Mean-field cooperativity in chemical kinetics

Biasio, Aldo Di; Agliari, Elena; Barra, Adriano; Burioni, Raffaella

doi:10.1007/s00214-012-1104-3

Cited by 20 publications

(25 citation statements)

References 23 publications

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“…In this way, for each experiment, once reached the chemical equilibrium, we get a saturation level and we can draw a point in the considered Cartesian plane; interpolating between all the points a sigmoidal curve will emerge (see Figure 1). Archibald V. Hill formulated a description for the behavior of with respect to : the so-called Hill equation empirically describes the fraction of molecules binding sites, occupied by the ligand, as a function of the ligand concentration [28][29][30][31]. This equation generalizes the Michaelis-Menten law (2) and reads as…”

Section: The Chemical Kineticsmentioning

confidence: 99%

“…In the following we summarize the minimal assumptions needed when modelling chemical kinetics from the Statistical Physics perspective; for a more extensive treatment of this kind of modelling we refer to [21,26,28,29,41], while for a rigorous explanation of the underlying equivalence between Statistical Mechanics and Analytical Mechanics we refer to the seminal works by Guerra [42], dealing with the Sherrington-Kirkpatrick model (and then deepened in, e.g., [43][44][45][46]), and by Brankov and Zagrebnov in [47], dealing with the Husimi-Temperley model (and then deepened in, e.g., [48][49][50][51] …”

Section: Formulation Of the Problem: The Thermodynamical Freementioning

confidence: 99%

“…This is a standard assumption in Chemical Kinetics [29,31,52] and it means that the diffusion of the ligands is fast enough to ensure a homogeneous solution. The concentration of free ligands is mapped into a one-body contribution 1 in the cost-function.…”

Section: Constitutes the First Bridge Between The Chemistry We Aim Tomentioning

confidence: 99%

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Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

et al. 2018

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Complex biochemical pathways can be reduced to chains of elementary reactions, which can be described in terms of chemical kinetics. Among the elementary reactions so far extensively investigated, we recall the Michaelis-Menten and the Hill positivecooperative kinetics, which apply to molecular binding and are characterized by the absence and the presence, respectively, of cooperative interactions between binding sites. However, there is evidence of reactions displaying a more complex pattern: these follow the positive-cooperative scenario at small substrate concentration, yet negative-cooperative effects emerge as the substrate concentration is increased. Here, we analyze the formal analogy between the mathematical backbone of (classical) reaction kinetics in Chemistry and that of (classical) mechanics in Physics. We first show that standard cooperative kinetics can be framed in terms of classical mechanics, where the emerging phenomenology can be obtained by applying the principle of least action of classical mechanics. Further, since the saturation function plays in Chemistry the same role played by velocity in Physics, we show that a relativistic scaffold naturally accounts for the kinetics of the above-mentioned complex reactions. The proposed formalism yields to a unique, consistent picture for cooperative-like reactions and to a stronger mathematical control.

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Section: The Chemical Kineticsmentioning

confidence: 99%

Section: Formulation Of the Problem: The Thermodynamical Freementioning

confidence: 99%

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Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

et al. 2018

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“…The study of diluted ferromagnets [1][2][3][4][5][6] dates back to several years ago, following two main paths sometimes overlapping, i.e. the statistical mechanics approach to lattices, and the graph theory approach to networks [7,8].…”

Section: Introductionmentioning

confidence: 99%

Dilution of Ferromagnets via a Random Graph‐Based Strategy

Javarone

Marinazzo

2018

Complexity

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The dynamics and behavior of ferromagnets have a great relevance even beyond the domain of statistical physics. In this work, we propose a Monte Carlo method, based on random graphs, for modeling their dilution. In particular, we focus on ferromagnets with dimension D ≥ 4, which can be approximated by the Curie-Weiss model. Since the latter has as graphic counterpart a complete graph, a dilution can be in this case viewed as a pruning process. Hence, in order to exploit this mapping, the proposed strategy uses a modified version of the Erdős-Renyi graph model. In doing so, we are able both to simulate a continuous dilution, and to realize diluted ferromagnets in one step. The proposed strategy is studied by means of numerical simulations, aimed to analyze main properties and equilibria of the resulting diluted ferromagnets. To conclude, we also provide a brief description of further applications of our strategy in the field of complex networks. *

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“…are ensembles of units able to organize spontaneously allowing order to arise starting from disordered configurations [30,36]. Synchrony has attracted much interest in the last decades due to its relevance in many different contexts as biology [3,25,12], chemistry [14], ecology [39], climatology [37], sociology [26], physics and engineering [34,38,42]. The fundamental features of all the mentioned examples are the presence of many objects -each of which is oscillating in a proper sense -and the phenomenon of mutual influence between oscillations.…”

Section: Introductionmentioning

confidence: 99%

Synchronization and Spin-Flop Transitions for a Mean-Field XY Model in Random Field

Collet

Ruszel

2016

J Stat Phys

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We characterize the phase space for the infinite volume limit of a ferromagnetic mean-field XY model in a random field pointing in one direction with two symmetric values. We determine the stationary solutions and detect possible phase transitions in the interaction strength for fixed random field intensity. We show that at low temperature magnetic ordering appears perpendicularly to the field. The latter situation corresponds to a spin-flop transition.

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Mean-field cooperativity in chemical kinetics

Cited by 20 publications

References 23 publications

Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

Complex Reaction Kinetics in Chemistry: A Unified Picture Suggested by Mechanics in Physics

Dilution of Ferromagnets via a Random Graph‐Based Strategy

Synchronization and Spin-Flop Transitions for a Mean-Field XY Model in Random Field

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