The Briggs−Rauscher reaction is a popular demonstration to illustrate chemical oscillations in laboratories, classrooms, and public seminars because of its simplicity and visual appeal. Here, we adapt the Briggs−Rauscher reaction to present reaction−diffusion−convection patterns in the undergraduate general or physical chemistry laboratory. By maintaining the ratio between malonic acid and potassium iodate concentrations as 0.2 in an uncovered Petri dish, sequential patterns (transient dendritic patterns and rotating dendritic patterns) can be observed, which are induced by the interaction of reaction, diffusion, and convection. This beautiful demonstration captures students' attention and inspires reflection and discussion about similar phenomena in nature as well as the wealth of behaviors in systems far from equilibrium.
Many drugs adjust and/or control the spatiotemporal dynamics of periodic processes such as heartbeat, neuronal signaling and metabolism, often by interacting with proteins or oligopeptides.Here we use a quasi-biocompatible, non-equilibrium pH oscillatory system as a biomimetic biological clock to study the effect of pH-responsive peptides on rhythm dynamics. The added peptides generate feedback that can lengthen or shorten the oscillatory period during which the peptides alternate between random coil and coiled-coil conformations. This modulation of a chemical clock supports the notion that short peptide reagents may have utility as drugs to regulate human body clocks.
It is important to
study nonlinear dynamical systems showing pH
and temperature oscillations simultaneously. Here, we systematically
investigated the bromate–sulfite reaction in its coupled system.
Large-amplitude temperature oscillations could be measured accompanied
by the pH oscillations with or without permanganate and manganese(II)
ions. The modulation effects on the oscillatory dynamics of the bromate–sulfite
reaction system produced by permanganate and manganese(II) ions were
investigated in detail. On the one hand, with permanganate, an additional
negative pH feedback process between permanganate and bisulfite occurs,
leading to weakening the pH positive feedback. The above opposite
effects make the period length change unmonotonically when adjusting
the permanganate concentration and flow rate. On the other hand, with
Mn2+ as the feedback agent, the nonmonotonic change of
period was not obvious because it only contained one feedback loop,
which can only reinforce negative feedback without affecting positive
feedback.
The BSF reaction system displayed photoinduction and photoinhibition behavior under flow conditions. The oscillatory period decreased as the light irradiation mainly enhanced the negative process and affected the positive feedback.
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