Metrics

  • citations in SCIndeks: 0
  • citations in CrossRef:0
  • citations in Google Scholar:[]
  • visits in previous 30 days:18
  • full-text downloads in 30 days:17

Contents

article: 9 from 10  
Back back to result list
2016, vol. 10, iss. 1, pp. 151-167
Advances made by Belgrade's group in research of oscillatory reactions
aUniversity of Belgrade, Faculty of Physical Chemistry + University of Belgrade, Institute of Chemistry, Technology and Metallurgy - IChTM
bUniversity of Belgrade, Institute of Chemistry, Technology and Metallurgy - IChTM

emaillkolar@ffh.bg.ac.rs, zcupic@ihtm.bg.ac.rs, boban@ffh.bg.ac.rs
Project:
Dynamics of nonlinear physicochemical and biochemical systems with modeling and predicting of their behavior under nonequilibrium conditions (MESTD - 172015)
Nanostructured Functional and Composite Materials in Catalytic and Sorption Processes (MESTD - 45001)

Keywords: oscillatory reactions; nonlinear dynamics; stoichiometric network analysis; numerical techniques for detection of periodic and aperiodic dynamic states; analytical determination
Abstract
Oscillatory dynamic states as one form of selforganization of nonlinear systems can be found in almost all sciences, like mechanics, physical chemistry or biomedicine. Although origin of these oscillations is different, computational challenges in modelling oscillatory phenomena remain similar in all fields. Since 1979 researchers from Belgrade's group perform systematic examinations of oscillatory reactions. As stability of steady states is the central point in modelling oscillatory reactions, in last 10 years they have adapted and improved powerful tool of the Stoichiometric Network Analysis for this goal. Moreover, bifurcations of few types were identified in several models of oscillatory reactions. Even very complex chaotic motions in phase space were characterized and quantified by several numerical techniques. Multiple time scale behaviour is found within the core of the complex dynamic behaviour of mixed-mode oscillations. Analytical applications were developed, too.
References
Anić, S., Kostić, M., Ninić, M., Blagojević, S., Kolar-Anić, Lj. (2007) Activation energies as the validity criterion of a model for complex reactions that can be in oscillatory states. Science of Sintering, vol. 39, br. 1, str. 77-83
Anić, S. (1997) Relation between number of oscillations and activation energies of an oscillatory process. J. Serb. Chem. Soc, vol. 62, 65-69
Anić, S., Mitić, D., Kolar-Anić, L. (1985) The Bray-Liebhafsky reaction, I: Controlled development of oscillations. J. Sreb. Chem. Soc, vol. 50, 53, 505
Anić, S., Kolar-Anić, L. (1996) Bray-Liebhafsky reaction, VI: Kinetics in iodide oscillations. J. Serb. Chem. Soc, vol. 61, 887
Anić, S., Kolar-Anić, L., Koros, E. (1997) Method to determine activation energies for the two kinetic states of the oscillatory Bray-Liebhafsky reaction. React. Kinet. Katal. Lett, vol. 61, 111
Anić, S., Kolar-Anić, L. (1986) The oscillatory decomposition of H2O2 monitored by the potentiometric method with Pt and Ag+/S2- indicator electrodes. Ber. Bunsenges. Phys. Chem, vol. 90, 1084
Anić, S.R., Kolar-Anić, L. (1987) The influence of potassium iodate on hydrogen peroxide decomposition in Bray-Liebhafsky reaction. Berichte der Bunsen-Gesellschaft, 91(10): 1010-13
Anić, S.R., Stanisavljev, D.R., Čupić, Ž., Radenković, M.B., Vukojević, V.B., Kolar-Anić, Lj.Z. (1998) The selforganization phenomena during catalytic decomposition of hydrogen peroxide. Science of Sintering, vol. 30, str. 49-57
