D<scp>IELS</scp>‐A<scp>LDER</scp>‐Reaktionen. II. Über die Anwendung linearer Freier‐Energie‐Beziehungen auf D<scp>IELS</scp>‐A<scp>LDER</scp>‐Reaktionen

Blankenburg, B.; Fiedler, H.; Hampel, M.; Hauthal, Hermann G.; Just, G.; Kahlert, K.; Korn, Joseph A.; Müller, Kai-Sven; Pritzkow, W.; Reinhold, Y.; Röllig, M.; Sauer, E.; Schnurpfeil, D.; Zimmermann, G.

doi:10.1002/prac.19743160513

Cited by 43 publications

(14 citation statements)

References 11 publications

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“…Carboxyl acids and alcohols are found to be the most promising solvent types for accelerating the here investigated DA reaction. This is in good agreement with reported kinetic solvent effects where acetic acid was found to be the best solvent and the second to fifth solvents were all alcohols. The solvents in Table can be targeted for further experimentations.…”

Section: Reaction Solvent Designsupporting

confidence: 92%

“…One of the most interesting aspects of this reaction is its pronounced solvent dependency . Blankenburg et al systematically studied the effects of various solvents on the DA reaction between 1,3‐cyclopentadiene and various dienophiles. In this work, the reaction between 1,3‐cyclopentadiene and acrolein at 303 K is considered as example reaction where 15 solvents with a wide variation of physical and chemical properties were experimentally investigated.…”

Section: Solvent Theoretical Descriptors and Reaction Rate Regressionmentioning

confidence: 99%

“…. Molar volumes of the reactants and product

V_{normalm}^{i}

( i = cyc, acr, and nor) are presented in Supporting Information Table S1 of Appendix C. The reaction was reported to be an irreversible second‐order reaction with respect to the reactants . Therefore, the required reactor volume

V_{normalR}

(m 3 ) can be expressed by

V_{normalR} = {\dot{N}}_{out, nor} \times 0.001 / true(k C_{cyc} C_{acr} true)

…”

Section: Integrated Solvent and Process Designmentioning

confidence: 99%

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Integrated solvent and process design exemplified for a Diels–Alder reaction

et al. 2014

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A new kind of solvent descriptor obtained from quantum chemical calculations is introduced. Group contributions to each solvent descriptor are regressed for 71 UNIFAC groups. A reaction kinetic model is built by correlating a set of experimentally determined reaction rate constants in various solvents with the corresponding theoretical solvent descriptors. Based on the kinetic model and the developed group contribution method, a computer-aided molecular design problem is formulated and optimal solvents to achieve highest reaction rates are identified. For considering the multiple and complicated effects of solvents on a chemical process, an integrated solvent and process design is performed. Solvent molecular structures and process operations are simultaneously optimized by the formulation and solution of a mixed-integer nonlinear program. The proposed design methodology is exemplified for a selected Diels-Alder reaction.

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Section: Reaction Solvent Designsupporting

confidence: 92%

Section: Solvent Theoretical Descriptors and Reaction Rate Regressionmentioning

confidence: 99%

“…. Molar volumes of the reactants and product

V_{normalm}^{i}

V_{normalR}

(m 3 ) can be expressed by

V_{normalR} = {\dot{N}}_{out, nor} \times 0.001 / true(k C_{cyc} C_{acr} true)

…”

Section: Integrated Solvent and Process Designmentioning

confidence: 99%

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Integrated solvent and process design exemplified for a Diels–Alder reaction

