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Complex behavior in the formaldehyde-sulfite reaction

Complex behavior in the formaldehyde-sulfite reaction
Complex behavior in the formaldehyde-sulfite reaction
The formaldehyde−sulfite reaction is an example of an “acid-to-alkali” clock. It displays an induction period, during which the pH varies only slowly in time, followed by a reaction event, during which the pH increases rapidly by several units. When the reaction is performed in a closed (batch) reactor, the clock time is found to increase with a decrease in initial concentrations of formaldehyde and sulfite and an increase in the total initial concentration of S(IV). At long times, following the clock event, there is a slow decrease in pH. In an open (flow) reactor, bistability between a low-pH steady state (pH ∼ 6−8) and a high-pH steady state (pH ∼ 11) is observed. Additionally, we report the existence of sustained, small-amplitude oscillations in pH in this system. An extended kinetic mechanism reproduces the batch behavior but fails to account for the complex behavior observed in the flow reactor. Possible additional reaction steps are discussed.
1089-5639
283–288
Kovacs, K.
b6ee9b2a-87b9-458d-b42b-9da62c637bf7
McIlwaine, R.
d6ab6441-ab31-4d20-be4d-bbf0a93b9f8d
Gannon, K.
ddf5c7e8-a4ac-4d37-ab15-4f3b7a6329b3
Taylor, A.F.
08028a29-428d-4732-b6b1-f7a93389b386
Scott, S.K.
a95f0e74-4dc4-4d00-a735-a314deca9379
Kovacs, K.
b6ee9b2a-87b9-458d-b42b-9da62c637bf7
McIlwaine, R.
d6ab6441-ab31-4d20-be4d-bbf0a93b9f8d
Gannon, K.
ddf5c7e8-a4ac-4d37-ab15-4f3b7a6329b3
Taylor, A.F.
08028a29-428d-4732-b6b1-f7a93389b386
Scott, S.K.
a95f0e74-4dc4-4d00-a735-a314deca9379

Kovacs, K., McIlwaine, R., Gannon, K., Taylor, A.F. and Scott, S.K. (2004) Complex behavior in the formaldehyde-sulfite reaction. Journal of Physical Chemistry A, 109 (1), 283–288. (doi:10.1021/jp0464324).

Record type: Article

Abstract

The formaldehyde−sulfite reaction is an example of an “acid-to-alkali” clock. It displays an induction period, during which the pH varies only slowly in time, followed by a reaction event, during which the pH increases rapidly by several units. When the reaction is performed in a closed (batch) reactor, the clock time is found to increase with a decrease in initial concentrations of formaldehyde and sulfite and an increase in the total initial concentration of S(IV). At long times, following the clock event, there is a slow decrease in pH. In an open (flow) reactor, bistability between a low-pH steady state (pH ∼ 6−8) and a high-pH steady state (pH ∼ 11) is observed. Additionally, we report the existence of sustained, small-amplitude oscillations in pH in this system. An extended kinetic mechanism reproduces the batch behavior but fails to account for the complex behavior observed in the flow reactor. Possible additional reaction steps are discussed.

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Published date: 14 December 2004
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Identifiers

Local EPrints ID: 499545
URI: http://eprints.soton.ac.uk/id/eprint/499545
DOI: doi:10.1021/jp0464324
ISSN: 1089-5639
PURE UUID: de5a0cc2-f0d4-4bc1-a3a4-6ef7ed2059c7
ORCID for A.F. Taylor: ORCID iD orcid.org/0000-0003-0071-8306

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Date deposited: 25 Mar 2025 18:07
Last modified: 26 Mar 2025 03:14

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Contributors

Author: K. Kovacs
Author: R. McIlwaine
Author: K. Gannon
Author: A.F. Taylor ORCID iD
Author: S.K. Scott

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