Anić, S.R., Kolar-Anić, L. (1986) Some new details the kinetic considerations of the oscillatory decomposition of hydrogen peroxide. Ber. Bunsenges. Phys. Chem, vol. 90, 539
Anić, S.R., Stanisavljev, D. (1996) Bray-Liebhafsky reaction, V: New kinetic data on low-acidity reaction systems. J. Serb. Chem. Soc, vol. 61, 121
Anić, S.R., Maksimović, J., Lončarević, D., Pejić, N.D., Čupić, Ž.D. (2009) Activity of polymer supported cobalt catalyst in the Bray-Liebhafsky oscillator. Russian journal of physical chemistry A, vol. 83, br. 9, str. 1468-1472
Anić, S.R., Kolar-Anić, L.Z. (1988) Kinetic aspects of the Bray-Liebhafsky oscillatory reaction. Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry in Condensed Phases, 84(10), 3413-21
Anić, S.R., Stanisavljev, D.R., Belovljev-Krnajski, G., Kolar-Anić, Lj.Z. (1989) Examination of the temperature variations on the Bray-Liebhafsky oscillatory reaction. Berichte der Bunsen-Gesellschaft, 93(4): 488-91
Anić, S.R., Vukojević, V.B., Radenković, M.B., Kolar-Anić, Lj.Z. (1989) New approach to the study of the peroxide kinetics of the Briggs-Rausher oscillatory reaction. Journal of the Serbian Chemical Society, vol. 54, str. 521-526
Anić, S.R., Kolar-Anić, Lj.Z., Stanisavljev, D.R., Begović, N., Mitić, D. (1991) Dilution reinitiated oscillations in the Bray-Liebhafsky system. Reaction Kinetics and Catalysis Letters, vol. 43, str. 155
Anić, S.R., Veselinović, D.S., Vukojević, V.B., Radenković, M.B. (1994) Electrochemical source of alternating current based on an oscillating reaction. Journal of the Serbian Chemical Society, vol. 59, str. 457-461
Begović, N., Marković, Z., Anić, S., Kolar-Anić, Lj. (2004) Computational Investigation of HIO and HIO2 Isomers. J. Phys. Chem. A, 651-657; 108
Belousov, B.P. (1981) A Periodic Reaction and Its Mechanism. in: Grecova M.T. [ed.] USSR Academy of Sciences, Gorky: Institute of Applied Physics, pp 176-186
Belousov, B.P. (1958) A Periodic Reaction and Its Mechanism. in: Sbornik Referatov po Radiatsionni Medetsine, Moscow
Belousov, B.P. (1985) A Periodic Reaction and Its Mechanism. in: Field R.J., Burger M. [ed.] Oscillations and Travelling Waves in Chemical Systems, New York: J. Wiley, pp 605-613
Blagojević, S.M., Anić, S.R., Čupić, Ž.D., Pejić, N.D., Kolar-Anić, Lj.Z. (2009) Temperature influence on the malonic acid decomposition in the Belousov-Zhabotinsky reaction. Russian Journal of Physical Chemistry A, 83(9): 1496-1501
Blagojević, S.M., Anić, S.R., Čupić, Ž.D. (2011) Influence of most important radicals on the numerically simulated belousov-zhabotinsky oscillatory reaction under batch conditions. Russian Journal of Physical Chemistry A, 85(13): 2274-2278
Blagojević, S.M., Anić, S.R., Čupić, Ž.D., Blagojević, S.N., Kolar-Anić, Lj.Z. (2013) Numerical evidence of complex nonlinear phenomena of the Belousov-Zhabotinsky oscillatory reaction under batch conditions. Russian Journal of Physical Chemistry A, 87(13): 2140-2145
Blagojević, S.N., Čupić, Ž., Ivanović-Šašić, A., Kolar-Anić, Lj. (2015) Mixed-mode oscillations and chaos in return maps of an oscillatory chemical reaction. Russian Journal of Physical Chemistry A, 89(13): 2349-2358
Blagojević, S., Pejić, N., Anić, S., Kolar-Anić, L. (2000) Belousov-Žabotinski oscilatorna reakcija - kinetika razlaganja malonske kiseline. Journal of the Serbian Chemical Society, vol. 65, br. 10, str. 709-713
Blagojević, S.M., Anić, S.R., Čupić, Ž.D., Pejić, N.D., Kolar-Anić, L.Z. (2008) Malonic acid concentration as a control parameter in the kinetic analysis of the Belousov–Zhabotinsky reaction under batch conditions. Physical Chemistry Chemical Physics, 10(44): 6658
