493. Kinetics and mechanism of aromatic nitration. Part II. Nitration by the nitronium ion, NO2 +, derived from nitric acid

Hughes, E. D.; Ingold, C. K.; Reed, R. I.

doi:10.1039/jr9500002400

Cited by 81 publications

(63 citation statements)

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“…It is highly likely that with toluene at these high acid concentrations k3' >> k-,' and formation of the encounter complex (reaction 2) is rate controlling when the nitration rate is first order in toluene (13 ' (15). With these it is likely that k-,' >> k,' and [3] I is rate controlling, so that k2 = (kl'aH+/k-laH20) (k,'/k-,')k,' and E, = A H , + AH, + E,', AH, ' being the heat of reaction 2, the formation of the encounter complex. One expects AH, to be small and , E,' to be relatively independent of the medium.…”

Section: Resultsmentioning

confidence: 99%

“…where k, = k,' aH+ and When k2[ArH] >> k , , [4] simplifies to which accounts for the rate being zero order with respect to the aromatic substrate under certain conditions such as those that often occur in organic solvents (2)(3)(4)(5). O n the other hand whenk, >> k, [ArH], [4] simplifies to which accounts for the rate being first order with respect to the aromatic substrate under other conditions such as those which normally obtain in aqueous sulphuric acid.…”

Section: Introductionmentioning

confidence: 99%

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Rates and activation energies of nitronium ion formation and reaction in the nitration of toluene in ∼78% sulphuric acid

Sheats¹,

Strachan²

1978

Can. J. Chem.

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A stopped-flow spectrometer has been used to investigate the mechanism of the nitration of toluene, and to determine kinetic parameters for the formation and reaction of nitronium ion, in 77.3 and 78.45 wt.% sulphuric acid. The protonation of nitric acid t o form nitronium ion and water is found to occur at similar rates at both acid concentrations and to have an activation energy of 18.3 t 4.0 kcal mol-l. The activation energy of the reverse reaction, the heat of the reaction, and the activation energy of encounter complex formation between nitronium ion and toluene are estimated to be respectively 10.5 + 4.0, 7.8 F 0.5, and 5.9 f 0

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Section: Resultsmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Rates and activation energies of nitronium ion formation and reaction in the nitration of toluene in ∼78% sulphuric acid

Sheats¹,

Strachan²

1978

Can. J. Chem.

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“…This work aims to bring about a detailed understanding of the two gasphase reactions in Equations (1) and (2) through the combined application of experimental techniques and a detailed ab initio study at the MP2/6 ± 31 G* level of theory. In particular, we report new theoretical and experimental results for the reaction in Equation (1), whereas for the reaction in Equation (2) we use both earlier experimental and theoretical results [7,8] and new results that allow us to perform a more comprehensive comparative analysis of the two reactions. We have found that the two reactions are mechanistically very similar and that they proceed mainly according to a 1,3-dipolar-type addition.…”

Section: Introductionmentioning

confidence: 96%

“…We have found that the two reactions are mechanistically very similar and that they proceed mainly according to a 1,3-dipolar-type addition. This reaction leads to the formation of two structurally related end products, nitrosated ketene from the reaction in Equation (1) and nitrosated acetaldehyde from the reaction in Equation (2).…”

Section: Introductionmentioning

confidence: 98%

Gas-Phase Reactions of Nitronium Ions with Acetylene and Ethylene: An Experimental and Theoretical Study

Bernardi

Cacace

Petris³

et al. 2000

Chem. Eur. J.

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A comparative study of the gas-phase reactions of NO 2 with acetylene and ethylene was performed by using FT-ICR, MIKE, CAD, and N f R/ CA mass spectrometric techniques, in conjunction with ab initio calculations at the MP2/6 ± 31 G* level of theory. Both reactions proceed according to the same mechanism, that is, 1,3-dipolar cycloaddition, but yield products of different stability. The C 2 H 2 NO 2 adduct from acetylene has an aromatic character and hence is highly stabilized with respect to the C 2 H 4 NO 2 adduct from ethylene. Both cycloadducts tend to isomerize into O-nitroso derivatives, that is, nitrosated ketene and nitrosated acetaldehyde, which represent the thermodynamically most stable products from the addition of NO 2 to acetylene and ethylene, respectively. As prototypal examples of the reactivity of free nitronium ions with most simple p systems, the reactions investigated are useful starting points to model the mechanism of aromatic nitration.

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“…The organic reactant (i.e., benzene or toluene) is transferred into the aqueous phase, also called mixed acid, where it reacts with the nitronium ion formed from the nitric acid. The sulphuric acid acts as a catalyst [1,2]. The strength of the sulphuric acid used determines the type of reaction developed, enabling operation in the kinetic or the fast reaction regimes, if the remaining parameters are kept constant [3].…”

Section: Introductionmentioning

confidence: 99%

Continuous adiabatic industrial benzene nitration with mixed acid at a pilot plant scale

Quadros

Oliveira

Baptista

2005

Chemical Engineering Journal

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A pilot plant for the continuous adiabatic nitration of benzene was constructed, reproducing the industrial operating conditions, in order to identify the reaction regime prevailing in this industrial process. Important process parameters were tested covering a wide range of operating conditions: reaction temperature (80-135• C), benzene to nitric acid molar feed ratio (0.96-1.15) and stirring speed (390-1700 rpm). The residence time and the sulphuric acid strength were fixed at 2 min and 68%, respectively. The data from a large number of experiments show a good agreement with the results of a mathematical model of the reactor.In the range of operating conditions tested, it was shown that the prevailing reaction regime is the intermediate one (0.3 < Ha < 2). The film model used to predict the mononitrobenzene production according to the intermediate regime achieved a good accuracy. The asymptotic solutions for the fast and slow reaction regimes were compared with the full solution model and it was clearly shown that the last led to improved results. Since the film model is a simple approach to describe the mass transfer with simultaneous chemical reaction, the results achieved confirmed the adequacy of this modelling approach.

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493. Kinetics and mechanism of aromatic nitration. Part II. Nitration by the nitronium ion, NO2 +, derived from nitric acid

Cited by 81 publications

References 1 publication

Rates and activation energies of nitronium ion formation and reaction in the nitration of toluene in ∼78% sulphuric acid

Rates and activation energies of nitronium ion formation and reaction in the nitration of toluene in ∼78% sulphuric acid

Gas-Phase Reactions of Nitronium Ions with Acetylene and Ethylene: An Experimental and Theoretical Study

Continuous adiabatic industrial benzene nitration with mixed acid at a pilot plant scale

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