The Diels-Alder Cycloaddition Reaction of Substituted Hemifullerenes with 1,3-Butadiene: Effect of Electron-Donating and  Electron-Withdrawing Substituents

Mojica, Martha; Méndez, Francisco; Alonso, J. A.

doi:10.3390/molecules21020200

Cited by 8 publications

(6 citation statements)

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“…Our previous studies of the substituent effect in the reactivity of C 30 H 10 suggested that it is possible to increase its reactivity in the DA reactions. 31,32 The results presented support the possibility to dimerize C 30 H 10 and the existence of C 60 H 20 . In fact, the fullerene hydride C 60 H 20 has been detected in the mass spectra of C 60 hydrides synthesized by condensation of benzene molecules, 49 although, the structure of C 60 H 20 formed in these experiments is not necessarily the belt-like structure discussed here, which is closely connected to the structure of the precursor C 30 H 10 .…”

Section: ) Stepwise Dimerizationsupporting

confidence: 72%

“…30 Although the full C 30 H 10 (1) has not been synthesized yet, one can expect that similar methods will allow for the synthesis of this fragment. On the basis of ab initio calculations Mojica et al 31,32 suggested that C 30 H 10 (1) is a good dienophile towards DA cycloaddition reaction with butadiene and possesses high symmetry, which makes it an ideal fragment to produce C 60 H 20 and the C 60 fullerene (Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

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Dimerization of pentacyclopentacorannulene C₃₀H₁₀ as a strategy to produce C₆₀H₂₀ as a precursor for C₆₀

et al. 2020

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Section: ) Stepwise Dimerizationsupporting

confidence: 72%

Section: Introductionmentioning

confidence: 99%

Dimerization of pentacyclopentacorannulene C₃₀H₁₀ as a strategy to produce C₆₀H₂₀ as a precursor for C₆₀

et al. 2020

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“…The definite mechanism for the formation of PAHs is not well understood. Some researchers proposed that they might be formed through free radical reactions, intramolecular addition or the polymerization of small molecules [5,6,7]. In meat products, PAHs are formed during processing at a high temperature, such as by smoking, drying, roasting, and grilling [8,9,10].…”

Section: Introductionmentioning

confidence: 99%

Small Molecular Weight Aldose (d-Glucose) and Basic Amino Acids (l-Lysine, l-Arginine) Increase the Occurrence of PAHs in Grilled Pork Sausages

Nie

Cai

et al. 2018

Molecules

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(1) Background: Amino acids and carbohydrates are widely used as additives in the food industry. These compounds have been proven to be an influencing factor in the production of chemical carcinogenic compounds polycyclic aromatic hydrocarbons (PAHs). However, the effect of the properties of the amino acids and carbohydrates on the production of PAHs is still little known. (2) Methods: We added different (i) R groups (the R group represents an aldehyde group in a glucose molecule or a ketone group in a fructose molecule); (ii) molecular weight carbohydrates; (iii) polarities, and (iv) acid-base amino acids to pork sausages. The effects of the molecular properties of carbohydrates and amino acids on the formation of PAHs in grilled pork sausages were investigated. (3) Results: The results showed that a grilled sausage with aldehyde-based d-glucose was capable of producing more PAHs than a sausage with keto-based d-fructose. A higher PAH content was determined in the grilled pork sausage when the smaller molecular weight, d-glucose, was added compared with the sausage where the larger molecular weight, 4-(α-d-glucosido)-d-glucose and cellulose were added. The addition of basic amino acids (l-lysine, l-arginine) was capable of producing more PAHs compared with the addition of acidic amino acids (l-glutamic acid, l-aspartate). When amino acid containing a benzene ring was added, a smaller volume of PAHs was produced compared with the addition of other amino acids. (4) Conclusions: Our study suggests that systematic consideration of molecule properties is necessary when using food additives (amino acids and carbohydrates) for food processing.

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“…In this particular case, the F I G U R E 3 Dimerization reactions between two [1+1] type moieties and between two [2+2] type moieties [122] activation barriers are lower than for the other reactions; what is more, the free energies of the process are negative, in contrast to the positive values for the other processes. Later, the same authors [124] used the B3LYP functional to find out whether the Diels-Alder cycloaddition with 1,3-butadiene can be accelerated by replacement of H at the border of triindenetriphenilene (primary hemifulleren 1) and pentacyclopentacorannulene (primary hemifulleren 2). The tested substituents included electron-donating groups (NH 2 , OMe, OH, Me, i-Pr) and electron-withdrawing ones (F, COOH, CF 3 , CHO, CN, NO 2 ).…”

Section: Bowl-shaped Polyenesmentioning

confidence: 99%

Quantum‐chemical approaches in the study of fullerene and its derivatives by the example of the most typical cycloaddition reactions: A review

Sattarova

Biglova

Мустафин

2021

Int J of Quantum Chemistry

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In the past two decades, quantum chemistry has become an indispensable tool for the reliable interpretation of experimental measurements of a wide range of molecular properties of fullerene and its derivatives. Among the modern quantum-chemical methods of analysis, preference is given to the density functional theory. This review describes the computational studies that demonstrate rather comprehensively the prospects of quantum-chemical calculations in many fields of the chemistry of fullerene and its derivatives, such as geometric parameters, stability of structures, molecular spectroscopic properties, electronic structures, the nature of bonds, thermochemistry, and simulation of the kinetics and mechanism of processes. The review focuses on the most typical cycloaddition reactions such as Diels-Alder, Prato and Bingel-Hirsch reactions.The general trends of scientific studies in this area are also discussed and a wide range of references is provided where the readers can find technical details of computational approaches that may be of interest for them.

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The Diels-Alder Cycloaddition Reaction of Substituted Hemifullerenes with 1,3-Butadiene: Effect of Electron-Donating and Electron-Withdrawing Substituents

Cited by 8 publications

References 36 publications

Dimerization of pentacyclopentacorannulene C₃₀H₁₀ as a strategy to produce C₆₀H₂₀ as a precursor for C₆₀

Dimerization of pentacyclopentacorannulene C₃₀H₁₀ as a strategy to produce C₆₀H₂₀ as a precursor for C₆₀

Small Molecular Weight Aldose (d-Glucose) and Basic Amino Acids (l-Lysine, l-Arginine) Increase the Occurrence of PAHs in Grilled Pork Sausages

Quantum‐chemical approaches in the study of fullerene and its derivatives by the example of the most typical cycloaddition reactions: A review

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The Diels-Alder Cycloaddition Reaction of Substituted Hemifullerenes with 1,3-Butadiene: Effect of Electron-Donating and Electron-Withdrawing Substituents

Cited by 8 publications

References 36 publications

Dimerization of pentacyclopentacorannulene C30H10 as a strategy to produce C60H20 as a precursor for C60

Dimerization of pentacyclopentacorannulene C30H10 as a strategy to produce C60H20 as a precursor for C60

Small Molecular Weight Aldose (d-Glucose) and Basic Amino Acids (l-Lysine, l-Arginine) Increase the Occurrence of PAHs in Grilled Pork Sausages

Quantum‐chemical approaches in the study of fullerene and its derivatives by the example of the most typical cycloaddition reactions: A review

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Dimerization of pentacyclopentacorannulene C₃₀H₁₀ as a strategy to produce C₆₀H₂₀ as a precursor for C₆₀

Dimerization of pentacyclopentacorannulene C₃₀H₁₀ as a strategy to produce C₆₀H₂₀ as a precursor for C₆₀