8 |
| Physicochemical analysis of some systems important in the production of aluminum. V. Liquidus of the cryolite angle of the system Na3AlF6-AlF3-Al2O3-NaCl |
241 |
– |
256 |
| K. Matiašovský and M. Malinovský |
Vol. 15, 4 |
| Physicochemical analysis of some systems important in the production of aluminum. VI. Liquidus of the cryolite angle of the system Na3AlF6-AlF3-Al2O3-CaF2-NaCl |
257 |
– |
270 |
| K. Matiašovský and M. Malinovský |
Vol. 15, 4 |
| An adjustment for N. S. Kurnakov's pyrometer |
315 |
– |
318 |
| C. Kubík, K. Matiašovský, and M. Malinovský |
Vol. 15, 4 |
| Physicochemical analyses of some systems important in production of aluminum. IV. Liquidus of the cryolite angle of the system Na3AlF6-Al2O3-CaF2-NaCl-MgF2 |
161 |
– |
172 |
| K. Matiašovský and M. Malinovský |
Vol. 15, 3 |
| Physicochemical analyses of some systems important in aluminum production. VII. Liquidus of the cryolite angle in the cut of the system Na3AlF6AlF3-Al2O3-CaF2-NaCl-MgF2 with the constant mount of 3 percent CaF2 |
699 |
– |
712 |
| K. Matiašovský and M. Malinovský |
Vol. 15, 10 |
| Physical-chemical analysis of some systems important in production of aluminum. III. Liquidus of the cryolite angle of the system Na3AlF6-Al2O3-CaF2-NaCl |
551 |
– |
563 |
| K. Matiašovský and M. Malinovský |
Vol. 14, 8 |
| Physicochemical study of some systems important in the production of aluminum. II. The phase diagram of the system Na3AlF6-CaF2-NaCl |
353 |
– |
364 |
| K. Matiašovský and M. Malinovský |
Vol. 14, 5 |
| Physicochemical study of some systems important in the production of aluminum. I. Phase diagram of the system CaF2-NaCl |
258 |
– |
264 |
| K. Matiašovský and M. Malinovský |
Vol. 14, 4 |
| Phase diagrams of some systems important in electrolytic production of magnesium. I. Two-component systems MgCl2-NaCl, CaCl2-NaCl, and MgCl2-CaCl2 |
69 |
– |
77 |
| K. Matiašovský |
Vol. 13, 2 |
| Phase diagrams of some systems important in electrolytic production of magnesium. II. Three-component system MgCl2-CaCl2-NaCl |
78 |
– |
97 |
| K. Matiašovský |
Vol. 13, 2 |