et al. 2014

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“…It should be emphasized that the term solvent polarity is used here by tradition; in fact, generalized solvating power depending on the ability for both specific and nonspecific solvation is concerned, and different solvent polarity parameters are not really related to the polarity in its physical sense (which is [13], cycloaddition of 1,4-naphthoquinone to 2,3-dimethylbuta-1,3-diene at 80oC (II) [14], and heterolysis of tert-butyl chloride at 25oC (V) [17], logarithms of the rate constants of quaternization of tripropylamine with methyl iodide at 20oC (III) [15] and quaternization of triethylamine with ethyl iodide at 25oC (IV) [16], and log (N/X) values for reaction I (VI) [13] ÄÄÄÂÄÄÄÄÄÄÄÄÄÄÄÄÄÂÄÄÄÄÄÂÄÄÄÄÂÄÄÄÄÄÄÂÄÄÄÄÂÄÄÄÄÄÄÂÄÄÄÄÄÂÄÄÄÄÂÄÄÄÄÂÄÄÄÄÄÂÄÄÄÄÂÄÄÄÄÄÂÄÄÄÄ No.³ Solvent ÄÄÄÁÄÄÄÄÄÄÄÄÄÄÄÄÄÁÄÄÄÄÄÁÄÄÄÄÁÄÄÄÄÄÄÁÄÄÄÄÁÄÄÄÄÄÄÁÄÄÄÄÄÁÄÄÄÄÁÄÄÄÄÁÄÄÄÄÄÁÄÄÄÄÁÄÄÄÄÄÁÄÄÄÄ related to dipole moment of molecules). In particular, this was noted by Reichardt [5,12].…”

mentioning

confidence: 99%

“…Table 1 contains values of W determined at 30oC for 17 solvents [5] and rate constants (or their logarithms) for the following reactions: I, cycloaddition of acrolein to cyclopentadiene at 30oC [13]; II, cycloaddition of 1,4-naphthoquinone to 2,3-dimethylbutadiene at 80oC [14]; III, quaternization of tripropylamine with methyl iodide at 20oC (so-called parameter j) [15]; IV, quaternization of triethylamine with ethyl iodide at 25oC [16]; V, heterolysis of tert-butyl chloride at 25oC [17]; and VI, N/X ratio in reaction I [13]. Table 1 contains values of W determined at 30oC for 17 solvents [5] and rate constants (or their logarithms) for the following reactions: I, cycloaddition of acrolein to cyclopentadiene at 30oC [13]; II, cycloaddition of 1,4-naphthoquinone to 2,3-dimethylbutadiene at 80oC [14]; III, quaternization of tripropylamine with methyl iodide at 20oC (so-called parameter j) [15]; IV, quaternization of triethylamine with ethyl iodide at 25oC [16]; V, heterolysis of tert-butyl chloride at 25oC [17]; and VI, N/X ratio in reaction I [13].…”

mentioning

confidence: 99%

10.1007/s11176-008-1018-x

2010

CrossRef Listing of Deleted DOIs

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Solvent effect on the ratio of the endo and exo isomers formed by the Diels3Alder reaction of cyclopentadiene with acrylic acid esters can be described by multiparameter equations involving solvent polarity and electrophilic solvating power as determining parameters. The solvent polarity parameter W based on the stereoisomer ratio in the reaction with methyl acrylate cannot be regarded as a universal measure of solvating power, which was demonstrated using a number of examples.

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Stereoselectivities and reaction rates in Diels-Alder reactions promoted by non-aqueous solvents and their aqueous mixtures: Correlations with non-adjustable parameters

Kumar

1996

J. Phys. Org. Chem.

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Stereoselectivities and rates of Diels-Alder reactions in different solvents were correlated with a parameter, Q, defined based on internal pressure, which is normalized with respect to a polarity scale. The polarity scale or index, although purely empirical in nature, can be calculated from the refractive index of the solvent. These correlations were linear for both stereoselectivities and reaction rates. Using expressions derived in this study, it is possible to represent the kinetic profiles of several Diels-Alder reactions in about 75 pure and mixed solvent media. The activation volume of a reaction can be directly estimated from the regression of data on rates and Q in various solvents using the proposed correlations.

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DIELS‐ALDER‐Reaktionen. II. Über die Anwendung linearer Freier‐Energie‐Beziehungen auf DIELS‐ALDER‐Reaktionen

Cited by 43 publications

References 11 publications

Integrated solvent and process design exemplified for a Diels–Alder reaction

Integrated solvent and process design exemplified for a Diels–Alder reaction

10.1007/s11176-008-1018-x

Stereoselectivities and reaction rates in Diels-Alder reactions promoted by non-aqueous solvents and their aqueous mixtures: Correlations with non-adjustable parameters

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