A new approach to the phenomena at the interfaces of finely dispersed systems
Само за регистроване кориснике
2007
Чланак у часопису (Објављена верзија)
Метаподаци
Приказ свих података о документуАпстракт
A new idea has been applied for the elucidation of the electron and momentum transfer phenomena, at both rigid and deformable interfaces, in finely (micro-, nano-, atto-) dispersed systems. The electroviscoelastic behavior of, e.g., liquid/liquid interfaces (emulsions and double emulsions), is based on three forms of "instabilities"; these are rigid, elastic, and plastic. The events are understood as interactions between the internal (immanent) and external (incident) periodical physical fields. Since the events at the interfaces of finely dispersed systems must be considered at the molecular, atomic, and/or entities level it is inevitable to introduce the electron transfer phenomenon beside the classical heat, mass, and momentum transfer phenomena commonly used in chemical engineering. Therefore, an entity can be defined as the smallest indivisible element of matter that is related to the particular transfer phenomena. Hence, the entity can be either differential element of mass/demon..., ion, phonon as quanta of acoustic energy, infon as quanta of information, photon, and electron. Three possible mathematical formalisms have been derived and discussed related to this physical formalism, i.e., to the developed theory of electroviscoelasticity. The first is the stretching tensor model, where the normal and tangential forces are considered, only in mathematical formalism, regardless of their origin (mechanical and/or electrical). The second is the classical integer-order van der Pol derivative model. Finally, the third model comprises an effort to generalize the previous van der Pol differential equations, both linear and nonlinear, where the ordinary time derivatives and integrals are replaced by corresponding fractional-order time derivatives and integrals of order p lt 2 (p = n-delta, n = 1, 2, delta lt lt 1). In order to justify and corroborate a more general approach the obtained calculated results were compared to those experimentally measured using the representative liquid/liquid system.
Кључне речи:
predictor-corrector method / numerical evaluation / fractional-order model / finely dispersed systems / emulsions / electroviscoelasticity / electron transfer phenomena / electrified liquid/liquid interfaces / double emulsions / asymptotic expansionИзвор:
Journal of Colloid and Interface Science, 2007, 316, 2, 984-995Издавач:
- Academic Press Inc Elsevier Science, San Diego
Финансирање / пројекти:
- Фини дисперзни системи: микро-, нано-, ато-инжењерство (RS-MESTD-MPN2006-2010-142034)
DOI: 10.1016/j.jcis.2007.07.051
ISSN: 0021-9797
PubMed: 17727876
WoS: 000250987500091
Scopus: 2-s2.0-35648995944
Колекције
Институција/група
Mašinski fakultetTY - JOUR AU - Spasić, Aleksandar M. AU - Lazarević, Mihailo PY - 2007 UR - https://machinery.mas.bg.ac.rs/handle/123456789/719 AB - A new idea has been applied for the elucidation of the electron and momentum transfer phenomena, at both rigid and deformable interfaces, in finely (micro-, nano-, atto-) dispersed systems. The electroviscoelastic behavior of, e.g., liquid/liquid interfaces (emulsions and double emulsions), is based on three forms of "instabilities"; these are rigid, elastic, and plastic. The events are understood as interactions between the internal (immanent) and external (incident) periodical physical fields. Since the events at the interfaces of finely dispersed systems must be considered at the molecular, atomic, and/or entities level it is inevitable to introduce the electron transfer phenomenon beside the classical heat, mass, and momentum transfer phenomena commonly used in chemical engineering. Therefore, an entity can be defined as the smallest indivisible element of matter that is related to the particular transfer phenomena. Hence, the entity can be either differential element of mass/demon, ion, phonon as quanta of acoustic energy, infon as quanta of information, photon, and electron. Three possible mathematical formalisms have been derived and discussed related to this physical formalism, i.e., to the developed theory of electroviscoelasticity. The first is the stretching tensor model, where the normal and tangential forces are considered, only in mathematical formalism, regardless of their origin (mechanical and/or electrical). The second is the classical integer-order van der Pol derivative model. Finally, the third model comprises an effort to generalize the previous van der Pol differential equations, both linear and nonlinear, where the ordinary time derivatives and integrals are replaced by corresponding fractional-order time derivatives and integrals of order p lt 2 (p = n-delta, n = 1, 2, delta lt lt 1). In order to justify and corroborate a more general approach the obtained calculated results were compared to those experimentally measured using the representative liquid/liquid system. PB - Academic Press Inc Elsevier Science, San Diego T2 - Journal of Colloid and Interface Science T1 - A new approach to the phenomena at the interfaces of finely dispersed systems EP - 995 IS - 2 SP - 984 VL - 316 DO - 10.1016/j.jcis.2007.07.051 ER -
@article{ author = "Spasić, Aleksandar M. and Lazarević, Mihailo", year = "2007", abstract = "A new idea has been applied for the elucidation of the electron and momentum transfer phenomena, at both rigid and deformable interfaces, in finely (micro-, nano-, atto-) dispersed systems. The electroviscoelastic behavior of, e.g., liquid/liquid interfaces (emulsions and double emulsions), is based on three forms of "instabilities"; these are rigid, elastic, and plastic. The events are understood as interactions between the internal (immanent) and external (incident) periodical physical fields. Since the events at the interfaces of finely dispersed systems must be considered at the molecular, atomic, and/or entities level it is inevitable to introduce the electron transfer phenomenon beside the classical heat, mass, and momentum transfer phenomena commonly used in chemical engineering. Therefore, an entity can be defined as the smallest indivisible element of matter that is related to the particular transfer phenomena. Hence, the entity can be either differential element of mass/demon, ion, phonon as quanta of acoustic energy, infon as quanta of information, photon, and electron. Three possible mathematical formalisms have been derived and discussed related to this physical formalism, i.e., to the developed theory of electroviscoelasticity. The first is the stretching tensor model, where the normal and tangential forces are considered, only in mathematical formalism, regardless of their origin (mechanical and/or electrical). The second is the classical integer-order van der Pol derivative model. Finally, the third model comprises an effort to generalize the previous van der Pol differential equations, both linear and nonlinear, where the ordinary time derivatives and integrals are replaced by corresponding fractional-order time derivatives and integrals of order p lt 2 (p = n-delta, n = 1, 2, delta lt lt 1). In order to justify and corroborate a more general approach the obtained calculated results were compared to those experimentally measured using the representative liquid/liquid system.", publisher = "Academic Press Inc Elsevier Science, San Diego", journal = "Journal of Colloid and Interface Science", title = "A new approach to the phenomena at the interfaces of finely dispersed systems", pages = "995-984", number = "2", volume = "316", doi = "10.1016/j.jcis.2007.07.051" }
Spasić, A. M.,& Lazarević, M.. (2007). A new approach to the phenomena at the interfaces of finely dispersed systems. in Journal of Colloid and Interface Science Academic Press Inc Elsevier Science, San Diego., 316(2), 984-995. https://doi.org/10.1016/j.jcis.2007.07.051
Spasić AM, Lazarević M. A new approach to the phenomena at the interfaces of finely dispersed systems. in Journal of Colloid and Interface Science. 2007;316(2):984-995. doi:10.1016/j.jcis.2007.07.051 .
Spasić, Aleksandar M., Lazarević, Mihailo, "A new approach to the phenomena at the interfaces of finely dispersed systems" in Journal of Colloid and Interface Science, 316, no. 2 (2007):984-995, https://doi.org/10.1016/j.jcis.2007.07.051 . .