Harpoon reaction

A harpoon reaction is a type of chemical reaction, first proposed by Michael Polanyi in 1920,^[1]^[2] whose mechanism (also called the harpooning mechanism) involves two neutral reactants undergoing an electron transfer over a relatively long distance to form ions that then attract each other closer together.^[3] For example, a metal atom and a halogen might react to form a cation and anion, respectively, leading to a combined metal halide.

The main feature of these redox reactions is that, unlike most reactions, they have steric factors greater than unity; that is, they take place faster than predicted by collision theory. This is explained by the fact that the colliding particles have greater cross sections than the pure geometrical ones calculated from their radii, because when the particles are close enough, an electron "jumps" (therefore the name) from one of the particles to the other one, forming an anion and a cation which subsequently attract each other. Harpoon reactions usually take place in the gas phase, but they are also possible in condensed media.^[4]^[5]

The predicted rate constant can be improved by using a better estimation of the steric factor. A rough approximation is that the largest separation R_x at which charge transfer can take place on energetic grounds, can be estimated from the solution of the following equation that determines the largest distance at which the Coulombic attraction between the two oppositely charged ions is sufficient to provide the energy ΔでるたE₀

{\frac {-q_{e}^{2}}{R_{x}}}+\Delta E_{0}=0

^[6]

With $\Delta E_{0}=E_{i}-E_{e}a$ , where Ei is the ionization potential of the metal and Eea is the electron affinity of the halogen.

Examples of harpoon reactions[edit]

Generically: Rg + X₂ + hνにゅー → RgX + X,^[7] where Rg is a rare gas and X is a halogen
Ba...FCH₃ + hνにゅー → BaF^(*) + CH₃^[8]
K + CH₃I → KI + CH₃^[9]

References[edit]

^ Polanyi, M. (1920-01-01). "Zum Ursprung der chemischen Energie". Zeitschrift für Physik (in German). 3 (1): 31–35. doi:10.1007/BF01356227. ISSN 0044-3328. S2CID 120940201.
^ Herschbach, D. R. (2007-03-14), "Reactive Scattering in Molecular Beams", in Ross, John (ed.), Advances in Chemical Physics, Advances in Chemical Physics, Hoboken, NJ, USA: John Wiley & Sons, Inc., pp. 319–393, doi:10.1002/9780470143568.ch9, ISBN 978-0-470-14356-8, retrieved 2022-04-13
^ IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "harpoon mechanism". doi:10.1351/goldbook.H02746
^ Fajardo, Mario E.; V. A. Apkarian (November 15, 1986). "Cooperative photoabsorption induced charge transfer reaction dynamics in rare gas solids. I. Photodynamics of localized xenon chloride exciplexes". The Journal of Chemical Physics. 85 (10): 5660–5681. Bibcode:1986JChPh..85.5660F. doi:10.1063/1.451579.
^ Fajardo, Mario E.; V. A. Apkarian (October 1, 1988). "Charge transfer photodynamics in halogen doped xenon matrices. II. Photoinduced harpooning and the delocalized charge transfer states of solid xenon halides (F, Cl, Br, I)". The Journal of Chemical Physics. 89 (7): 4102–4123. Bibcode:1988JChPh..89.4102F. doi:10.1063/1.454846.
^ Atkins, Peter (2014). Atkins' Physical Chemistry. Oxford. p. 875. ISBN 9780199697403.
^ Okada, F.; L. Wiedeman; V. A. Apkarian (February 23, 1989). "Photoinduced harpoon reactions as a probe of condensed-phase dynamics: iodine chloride in liquid and solid xenon". Journal of Physical Chemistry. 93 (4): 1267–1272. doi:10.1021/j100341a020.
^ Skowronek, S.; J. B. Jiméne; A. González Ureña (8 July 1999). "Resonances in the Ba...FCH₃ + hνにゅー → BaF + CH₃ reaction probability". Journal of Chemical Physics. 111 (4): 460–463. Bibcode:1999JChPh.111..460S. doi:10.1063/1.479326.
^ Wiskerke, A. E.; S. Stolte; H. J. Loesch; R. D. Levine (2000). "K + CH₃I → KI + CH₃ revisited: the total reaction cross section and its energy and orientation dependence. A case study of an intermolecular electron transfer". Physical Chemistry Chemical Physics. 2 (4): 757–767. Bibcode:2000PCCP....2..757W. doi:10.1039/a907701d.

