History In 1913, the German chemist
Max Bodenstein first put forth the idea of
chemical chain reactions. If two molecules react, not only molecules of the final reaction products are formed, but also some unstable molecules which can further react with the parent molecules with a far larger probability than the initial reactants. (In the new reaction, further unstable molecules are formed besides the stable products, and so on.) In 1918,
Walther Nernst proposed that the
photochemical reaction between
hydrogen and
chlorine is a chain reaction in order to explain what is known as the
quantum yield phenomena. This means that one
photon of light is responsible for the formation of as many as 106 molecules of the product
HCl. Nernst suggested that the photon dissociates a Cl2 molecule into two Cl atoms which each initiate a long chain of reaction steps forming HCl. In 1923, Danish and Dutch scientists J. A. Christiansen and
Hendrik Anthony Kramers, in an analysis of the formation of polymers, pointed out that such a chain reaction need not start with a molecule excited by light, but could also start with two molecules colliding violently due to thermal energy as previously proposed for initiation of chemical reactions by
van' t Hoff. Semyonov shared the Nobel Prize in 1956 with Sir
Cyril Norman Hinshelwood, who independently developed many of the same quantitative concepts.
Typical steps The main types of steps in chain reaction are of the following types. • Initiation : Br2 → 2 Br• (thermal) or Br2 + hν → 2 Br• (photochemical) : each Br atom is a free radical, indicated by the symbol "•" representing an unpaired electron. • Propagation (here a cycle of two steps) : Br• + H2 → HBr + H• : H• + Br2 → HBr + Br• : the sum of these two steps corresponds to the overall reaction H2 + Br2 → 2 HBr, with
catalysis by Br• which participates in the first step and is regenerated in the second step. • Retardation (inhibition) : H• + HBr → H2 + Br• : this step is specific to this example, and corresponds to the first propagation step in reverse. • Termination 2 Br• → Br2 : recombination of two radicals, corresponding in this example to initiation in reverse. As can be explained using the
steady-state approximation, the thermal reaction has an initial rate of
fractional order (3/2), and a complete rate equation with a two-term denominator (
mixed-order kinetics). • H• + O2 → •OH + •O• • •O• + H2 → •OH + H• • In
chain-growth polymerization, the propagation step corresponds to the elongation of the growing
polymer chain. Chain transfer corresponds to transfer of the activity from this growing chain, whose growth is terminated, to another molecule which may be a second growing polymer chain. For polymerization, the
kinetic chain length defined above may differ from the
degree of polymerization of the product macromolecule. •
Polymerase chain reaction, a technique used in
molecular biology to amplify (make many copies of) a piece of
DNA by
in vitro enzymatic replication using a
DNA polymerase.
Acetaldehyde pyrolysis and rate equation The
pyrolysis (thermal decomposition) of
acetaldehyde, CH3CHO (g) → CH4 (g) + CO (g), proceeds via the Rice-Herzfeld mechanism: • Initiation (formation of
free radicals): : CH3CHO (g) → •CH3 (g) + •CHO (g) k1 The methyl and CHO groups are
free radicals. • Propagation (two steps): : •CH3 (g) + CH3CHO (g) → CH4 (g) + •CH3CO (g) k2 This reaction step provides
methane, which is one of the two main products. : •CH3CO (g) → CO (g) + •CH3 (g) k3 The product •CH3CO (g) of the previous step gives rise to
carbon monoxide (CO), which is the second main product. The sum of the two propagation steps corresponds to the overall reaction CH3CHO (g) → CH4 (g) + CO (g),
catalyzed by a methyl radical •CH3. • Termination: : •CH3 (g) + •CH3 (g) → C2H6 (g) k4 This reaction is the only source of
ethane (minor product) and it is concluded to be the main chain ending step. Although this mechanism explains the principal products, there are others that are formed in a minor degree, such as
acetone (CH3COCH3) and
propanal (CH3CH2CHO). Applying the
Steady State Approximation for the intermediate species CH3(g) and CH3CO(g), the rate law for the formation of methane and the order of reaction are found: The rate of formation of the product methane is (1)... \frac{d\ce{[CH4]}}{dt} = k_2\ce{[CH3]} \ce{[CH3CHO]} For the intermediates (2)... \frac{d\ce{[CH_3]}}{dt} = k_1 \ce{[CH3CHO]} - k_2 \ce{[CH3]} \ce{[CH3CHO]} + k_3 \ce{[CH3CO]} - 2 k_4 \ce{[CH3]}^2 = 0 and (3)... \frac{d\ce{[CH3CO]}}{dt} = k_2 \ce{[CH3]} \ce{[CH3CHO]} - k_3 \ce{[CH3CO]} = 0 Adding (2) and (3), we obtain k_1 \ce{[CH3CHO]} - 2 k_4 \ce{[CH3]}^2 = 0 so that (4)...\ce{[CH3]} = \frac{k_1}{2k_4}\ce{[CH3CHO]}^{1/2} Using (4) in (1) gives the rate law (5) \frac{d\ce{[CH4]}}{dt} = \frac{k_1}{2k_4} k_2 \ce{[CH3CHO]}^{3/2}, which is order 3/2 in the reactant CH3CHO. ==Nuclear chain reactions==