Roger Taylor scite author profile

Roger Taylor

5Publications

129Citation Statements Received

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University of Sussex

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The mechanism of thermal eliminations part XXIII: [1] The thermal decomposition of pyruvic acid

Taylor¹

1987

Int J of Chemical Kinetics

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The thermal decomposition of pyruvic acid into carbon dioxide and acetaldehyde is a unimolecular first-order reaction and takes place according to the rate equation. loyk 13.53--41.250,'4.575 K. These parameters contrast markedly with those recently reported. viz. logk = 7.19-27.700/4.575 K and confirm that the latter, which gave an unacceptably low value for the frequency factor. are anomalous. The lower reactivity of p? rt1v:c acid compared to oxalic acid is interpreted in terms of normal electronic effects.

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The mechanism of thermal eliminations. Part 21. Rate data for pyrolysis of 2-ethoxyquinoline, 1- and 3-ethoxyisoquinoline, and 1-ethoxythiazole: correlation of reactivities with π-bond order of the CN bond

Al‐Awadi¹,

Taylor²

1986

J. Chem. Soc., Perkin Trans. 2

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We have measured the rates of thermal elimination of ethylene from the title compounds between 587.3 and 722.9 K. The reactivities relative to 2-ethoxypyridine at 650 K are: 3-ethoxyisoquinoline (0.21 ), 2ethoxyquinoline (3.1 3), 1 -ethoxyisoquinoline (6.47), 2-ethoxythiazole (63.1 ). These reactivities parallel the Tc-bond order of the C=N bond, though the exceptional reactivity of 2-ethoxythiazole is attributed to additional acceleration through +M electron release from sulphur to nitrogen. This emphasizes the greater relative importance of nucleophilic attack by the nitrogen upon the phydrogen atom as compared with the analogous mechanism for pyrolysis of esters. Because of the semi-concerted nature of the reaction, interruption of aromaticity is much less significant than in, for example, electrophilic aromatic substitution. Thus retention of the benzenoid character of the ring not involved in the elimination is not an important rate-determining feature, as shown by the lower reactivity of 3ethoxyisoquinoline relative to 2-ethoxypyridine. The unimportance of the interruption of aromaticity of the benzenoid ring means that conjugative effects are better relayed to nitrogen in the P-naphthalenelike position (isoquinoline) than in the a-naphthalene-like position (quinoline). This is the reverse of the familiar pattern for reactions of naphthalene-like systems where full charges are involved, and may be an additional factor contributing to the higher reactivity of 1 -ethoxyisoquinoline than of 2-ethoxyquinoline, as may also be the -l effect of the benzo substituent. The conclusions are used to predict elimination rates for alkoxyheterocycles not yet studied.

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The mechanism of thermal eliminations. Part 22. Rate data for pyrolysis of primary, secondary, and tertiary β-hydroxy alkenes, β-hydroxy esters, and β-hydroxy ketones. The dependence of transition-state structure for six-centre eliminations upon compound type

R¹,

McEwen²,

Taylor³

1987

J. Chem. Soc., Perkin Trans. 2

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Substituent Effects in Pyrolysis. V.^1,2 A p-σ⁺ Correlation in the Pyrolysis of 1-Arylethyl Acetates

Taylor¹,

Smith²,

Wetzel³

1962

J. Am. Chem. Soc.

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Electrophilic aromatic substitution. Part 18. Protiodetritiation of anthracene, coronene (dibenzo[ghi,pqr]perylene), and triphenylene in anhydrous trifluoroacetic acid

Ansell¹,

Hirschler²,

Taylor³

1977

J. Chem. Soc., Perkin Trans. 2

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Roger Taylor

The mechanism of thermal eliminations part XXIII: [1] The thermal decomposition of pyruvic acid

The mechanism of thermal eliminations. Part 21. Rate data for pyrolysis of 2-ethoxyquinoline, 1- and 3-ethoxyisoquinoline, and 1-ethoxythiazole: correlation of reactivities with π-bond order of the CN bond

The mechanism of thermal eliminations. Part 22. Rate data for pyrolysis of primary, secondary, and tertiary β-hydroxy alkenes, β-hydroxy esters, and β-hydroxy ketones. The dependence of transition-state structure for six-centre eliminations upon compound type

Substituent Effects in Pyrolysis. V.^1,2 A p-σ⁺ Correlation in the Pyrolysis of 1-Arylethyl Acetates

Electrophilic aromatic substitution. Part 18. Protiodetritiation of anthracene, coronene (dibenzo[ghi,pqr]perylene), and triphenylene in anhydrous trifluoroacetic acid

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Roger Taylor

The mechanism of thermal eliminations part XXIII: [1] The thermal decomposition of pyruvic acid

The mechanism of thermal eliminations. Part 21. Rate data for pyrolysis of 2-ethoxyquinoline, 1- and 3-ethoxyisoquinoline, and 1-ethoxythiazole: correlation of reactivities with π-bond order of the CN bond

The mechanism of thermal eliminations. Part 22. Rate data for pyrolysis of primary, secondary, and tertiary β-hydroxy alkenes, β-hydroxy esters, and β-hydroxy ketones. The dependence of transition-state structure for six-centre eliminations upon compound type

Substituent Effects in Pyrolysis. V.1,2 A p-σ+ Correlation in the Pyrolysis of 1-Arylethyl Acetates

Electrophilic aromatic substitution. Part 18. Protiodetritiation of anthracene, coronene (dibenzo[ghi,pqr]perylene), and triphenylene in anhydrous trifluoroacetic acid

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Substituent Effects in Pyrolysis. V.^1,2 A p-σ⁺ Correlation in the Pyrolysis of 1-Arylethyl Acetates