[1] Polanyi, M. (1920-01-01). "Zum Ursprung der chemischen Energie". Zeitschrift für Physik (in German). 3 (1): 31–35. doi:10.1007/BF01356227. ISSN 0044-3328. S2CID 120940201.

[2] Herschbach, D. R. (2007-03-14), "Reactive Scattering in Molecular Beams", in Ross, John (ed.), Advances in Chemical Physics, Advances in Chemical Physics, Hoboken, NJ, USA: John Wiley & Sons, Inc., pp. 319–393, doi:10.1002/9780470143568.ch9, ISBN 978-0-470-14356-8, retrieved 2022-04-13

[3] IUPAC, Compendium of Chemical Terminology, 2nd ed. (the "Gold Book") (1997). Online corrected version: (2006–) "harpoon mechanism". doi:10.1351/goldbook.H02746

[4] Fajardo, Mario E.; V. A. Apkarian (November 15, 1986). "Cooperative photoabsorption induced charge transfer reaction dynamics in rare gas solids. I. Photodynamics of localized xenon chloride exciplexes". The Journal of Chemical Physics. 85 (10): 5660–5681. Bibcode:1986JChPh..85.5660F. doi:10.1063/1.451579.

[5] Fajardo, Mario E.; V. A. Apkarian (October 1, 1988). "Charge transfer photodynamics in halogen doped xenon matrices. II. Photoinduced harpooning and the delocalized charge transfer states of solid xenon halides (F, Cl, Br, I)". The Journal of Chemical Physics. 89 (7): 4102–4123. Bibcode:1988JChPh..89.4102F. doi:10.1063/1.454846.

[6] Atkins, Peter (2014). Atkins' Physical Chemistry. Oxford. p. 875. ISBN 9780199697403.

[7] Okada, F.; L. Wiedeman; V. A. Apkarian (February 23, 1989). "Photoinduced harpoon reactions as a probe of condensed-phase dynamics: iodine chloride in liquid and solid xenon". Journal of Physical Chemistry. 93 (4): 1267–1272. doi:10.1021/j100341a020.

[8] Skowronek, S.; J. B. Jiméne; A. González Ureña (8 July 1999). "Resonances in the Ba...FCH₃ + hνにゅー → BaF + CH₃ reaction probability". Journal of Chemical Physics. 111 (4): 460–463. Bibcode:1999JChPh.111..460S. doi:10.1063/1.479326.

[9] Wiskerke, A. E.; S. Stolte; H. J. Loesch; R. D. Levine (2000). "K + CH₃I → KI + CH₃ revisited: the total reaction cross section and its energy and orientation dependence. A case study of an intermolecular electron transfer". Physical Chemistry Chemical Physics. 2 (4): 757–767. Bibcode:2000PCCP....2..757W. doi:10.1039/a907701d.

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v t e Basic reaction mechanisms
Nucleophilic substitutions	Unimolecular nucleophilic substitution (S_N1) Bimolecular nucleophilic substitution (S_N2) Nucleophilic aromatic substitution (S_NAr) Nucleophilic internal substitution (S_Ni) Nucleophilic acyl substitution (S_NAcyl)
Electrophilic substitutions	Electrophilic aromatic substitution (S_EAr)
Elimination reactions	Unimolecular elimination (E1) E1cB-elimination Bimolecular elimination (E2) E_i elimination
Addition reactions	Electrophilic addition Nucleophilic addition Free-radical addition Cycloaddition Oxidative addition
Unimolecular reactions	Intramolecular reaction Isomerization Photodissociation Lindemann–Hinshelwood mechanism RRKM theory
Electron/Proton transfer reactions	Redox Harpoon reaction Grotthuss mechanism Marcus theory Inner sphere electron transfer Outer sphere electron transfer
Medium effects	Solvent effects Cage effect Matrix isolation
Related topics	Elementary reaction Reaction dynamics Reactive intermediate Radical (chemistry) Molecularity Stereochemistry Catalysis Collision theory Arrow pushing Potential energy surface More O'Ferrall–Jencks plot
Chemical kinetics	Rate equation Equilibrium constant Rate-determining step Reaction coordinate Energy profile (chemistry) Transition state theory Activation energy Activated complex Arrhenius equation Eyring equation Michaelis–Menten kinetics Diffusion-controlled reaction