Enhancing the Kinetics of Self-oscillating Chemical Reactions via Catalytic Ceria Nanomats

Sharma, Vishesh; Dayal, Pratyush

doi:10.1021/acs.jpcc.0c04304

Cited by 4 publications

(3 citation statements)

References 49 publications

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“…The rate equations based on the above mechanism can be written as Here, the symbols k i ( i = 1, ..., 8) represent the rate constants of the respective forward reactions –R8; the negative subscript indicates the rate of the backward reaction. To capture the effect of the nanocatalyst concentration on the BZ kinetics, we assume that the catalyst affects step R5 only ,, and that no side/additional reactions take place in its presence. Thus, the rate constant in step R5 signifies the apparent rate constant ,, given as k 5 = k 50 [C] α e – E a / RT , where k 50 is the concentration/temperature-independent pre-exponential factor, E a is the activation energy of the nanocatalyst (Ru-GO, Ru-rGO, Ru-graphene), [C] is the concentration of Ru in the nanocatalyst, α is the order of the reaction, R is the gas constant, and T is the temperature.…”

Section: Methodsmentioning

confidence: 99%

“…To capture the effect of the nanocatalyst concentration on the BZ kinetics, we assume that the catalyst affects step R5 only ,, and that no side/additional reactions take place in its presence. Thus, the rate constant in step R5 signifies the apparent rate constant ,, given as k 5 = k 50 [C] α e – E a / RT , where k 50 is the concentration/temperature-independent pre-exponential factor, E a is the activation energy of the nanocatalyst (Ru-GO, Ru-rGO, Ru-graphene), [C] is the concentration of Ru in the nanocatalyst, α is the order of the reaction, R is the gas constant, and T is the temperature. Here, however, as the experiments are performed at a fixed concentration of nanocatalysts under isothermal conditions, the value of k 5 for Ru-GO, Ru-rGO, and Ru-graphene is used directly …”

Section: Methodsmentioning

confidence: 99%

“…In the absence of MO, the value of the rate constant in step R8-1 is taken as k 8 = 2.0 × 10 –2 s –1 . For the traditional solution-based catalyst, the value of k 5 = 1.18 M –1 s –1 , whereas the value of k 5 is taken as 2.0, 4.0, and 13.0 M –1 s –1 for Ru-GO, Ru-rGO, and Ru-graphene nanocatalysts, respectively.…”

Section: Methodsmentioning

confidence: 99%

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Fast-Moving Self-Propelled Droplets of a Nanocatalyzed Belousov–Zhabotinsky Reaction

2021

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Self-sustained locomotion by virtue of an internalized chemical reaction is a characteristic feature of living systems and has inspired researchers to develop such self-moving biomimetic systems. Here, we harness a self-oscillating Belousov–Zhabotinsky (BZ) reaction, a well-known chemical oscillator, with enhanced kinetics by virtue of our graphene-based catalytic mats, to elucidate the spontaneous locomotion of BZ reaction droplets. Specifically, our nanocatalysts comprise ruthenium nanoparticle decorations on graphene oxide, reduced graphene oxide, and graphene nanosheets, thereby creating 0D–2D heterostructures. We demonstrate that when these nanocatalyzed droplets of the BZ reaction are placed in an oil-surfactant medium, they exhibit a macroscopic translatory motion at the velocities of few millimeters per second. This motion is brought about by the combination of enhanced kinetics of the BZ reaction and the Marangoni effect. Our investigations reveal that the velocity of locomotion increases with the electrical conductivity of our nanocomposites. Moreover, we also show that the positive feedback generated by the reaction–diffusion phenomena results in an asymmetric distribution of surface tension that, in turn, facilitates the self-propelled motion of the BZ droplets. Finally, we explore a system of multiple nanocatalyzed BZ droplets and reveal a variety of motions caused by their mutual interactions. Our findings suggest that through the use of 0D–2D hybrid nanomaterials, it is possible to design fast-moving self-propelled synthetic objects for a variety of biomimetic applications.

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Section: Methodsmentioning

confidence: 99%

Section: Methodsmentioning

confidence: 99%

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Fast-Moving Self-Propelled Droplets of a Nanocatalyzed Belousov–Zhabotinsky Reaction

2021

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A nonlinear continuum framework for constitutive modeling of active polymer gels

Nemani,

Ayyagari,

Dayal

2024

Mechanics of Materials

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Dynamical attributes of nanocatalyzed self-oscillating reactions via bifurcation analyses

Rajput

Dayal

2021

The Journal of Chemical Physics

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Self-oscillating chemical reactions that undergo reaction–diffusion (RD) phenomena have shown great potential for designing stimuli-responsive materials. Belousov–Zhabotinsky (BZ) reactions are one such class of reactions that exhibit nonlinear chemical oscillations due to redox cycles of the metal-ion catalyst by virtue of Hopf bifurcation. Using bifurcation analyses, here we investigate the BZ reactions, catalyzed by 0D–2D catalytic nanomats and bare nanosheets, which are known to exhibit enhanced dynamic response due to catalysts’ heterogeneity. Specifically, we incorporate the nanocatalysts’ activity in the kinetic model of the BZ reactions and, subsequently, use catalysts’ activity as the bifurcation parameter for analyses. By computing higher-order Lyapunov and frequency coefficients, we have revealed new oscillatory regimes in the bifurcation diagram, including re-entrant regions where sustained oscillations are unexpectedly suppressed, even with high catalytic activity. In addition, we also calculate the amplitude and frequency of BZ oscillations in each of these regions as a function of nanocatalysts’ activity. We believe that our current findings can be used to harness the nonlinearity of RD-based dynamical systems to provide unique functionalities to active stimuli-response systems.

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Enhancing the Kinetics of Self-oscillating Chemical Reactions via Catalytic Ceria Nanomats

Cited by 4 publications

References 49 publications

Fast-Moving Self-Propelled Droplets of a Nanocatalyzed Belousov–Zhabotinsky Reaction

Fast-Moving Self-Propelled Droplets of a Nanocatalyzed Belousov–Zhabotinsky Reaction

A nonlinear continuum framework for constitutive modeling of active polymer gels

Dynamical attributes of nanocatalyzed self-oscillating reactions via bifurcation analyses

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