Bray, W.C. (1921) Periodic reaction in homogeneous solution and its relation to catalysis. Journal of the American Chemical Society, 43, 1262-7
Bray, W.C., Liebhafsky, H.A. (1931) Reactions involving hydrogen peroxide, iodine and iodate ion. I. Introduction. Journal of the American Chemical Society, 53(1): 38-44
Briggs, T.S., Rausher, W.C. (1973) An oscillatory iodine clock. J Chem. Education, vol. 50, 496
Bubanja, I.N., Maćešić, S., Ivanović-Šašić, A., Čupić, Ž., Anić, S., Kolar-Anić, Lj. (2016) Intermittent chaos in the Bray–Liebhafsky oscillator. Temperature dependence. Phys. Chem. Chem. Phys., 18(14): 9770-9778
Čupić, Ž., Anić, S., Terlecki-Baričević, A., Kolar-Anić, Lj. (1995) The Bray-Liebhafsky reaction. Influence of some polymers based on poly (4-vinylpyridine). Reaction Kinetics & Catalysis Letters, 54(1): 43-49
Čupić, Ž., Anić, S., Mišljenović, Đ. (1996) The Bray-Liebhafsky Reaction. VII. Concentrations of the External Species H+ and IO3-. J. Serb. Chem. Soc., 893-902; 61
Čupić, Ž., Marković, V., Ivanović, A., Kolar-Anić, Lj. (2011) Modeling of the Complex Nonlinear Processes: Determination of the Instability Region by the Stoichiometric Network Analysis. in: Brennan Christopher R. [ed.] Mathematical Modelling, New York: Nova Science Publishers, pp. 111-178
Čupić, Ž., Schmitz, G., Kolar-Anić, Lj. (2016) Stoichiometric network analysis as mathematical method for examinations of instability region and oscillatory dynamics. Scientific Publications of the State University of Novi Pazar Series A: Applied Mathematics, Informatics and mechanics, vol. 8, br. 1, str. 43-64
Čupić, Ž., Ivanović-Šašić, A., Anić, S., Stanković, B., Maksimović, J., Kolar-Anić, L., Schmitz, G. (2013) Tourbillion in the phase space of the Bray-Liebhafsky nonlinear oscillatory reaction and related multiple-time-scale model. Communications in Mathematical and in Computer Chemistry / MATCH, vol. 69, br. 3, str. 805-830
Čupić, Ž., Ivanović-Šašić, A., Blagojević, S., Blagojević, S., Kolar-Anić, L., Anić, S. (2016) Return map analysis of the highly nonlinear Bray–Liebhafsky reaction model. Reaction Kinetics, Mechanisms and Catalysis, 118(1): 27-38
Čupić, Ž., Marković, V.M., Maćešić, S., Stanojević, A., Damjanović, S., Vukojević, V., Kolar-Anić, L. (2016) Dynamic transitions in a model of the hypothalamic-pituitary-adrenal axis. Chaos: An Interdisciplinary Journal of Nonlinear Science, 26(3): 033111
Čupić, Ž., Stanojević, A., Marković, V.M., Kolar-Anić, L., Terenius, L., Vukojević, V. (2016) The HPA axis and ethanol: a synthesis of mathematical modelling and experimental observations. Addiction Biology
Čupić, Ž.D., Kolar-Anić, L.Z., Anić, S.R., Maćešić, S.R., Maksimović, J.P., Pavlović, M.S., Milenković, M.C., Bubanja, I.N.M., Greco, E., Furrow, S.D., Cervellati, R. (2014) Regularity of Intermittent Bursts inBriggsRauscherOscillating Systems with Phenol. Helvetica Chimica Acta, 97(3): 321-333
Ćirić, J., Anić, S., Čupić, Ž., Kolar-Anić, L. (2000) The Bray-Liebhafsky oscillatory reaction: Kinetic investigations in reduction and oxidation pathways based on hydrogen peroxide concentration monitoring. Science of Sintering, vol. 32, br. 3, str. 187-196
Epstein, I.R., Pojman, J.A., Steinbock, O. (2006) Introduction: Self-organization in nonequilibrium chemical systems. Chaos: An Interdisciplinary Journal of Nonlinear Science, 16(3): 037101
Field, R.J., Burger, M., ur. (1985) Oscillation and traveling waves in chemical systems. New York, itd: Wiley
