ORALS
SESSION:
EnergyMonPM2-R11
| Mauntz International Symposium (7th Intl. Symp. on Sustainable Energy Production: Fossil; Renewables; Nuclear; Waste handling , processing, & storage for all energy production technologies; Energy conservation) |
| Mon. 28 Nov. 2022 / Room: Game | |
| Session Chairs: Leo Eskin; Session Monitor: TBA |
17:10: [EnergyMonPM212] OS
Some of the Basic Aspects of Transition State Theory (TST) of Bimolecular Reaction Rates Revisited with an Input From Nonequilibrium Thermodynamics Anil A.
Bhalekar1 ; Bjarne
Andresen
2 ;
1Department of Chemistry, R. T. M. Nagpur University, NAGPUR, India;
2University of Copenhagen, COPENHAGEN, Denmark;
Paper Id: 133
[Abstract] In view of the prevailing over skepticism about the sound thermodynamic base of the expression of the rate constant given by the traditional transition state theory (TST) of bimolecular reactions, its foundational ingredients are revisited in this paper. The inference drawn earlier of the existence of <i><i>quasiequilibrium</i></i> between the reactants and activated complexes has been properly amended. The need for this has been elucidated by showing that the use of <i>quasiequilibrium</i> amounts to use it as a pre-equilibrium step hence it implies that the conversion of activated complexes to the product molecules must be a slow step according to the basic principles of chemical kinetics. However, it has been demonstrated that the existence time of an activated complex is less than the time required to complete half of the molecular vibration of the activated complex. Which means they are highly reactive ones. Therefore, it is not the case of <i>pre-equilibrium </i>but, indeed, is the case of a steady state for the forward moving activated complexes, which is what Arnot had advocated earlier. However, we have demonstrated that the said steady state for the concentration of the forward moving activated complexes is a case of <i>dynamic chemical equilibrium</i> between the reactants and the forward moving activated complexes whose sound thermodynamic base has been elucidated by describing the corresponding nonequilibrium thermodynamics. Thus, the much-needed description of the thermodynamic base of TST given expression of the rate constant has been accomplished.
References:
<b>Bibliography</b>\n1. A. A. Bhalekar, Nonequilibrium thermodynamics of dynamic chemical equilibria, (Preceding Paper) (2020)\n2. H. Eyring, Activated Complex in Chemical Reactions, <i>J. Chem. Phys.</i>, 3, 107-115 (1935).\n3. M. G. Evans and M. Polanyi, Some applications of the transition state method to the calculation of reaction velocities, especially in solution, <i>Trans. Faraday Soc.</i>, 31, 875-894 (1935)\n4. S. Glasstone, K. J. Laidler, and H. Eyring, <i>Theory of Rate Processes</i>, McGraw-Hill, New York, 1941\n5. K. J. Laidler and J. C. Polanyi, <i>Theories of the Kinetics of Bimolecular Reactions</i>, Vol 3, of <i>Progress in Reaction Kinetics</i>, ch. 1, Pergomon Press, London, 1965\n6. K. J. Laidler and M. C. King, The development of transition-state theory, <i>J. Phys. Chem.</i>, 87, 2657-2664 (1983)\n7. C. L. Arnot, Activated complex theory of bimolecular gas reactions, <i>J. Chem. Educ.</i>, 49, 480-482 (1972)\n8. I. Prigogine and R. Defay, <i>Chemical Thermodynamics</i>, D. H. Everett, Transl., Longmans-Green, London, 1954\n9. A. A. Bhalekar, The transition state theory of bimolecular reaction rates via the Bodenstein steady state for activated complexes, <i>CACAA</i>, 4, 309-340 (2015)
17:35 Break
SESSION:
EnergyMonPM3-R11
| Mauntz International Symposium (7th Intl. Symp. on Sustainable Energy Production: Fossil; Renewables; Nuclear; Waste handling , processing, & storage for all energy production technologies; Energy conservation) |
| Mon. 28 Nov. 2022 / Room: Game | |
| Session Chairs: Greg Baiden; Session Monitor: TBA |
17:50: [EnergyMonPM313] OS
A Revisit to the Local Thermodynamic Equilibrium Assumption of Nonequilibrium Thermodynamics Anil A.
Bhalekar1 ; Bjarne
Andresen
2 ;
1Department of Chemistry, R. T. M. Nagpur University, NAGPUR, India;
2University of Copenhagen, COPENHAGEN, Denmark;
Paper Id: 175
[Abstract] The global level thermodynamic comprehension of the local thermodynamic equilibrium assumption of nonequilibrium thermodynamics is presented. How the Gibbs relation given by equilibrium thermodynamics also describes a passage on an irreversible path is demonstrated at the global thermodynamic level. Specifically it has been demonstrated that the Gibbs relation indeed also takes care of irreversibility for a spatially uniform system with internal source of irreversibility for example the chemical reactions at non-vanishing rates and the irreversibility originating in the gradients of intensities across the boundary of the system. Hence, thermodynamic functions appearing in Gibbs relation are those for equilibrium and nonequilibrium states. The former is the case when it is used to describe a passage through the succession of equilibrium states and the latter is the case while describing the the passage through the succession of nonequilibrium states, i.e. on irreversible trajectories. Thereby, it gets demonstrated that the scope of validity of the local thermodynamic equilibrium assumption of nonequilibrium thermodynamics is much wider than it has been understood so far.
References:
Bibliography:\n[1] S. R. De Groot and P. Mazur, Non-Equilibrium Thermodynamics. Amsterdam: North Holland, 1962.\n[2] R. Clausius, The Mechanical Theory of Heat. London: Macmillan & Co., 1879. Translated by W. R. Browne.\n[3] H. A. Bumstead and R. G. V. Name, eds., The Scientific Papers of J. Willard Gibbs, vol. I. Thermodynamics. London and Bombay: Longmas, Green and Company, 1906.\n[5] J. N. Brønsted, “On the concept of heat,” Det. Kgl. Danske Videnskab. Seleskab. Math-Fys. Medd., vol. 19(8) (1941) 1 – 79.\n[6] I. Prigogine and R. Defay, Chemical Thermodynamics. London: Longmans Green, 1954. Translated by D. H. Everett.\n[7] B. C. Eu, “Form of uncompensated heat giving rise to a pfaffian differential form in thermodynamic space,” Phys. Rev. E, 51 (1995) 768 – 771.\n[8] A. A. Bhalekar, “Irreversible thermodynamic framework using compatible equations from thermodynamics and fluid dynamics. A second route to generalized phenomenological irreversible thermodynamic theory (GPITT),” Bull. Cal. Math. Soc., 94(2) (2002) 209 – 224. \nNote: This abstract is dedicated to Prof. Ferid Murad, Nobel Laureate in Medicine and the Symbol of Unified Science.
