Exploding Chemical Gardens: A Phase‐Change Clock Reaction

Ding, Yang; Gutiérrez-Ariza, Carlos; Sainz‐Díaz, C. Ignacio; Cartwright, Julyan H. E.; Cardoso, Silvana S. S.

doi:10.1002/ange.201812331

Cited by 8 publications

(3 citation statements)

References 27 publications

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“…[17][18][19] Various experimental techniques have been documented so far for the formation of chemical garden architectures. [20][21][22][23][24][25][26][27][28][29] Recent studies have investigated the influence of magnetic fields on the morphology regulation of chemical gardens. 30,31 Comprehending the impact of controlling parameters like light illumination or mechanical constriction on the growth kinetics of the chemical garden architectures could contribute to the generation of a predicted morphology and colour in the growing tubes.…”

Section: Introductionmentioning

confidence: 99%

Light-modulated colour transformation in highly intertwined vertically growing silver tungstate tubes

Patel,

Busupalli

2023

Phys. Chem. Chem. Phys.

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Section: Introductionmentioning

confidence: 99%

Light-modulated colour transformation in highly intertwined vertically growing silver tungstate tubes

Patel,

Busupalli

2023

Phys. Chem. Chem. Phys.

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“…The leading theory behind the emergence of life on Earth raises a question: can these mineral-rich chimneys found in oceans be the first evidence of living organisms? The ongoing studies around this question have attracted the attention of scientists to the lab-grown chemical gardens, and significant progress has been made to reveal the full potential of these systems in the fields of chemistry, physics, fluid dynamics, biology, and geology. − As part of the increasing research activities, many potential application areas such as electrochemistry, material science, microfluidics, sensors, filtration, and catalysis are suggested for the use of chemical garden structures …”

Section: Introductionmentioning

confidence: 99%

Comparative Evaluation of Chemical Garden Growth Techniques

Aslanbay Guler,

Demirel,

Imamoglu

2023

Langmuir

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Chemical gardens are an exciting area of selforganized precipitation structures that form nano-and micro-sized structures in different shapes. This field has attracted great interest from researchers due to the specific characteristics and potential applications of these structures. Today, research on chemical gardens has provided deeper information regarding the formation mechanisms of these structures, and several techniques have been developed for chemical garden growth. However, they all show different growth patterns and lead to the formation of structures with a variety of morphological, chemical, or physical properties. This study aimed to evaluate the effects of different production techniques on chemical garden growth, taking into consideration the growth patterns, morphology, microstructure, and chemical composition. The chemical garden structures obtained in seed and injection experiments, two common methods, showed highly similar surface structures, void formation, and chemical composition. The membrane growth method has a small number of applications; thus, it was comprehensively evaluated to add new insights to the existing limited data. It produced the most stable and standard structures in a flat sheet-like shape and showed different morphologies than those observed in other two methods. Overall, this study presented significant results about the effect of growth techniques on chemical garden structures and similar systems.

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“…Clock reaction is an interesting chemical system in which the concentration of one or more products build up abruptly after a well-defined induction time or so-called Landolt time, [1] which is typically accompanied by a characteristic event, such as sudden changes of color, [2] absorbance, [3] chemiluminescence, [4] and phase. [5] The nonlinear chemical kinetics of clock reactions arises from the fact that they essentially involve two parallel redox reactions going in opposite directions at different rates. As shown in Figure 1, for [A] 0 > [B] 0 , the clock species C emerges only after B (stoichiometric constraint) is consumed.…”

Section: Introductionmentioning

confidence: 99%

Construction of a Clock Catalytic System: Highly Efficient and Self‐Indicating Synthesis of Benzoheterocycles at Ambient Temperature

et al. 2021

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Inspired by the mechanism of the clock reaction, we rationally constructed a novel phosphomolybdenum blue (PMB) clock catalytic system for a highly efficient synthesis of benzimidazoles and benzothiazoles simply at ambient temperature. The current PMB clock catalytic system exhibits a sharp decoloration event to announce the depletion of the intermediateconstraint, making this synthetic approach selfindicating and TLC-free. 31 P NMR and XPS analysis of PMBcatalyst showed that only two Mo 6 + atoms are reduced to Mo 5 + atoms in the Keggin structure due to the moderate reducibility of benzimidazoline and benzothiazoline intermediates. Thus,the active Keggin-type POM cluster could be well maintained in DMSO during the redox cycling of phosphomolybdic acid (PMA) and PMB. 1 H NMR tracing experiment not only confirmed the proposed reaction mechanism but also showed that PMB exerts Lewis acid catalytic activityat the early phase of the reaction other than the expected redox catalytic activity.

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Exploding Chemical Gardens: A Phase‐Change Clock Reaction

Cited by 8 publications

References 27 publications

Light-modulated colour transformation in highly intertwined vertically growing silver tungstate tubes

Light-modulated colour transformation in highly intertwined vertically growing silver tungstate tubes

Comparative Evaluation of Chemical Garden Growth Techniques

Construction of a Clock Catalytic System: Highly Efficient and Self‐Indicating Synthesis of Benzoheterocycles at Ambient Temperature

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