Field, R.J., Noyes, R.M. (1974) Oscillations in chemical systems. IV. Limit cycle behavior in a model of a real chemical reaction. Journal of Chemical Physics, 60(5): 1877-1884
Gray, P., Scott, S.K. (1986) A new model for oscillatory behaviour in closed systems: The autocatalator. Ber. Bunsenges. Phys. Chem, vol. 90, 985-996
Gray, P., Scott, S.K. (1990) Chemical oscillations and instabilities: Non-linear chemical kinetics. Oxford: Oxford University Press
Ivanović, A.Z., Čupić, Ž.D., Janković, M.M., Kolar-Anić, Lj.Z., Anić, S.R. (2008) The chaotic sequences in the Bray–Liebhafsky reaction in an open reactor. Physical Chemistry Chemical Physics, 10(38): 5848
Ivanović, A.Z., Čupić, Ž.D., Kolar-Anić, Lj.Z., Janković, M.M., Anić, S.R. (2009) Large deviation spectra of chaotic time series from Bray-Liebhafsky reaction. Russian Journal of Physical Chemistry A, 83(9): 1526-1530
Ivanović-Šašić, A.Z., Marković, V.M., Anić, S.R., Kolar-Anić, Lj.Z., Čupić, Ž.D. (2011) Structures of chaos in open reaction systems. Physical Chemistry Chemical Physics, 13(45): 20162
Jelic, S.Z., Cupic, Z.D., Kolar-Anic, L.Z., Vukojevic, V.B. (2009) Predictive Modeling of the Hypothalamic-Pituitary-Adrenal (HPA) Function. Dynamic Systems Theory Approach by Stoichiometric Network Analysis and Quenching Small Amplitude Oscillations. International Journal of Nonlinear Sciences and Numerical Simulation, vol. 10, br. 11-12, str. 1451-1472
Jelić, S., Čupić, Ž., Kolar-Anić, Lj. (2008) Chapter XIII - Modelling of the Hypothalamic-Pituitary-Adrenal System Activity Based on the Stoichiometric Analysis. in: Romano Elissa, de Luca Sara [ed.] New Research on Neurosecretory Systems, Hauppauge NY: Nova Science Publishers, pp. 225-245
Kolar-Anic, L.Z., Cupic, Z.D., Schmitz, G., Anic, S.R. (2010) Improvement of the stoichiometric network analysis for determination of instability conditions of complex nonlinear reaction systems. Chemical Engineering Science, vol. 65, br. 12, str. 3718-3728
Kolar-Anić, Lj., Čupić, Ž., Anić, S., Pejić, N., Vukojević, V. (2017) Complex Reaction Systems. in: Wang Z. [ed.] Encyclopaedia of Physical Organic Chemistry, Wiley, 6 Volume Set; Chapter 21.5.; ISBN: 978-1-118-47045-9
Kolar-Anić, Lj., Čupić, Ž., Anić, S., Blagojević, S., Vukojević, V. (2017) Self-organizing Phenomena in Chemistry, Physical Chemistry and Biology. in: Wang Z. [ed.] Encyclopaedia of Physical Organic Chemistry, Wiley, 6 Volume Set; Chapter 21.6.; ISBN: 978-1-118-47045-9
Kolar-Anić, Lj., Grozdić, T., Vukojević, V., Schmitz, G., Anić, S. (2004) Simulations of Complex Oscillations based on a Model of the Bray-Liebhafsky reaction. in: Anić S., Čupić Ž., Kolar-Anić Lj. [ed.] Selforganization in Nonequilibrium Systems, Belgrade: SPCS, pp 115-118
Kolar-Anić, Lj., Vukojević, V., Pejić, N., Grozdić, T., Anić, S. (2004) Deterministic Chaos in Open Well-stirred Bray-Liebhafsky Reaction System, Experimental Chaos. in: Boccaletti S, Gluckman B J, Kurths J, Pecora L, Meucci R and Yordanov Q [ed.] AIP Conference Proceedings, 742, 3-8
Kolar-Anić, Lj., Čupić, Ž., Anić, S., Pejić, N., Ivanović-Šašić, A., Vukojević, V. (2017) Methods for the Examination of Kinetics of Oscillatory Reactions. in: Wang Z. [ed.] Encyclopaedia of Physical Organic Chemistry, Wiley, 6 Volume Set; Chapter 21.6.; ISBN: 978-1-118-47045-9
Kolar-Anić, Lj., Čupić, Ž., Anić, S., Blagojević, S., Ivanović-Šašić, A., Vukojević, V. (2017) Models of Oscillatory Reactions. in: Encyclopaedia of Physical Organic Chemistry, Wiley, 6 Volume Set; ISBN: 978-1-118-47045-9
Kolar-Anić, L., Blagojević, S., Pejić, N., Begović, N., Blagojević, S., Anić, S. (2006) New evidence of transient complex oscillations in a closed, well-stirred belousov-zhabotinsky system. Journal of the Serbian Chemical Society, vol. 71, br. 6, str. 605-612
Kolar-Anić, L.Z., Schmitz, G. (1992) Mechanism of the Bray-Liebhafsky reaction: Effect of the oxidation of iodous acid by hydrogen peroxide. Journal of the Chemical Society Faraday Transactions, vol. 88 (16), str. 2343-2349
Kolar-Anić, L.Z., Mišljenović, Đ.M., Anić, S.R., Nicolis, G. (1995) Influence of the reduction of iodate ion by hydrogen peroxide on the model of the Bray-Liebhfasky reaction. Reaction Kinetics and Catalysis Letters, vol. 54, str. 35-41
Kolar-Anić, L., Vukelić, N., Mišljenović, Đ., Anić, S. (1995) On the instability domains of some models for the Bray-Liebhafsky oscillatory reaction. J. Serb. Chem. Soc, vol. 60, 1005
Lefever, R., Nicolis, G., Borckmans, P. (1988) The brusselator: it does oscillate all the same. Journal of the Chemical Society, Faraday Transactions 1: Physical Chemistry in Condensed Phases, 84(4): 1013
Liebhafsky, H.A. (1932) Tha Rate of Oxidation, in Acid Solution, of Hydrogen Peroxide by Iodine. Journal of American Chemical Society, 3504-3508; 54
Liebhafsky, H.A. (1931) Reactions involving hydrogen peroxide, iodine and iodate ion. Iii. The reduction of iodate ion by hydrogen peroxide. Journal of the American Chemical Society, 53(3): 896-911
Liebhafsky, H.A. (1931) Reactions involving hydrogen peroxide, iodine and iodate ion. Iv. The oxidation of iodine to iodate ion by hydrogen peroxide. Journal of the American Chemical Society, 53(6): 2074-2090
Liebhafsky, H.A. (1932) The catalytic decomposition of hydrogen peroxide by the iodine-iodide couple. Ii and iii. The rate of oxidation in neutral, and in acid, solution of hydrogen peroxide by iodine. Journal of the American Chemical Society, 54(9): 3499-3508
Liebhafsky, H.A., Mohammad, A. (1933) The Kinetics of the Reduction, in Acid Solution, of Hydrogen Peroxide by Iodide Ion. Journal of the American Chemical Society, 55(10): 3977-3986
Liebhafsky, H.A. (1934) The Catalytic Decomposition of Hydrogen Peroxide by the Iodine—Iodide Couple. IV. The Approach to the Steady State1. Journal of the American Chemical Society, 56(11): 2369-2372
Lotka, A.J. (1925) Elements of Physical Biology. Baltimore, USA: Williams and Wilkins
Lotka, A.J. (1909) Contribution to the Theory of Periodic Reactions. Journal of Physical Chemistry, 14(3): 271-274
Lotka, A.J. (1920) Analytical Note on Certain Rhythmic Relations in Organic Systems. Proceedings of the National Academy of Sciences, 6(7): 410-415
Lotka, A.J. (1920) Undamped oscillations derived from the law of mass action. Journal of the American Chemical Society, 42(8): 1595-1599
Maćešić, S., Čupić, Ž., Anić, S., Kolar-Anić, L. (2015) Autocatalator as the source of instability in the complex non-linear neuroendocrine model. International Journal of Non-Linear Mechanics, 73: 25-30
Maćešić, S., Čupić, Ž., Kolar-Anić, L. (2012) Model of a nonlinear reaction system with autocatalysis and autoinhibition: Stability of dynamic states. Hemijska industrija, vol. 66, br. 5, str. 637-646
Maćešić, S., Čupić, Ž., Kolar-Anić, L. (2016) Bifurcation analysis of the reduced model of the Bray–Liebhafsky reaction. Reaction Kinetics, Mechanisms and Catalysis, 118, 39-55
Maćešić, S.R., Čupić, Ž.D., Blagojević, S.M., Pejić, N.D., Anić, S.R., Kolar-Anić, L.Z. (2014) Current rates and reaction rates in the Stoichiometric Network Analysis (SNA). Open Chemistry, 13(1): 591-599
Maksimović, J.P., Čupić, Ž.D., Lončarević, D., Pejić, N., Vasiljević-Radović, D., Anić, S. (2011) Kinetics of the Bray-Liebhafsky oscillatory reaction perturbed by polymer supported cobalt catalyst. Science of Sintering, vol. 43, br. 1, str. 55-62
Markovic, V.M., Cupic, Z., Vukojevic, V., Kolar-Anic, L. (2011) Predictive modeling of the hypothalamic-pituitary-adrenal (HPA) axis response to acute and chronic stress. Endocrine Journal, 58(10): 889-904
Marković, V.M., Čupić, Ž., Ivanović, A., Kolar-Anić, Lj. (2011) The stability of the extended model of hypothalamic-pituitary-adrenal axis examined by stoichiometric network analysis. Russian Journal of Physical Chemistry A, 85(13): 2327-2335
Marković, V.M., Čupić, Ž., Maćešić, S., Stanojević, A., Vukojević, V., Kolar-Anić, L. (2014) Modelling cholesterol effects on the dynamics of the hypothalamic–pituitary–adrenal (HPA) axis. Mathematical Medicine and Biology, 33(1): 1-28
Milenković, M.C., Stanisavljev, D.R. (2012) Role of Free Radicals in Modeling the Iodide–Peroxide Reaction Mechanism. Journal of Physical Chemistry A, 116(23): 5541-5548
Nicholis, G., Prigogine, I. (1977) Self-organization in non-equilibrium systems. New York, itd: Wiley-Interscience
Nicolis, G., Prigogine, I. (1989) Exploring Complexity. New York, NY: Freeman
Nicolis, G. (1995) Introduction to nonlinear science. Cambridge: Cambridge University Press
Pejic, N.D., Maksimovic, J.P., Ribic, D.D., Kolar-Anic, L.Z. (2009) Dynamic states of the Bray-Liebhafsky reaction when sulfuric acid is the control parameter. Russian Journal of Physical Chemistry A, vol. 83, br. 9, str. 1490-1495
Pejić, N., Vujković, M., Maksimović, J., Ivanović, A., Anić, S., Čupić, Ž., Kolar-Anić, Lj. (2011) Dynamic behavior of the bray-liebhafsky oscillatory reaction controlled by sulfuric acid and temperature. Russian Journal of Physical Chemistry A, 85(13): 2310-2316
Pejić, N., Čupić, Ž., Anić, S., Vukojević, V., Kolar-Anić, L. (2001) The oscillatory Bray-Liebhafsky reaction as a matrix for analyzing enzyme and polymeric catalysts for hydrogen peroxide. Science of Sintering, vol. 33, br. 2, str. 107-115
Pejić, N.D., Blagojević, S.M., Anić, S.R., Vukojević, V.B., Mijatović, M.D., Ćirić, J.S., Marković, Z.S., Marković, S.D., Kolar-Anić, L.Z. (2007) Kinetic determination of morphine by means of Bray-Liebhafsky oscillatory reaction system using analyte pulse perturbation technique. Analytica chimica acta, vol. 582, br. 2, str. 367-374
Pejić, N., Blagojević, S., Anić, S., Kolar-Anić, L. (2007) Determination of ascorbic acid in pharmaceutical dosage forms and urine by means of an oscillatory reaction system using the pulse perturbation technique. Analytical and bioanalytical chemistry, 389(6): 2009-17
Pejić, N., Kolar-Anić, L., Anić, S., Stanisavljev, D. (2006) Determination of paracetamol in pure and pharmaceutical dosage forms by pulse perturbation technique. Journal of pharmaceutical and biomedical analysis, 41(2): 610-5
Pejić, N.D., Anić, S.R., Kuntić, V.S., Vukojević, V.B., Kolar-Anić, L.Z. (2003) Kinetic determination of microquantities of rutin by perturbation of the Bray-Liebhafsky oscillatory reaction in an open system. Microchimica acta, vol. 143, br. 4, str. 261-267
Pejić, N., Blagojević, S., Anić, S., Vukojević, V., Kolar-Anić, L. (2005) Microquantitative determination of hesperidin by pulse perturbation of the oscillatory reaction system. Analytical and Bioanalytical Chemistry, 381(3): 775-780
Pejić, N., Sarap, N., Maksimović, J., Anić, S., Kolar-Anić, L. (2013) Pulse perturbation technique for determination of piroxicam in pharmaceuticals using an oscillatory reaction system. Open Chemistry, 11(2): 180-188
Pejić, N., Kolar-Anić, L., Maksimović, J., Janković, M., Vukojević, V., Anić, S. (2016) Dynamic transitions in the Bray–Liebhafsky oscillating reaction. Effect of hydrogen peroxide and temperature on bifurcation. Reaction Kinetics, Mechanisms and Catalysis, 118(1): 15-26
Pejić, N.D., Blagojević, S.M., Sarap, N.B., Maksimović, J.P., Anić, S.R., Čupić, Ž.D., Kolar-Anić, L.Z. (2014) Pertubation od the Duschman Reaction with Piroxicam: Experimantal and Model Calculations. Helvetica Chimica Acta, 97(1): 47-55
Pejić, N.D., Blagojević, S.M., Sarap, N.B., Maksimović, J.P., Anić, S.R., Čupić, Ž.D., Kolar-Anić, L.Z. (2014) Perturbations of theDushmanReaction with Piroxicam: Experimental and Model Calculations. Helvetica Chimica Acta, 97(1): 47-55
Pejić, N.D., Blagojević, S.M., Vukelić, J., Kolar-Anić, L.Z., Anić, S.R. (2007) Analyte pulse perturbation technique for the determination of 6-O-acetylmorphine in seized street drug samples. Bulletin of the chemical society of Japan, vol. 80, br. 10, str. 1942-1948
Pejić, N.D., Maksimović, J.P., Blagojević, S.M., Anić, S.R., Čupić, Ž.D., Kolar-Anić, L.Z. (2012) Kinetic analytical method for determination of uric acid in human urine using analyte pulse perturbation technique. Journal of the Brazilian Chemical Society, 23, 1450-1459
Prigogine, I. (1977) Time, Structure and Fluctuations: Nobel Lecture in chemistry. 263-285; Chemistry
Radenković, M., Schmitz, G., Kolar-Anić, L. (1997) Simulation of iodine oxidation by hydrogen peroxide in acid media, on the basis of the model of Bray-Liebhafsky reaction. Journal of the Serbian Chemical Society, 62(4): 367-369
Schmitz, G., Kolar-Anić, Lj., Anić, S., Čupić, Z. (2000) The Illustration of Multistability. J. Chem. Education, 77, 1502-1505
Schmitz, G. (1987) Cinétique de la réaction de Bray. J Chem. Phys, vol. 84, 957
Schmitz, G., Kolar-Anić, L., Anić, S., Grozdić, T., Vukojević, V. (2006) Complex and Chaotic Oscillations in a Model for the Catalytic Hydrogen Peroxide Decomposition under Open Reactor Conditions. Journal of Physical Chemistry A, 110(34): 10361-10368
Schmitz, G., Kolar-Anić, L.Z., Anić, S.R., Čupić, Z.D. (2008) Stoichiometric Network Analysis and Associated Dimensionless Kinetic Equations. Application to a Model of the Bray−Liebhafsky Reaction. Journal of Physical Chemistry A, 112(51): 13452-13457
Scott, S.K. (1987) Oscillations in simple models of chemical systems. Accounts of Chemical Research, 20(5): 186-191
Stanisavljev, D., Vukojević, V. (1995) Thermochemical Effects Accompanying Oscillations in the Bray-Liebhafsky Reaction. J. Serb. Chem. Soc., 1125-1334; 60
Stanisavljev, D. (1997) Consideration of the thermodynamic stability of iodine species in the Bray-Liebhafsky reaction. Berichte der bunsen-gesellschaft, 101(7): 1036-1039
Stanisavljev, DR., Djordjevic, AR., Likar-Smiljanic, VD. (2006) Microwaves and coherence in the Bray-Liebhafsky oscillatory reaction. Chemical Physics Letters, vol. 423, br. 1-3, str. 59-62
Stanisavljev, D.R., Grozdić, T.D., Kaninski, M.P. M., Djordjević, A.R., Stojić, D.Lj. (2007) The microwave influence on the electrolytic decomposition of KOH water solution. Electrochemistry Communications, 9(5): 901-904
Stanisavljev, D.R., Dramićanin, M.D. (2007) Excessive Excitation of Hydrogen Peroxide during Oscillatory Chemical Evolution. Journal of Physical Chemistry A, 111(32): 7703-7706
Stanisavljev, D.R., Milenković, M.C., Mojović, M.D., Popović-Bijelić, A.D. (2011) Oxygen Centered Radicals in Iodine Chemical Oscillators. Journal of Physical Chemistry A, 115(27): 7955-7958
Stanisavljev, D.R., Velikić, Z., Veselinović, D.S., Jacić, N.V., Milenković, M.C. (2014) Bray–Liebhafsky oscillatory reaction in the radiofrequency electromagnetic field. Chemical Physics, 441: 1-4
Stanisavljev, D., Begović, N., Vukojević, V. (1998) Influence of Heavy Water on the Bray−Liebhafsky Oscillating Reaction. Journal of Physical Chemistry A, 102(35): 6887-6891
Stanisavljev, D.R., Vukojević, V.B. (2002) Investigation of the Influence of Heavy Water on Kinetic Pathways in the Bray−Liebhafsky Reaction. Journal of Physical Chemistry A, 106(23): 5618-5625
Stanisavljev, D.R., Djordjević, A.R., Likar-Smiljanić, V.D. (2004) Microwave Driven Bray–Liebhafsky Oscillatory Reaction. ChemPhysChem, 5(1): 140-144
Stanisavljev, D.R., Djordjević, A.R., Likar-Smiljanić, V.D. (2005) Investigation of microwave effects on the oscillatory Bray–Liebhafsky reaction. Chemical Physics Letters, 412(4-6): 420-424
Stanisavljev, D., Begović, N., Žujović, Z., Vučelić, D., Bačić, G. (1998) 1H NMR Monitoring of Water Behavior during the Bray−Liebhafsky Oscillatory Reaction. Journal of Physical Chemistry A, 102(35): 6883-6886
Stanković, B., Čupić, Ž., Pejić, N., Kolar-Anić, L. (2013) Numerical Study on Bray-Liebhafsky Oscillatory Reaction: Bifurcations. Journal of Applied Nonlinear Dynamics, 2(3): 285-301
Stanković, B., Čupić, Ž., Maćešić, S., Pejić, N., Kolar-Anić, L. (2016) Complex bifurcations in the oscillatory reaction model. Chaos, Solitons & Fractals, 87: 84-91
Stávek, J., Šı́pek, M., Šesták, J. (2002) The application of the principle of least action to some self-organized chemical reactions. Thermochimica Acta, 388(1-2): 441-450
Terlecki-Baričević, A., Čupić, Ž., Anić, S., Kolar-Anić, L., Mitrovski, S., Ivanović, S. (1995) Polyvinylpyridine supported iron(III) catalysts for hydrogen peroxide decomposition. Journal of the Serbian Chemical Society, vol. 60, str. 969-979
Volterra, V. (1926) Fluctuations in the Abundance of a Species considered Mathematically. Nature, 118(2972): 558-560
Vukojević, V.B., Pejić, N.D., Stanisavljev, D.R., Anić, S.R., Kolar-Anić, L.Z. (1999) Determination of Cl−, Br−, I−, Mn2+, malonic acid and quercetin by perturbation of a non-equilibrium stationary state in the Bray–Liebhafsky reaction. Analyst, 124(2): 147-152
Vukojević, V.B., Anić, S.R., Kolar-Anić, Lj.Z. (2000) Investigation of dynamic behavior of the Bray-Liebhafsky reaction in the CSTR. Determination of bifurcation points. Journal of Physical Chemistry A, vol. 104, br. 46, str. 10731-10739
Vukojević, V.B., Pejić, N.D., Stanisavljev, D.R., Anić, S.R., Kolar-Anić, Lj.Z. (2001) Micro-quantitative determination of quercetin by perturbation of a non-equilibrium stationary state in the Bray-Liebhafsky reaction system. Pharmazie, vol. 56, br. 11, str. 897-898
Vukojević, V.B., Anić, S.R., Kolar-Anić, L.Z. (2002) Investigation of dynamic behavior of the Bray-Liebhafsky reaction in the CSTR. Properties of the system examined by pulsed perturbations with I-. Physical Chemistry Chemical Physics, vol. 4, br. 8, str. 1276-1283
Wang, Z. Organic Chemistry. Wiley, 6 Volume Set, Chapter 21.6
Winfree, A.T. (1984) The prehistory of the Belousov-Zhabotinsky oscillator. Journal of Chemical Education, 61(8): 661
Zhabotinskii, A.M. (1964) Periodic process of the oxidation of malonic acid in solution (study of kinetics of Belousov's reaction). Biofizika, 9(3), 306-11
Zhabotinsky, A.M. (1991) A history of chemical oscillations and waves. Chaos: An Interdisciplinary Journal of Nonlinear Science, 1(4): 379-386