Transition metal cmplexes of ambidentate anions /

Jennings, Margaret Ann

January 1969

No description available.

Chemistry

Ambident anions

Efficient Carbohydrate Synthesis By Intra- and Supramolecular Control

Dong, Hai

January 2009

The Lattrell-Dax method of nitrite-mediated substitution of carbohydrate triflates is an efficient method to generate structures of inverse configuration. In this study, the effects of the neighboring group on the Lattrell-Dax inversion were explored. A new carbohydrate/anion host-guest system was discovered and the ambident reactivity of the nitrite anion was found to cause a complicated behavior of the reaction. It has been demonstrated that a neighboring equatorial ester group plays a highly important role in this carbohydrate epimerization reaction, restricting the nitrite N-attack, thus resulting in O-attack only and inducing the formation of inversion compounds in good yields. Based on this effect, efficient synthetic routes to a range of carbohydrate structures, notably β-D-mannosides and β-D-talosides, were designed by use of double parallel and double serial inversion. A supramolecularly activated, triggered cascade reaction was also developed. This cascade reaction is triggered by a deprotonation process that is activated by anions. It was found that the anions can activate this reaction following their hydrogen bonding tendencies to the hydroxyl group in aprotic solvents. / QC 20100709

Carbohydrate Chemistry

Supramolecular Control

Ambident Reactivity

Bioorganic chemistry

Bioorganisk kemi

Arilação seletiva de ânions heterocíclicos ambidentados por sais de difenil iodônio / Seletive arylation of ambident heterocycle anions by diphenyl iodonium salts

Artur, Julio Cesar

12 September 2008

A arilação seletiva de compostos orgânicos confere-lhes propriedades com amplas aplicações: em compostos de atividade biológica, inibidora da protease do vírus HIV-1, e de interesse como agroquímicos ou na engenharia de materiais. Em razão disso, novos métodos e reagentes tem sido desenvolvidos com essa finalidade. Sabe-se que a N-arilação de várias aminas, catalisadas por paládio, com haletos de arila e triflatos é tida como ferramenta importante a disposição do químico sintético. Do mesmo modo, publicou-se que a N-arilação de certos -amino ácidos por haletos de arila, procede-se facilmente quando catalisada por CuI. Alternativamente, a literatura cita outros métodos eficientes usando ácidos borônicos, compostos arilbismuto e compostos organochumbo. Neste trabalho foi estudada a arilação seletiva de ânions ambidentados pelo sal de iodo polivalente cloreto de difenil iodônio, em diferentes condições de reação, visando a otimização da síntese: 1) reação térmica (agitação magnética), sem catalisador, e em diferentes solventes, ou mistura de solventes; 2) reação sonoquímica, sem catalisador e em diferentes soluções; 3) reação térmica e sonoquímica na presença de catalisador CuCl (10%). Sacarinato de sódio, acesulfame de potássio, e ftalimida potássica foram escolhidos como ânions ambidentados derivados de sulfoimidas e imidas a serem arilados. No caso de N-fenil sacarina a quemiosseletividade e o melhor rendimento são observados com acetonitrila/água (1:1, v/v), sob refluxo para formação do par iônico intermediário (ou o iodano correspondente), seguido por fusão térmica na ausência de solvente. O acesulfame potássico, por sua vez, forneceu seletivamente produtos de N- ou O-fenilação, de acordo com as seguintes condições estabelecidas: 1) produto de fenilação por via térmica ou sonoquímica em etanol; 2) produto de O-fenilação, por via térmica ou sonoquímica em acetonitrila. A ftalimida potássica, na ausência de catalisador, é arilada em baixos rendimentos. A melhor condição de síntese é encontrada com acetonitrila e CuCl (10%), sendo 92% o rendimento por via sonoquímica e 78% por via térmica. A seletividade verificada foi analisada em termos das interações dos ânions ambidentados e dos solventes em questão. / The arylation of organic compounds gives place to a wide number of applications: concerning to their biological properties as HIV-1, protease inhibitor, as well as synthetic intermediates in pharmaceuticals, agrochemical and polymer chemistry. New methodologies and reagents have been developed as consequence of this. It is already known that N-arylation of several amines, catalyzed by palladium, with aryl halides and trifflates is a valuable tool to various reported organic synthesis. In the same way, it has been published that the N-arylation of certain -amino acids by aryl halides, proceeds smoothly when catalized by CuI. Alternatively, the literature reports other efficient methods using boranic acids, arylbismuth and organolead compounds. In the present work, it was studied the selective arylation of ambident anions by hypervalent iodine salts (chloride of diphenyl iodonium), in a different set of conditions, seeking the synthesis optimizations: 1) thermal reactions (silent mode, magnetic stirring), without catalyst, and, in different solvents or mixture of then; 2) sonochemical reactions, without catalyst, and in a different solvent composition; 3) thermal and sonochemical reactions carried out in the presence of (10%) CuCl as the catalyst. Sodium saccharinate, acessulfame K and potassium phthalimide were chosen as the ambident anions (derived from sulfonimides and imide functional groups) to be studied. In the N-phenyl saccharin case the chemioselectivity was achieved along the best yields when water/acetonitrila (1:1, v/v) solvent was employed in the step to form the ion pair (or the 3-iodane, intermediate), followed by the thermal fusion in the absence of solvent. The acessulfame K, for its turn, supplied selectively products of N- and O-arylation under the following established conditions: 1) N-phenylation in etanol through thermal and sonochemical approach; 2) O-phenylation product, in acetonitrila, by thermal and sonochemical method. Finally, arylation of potassium phthalimide with diaryliodonium is sluggish and gives low yields without catalyst. The best protocol to this synthesis was found with the solvent acetonitrile and (10%) CuCl catalyst addition, being 92% the yield of sonochemical reaction and 78% of the thermal one. The selectivity achieving was analyzed in accord with the solution interaction between the ambident anion and the solvent molecules.

ambident anions

ânions ambidentados

arylation by diphenyl iodonium

efeito de solventes

ultra-som

ultrasound

Arilação seletiva de ânions heterocíclicos ambidentados por sais de difenil iodônio / Seletive arylation of ambident heterocycle anions by diphenyl iodonium salts

Julio Cesar Artur

12 September 2008

A arilação seletiva de compostos orgânicos confere-lhes propriedades com amplas aplicações: em compostos de atividade biológica, inibidora da protease do vírus HIV-1, e de interesse como agroquímicos ou na engenharia de materiais. Em razão disso, novos métodos e reagentes tem sido desenvolvidos com essa finalidade. Sabe-se que a N-arilação de várias aminas, catalisadas por paládio, com haletos de arila e triflatos é tida como ferramenta importante a disposição do químico sintético. Do mesmo modo, publicou-se que a N-arilação de certos -amino ácidos por haletos de arila, procede-se facilmente quando catalisada por CuI. Alternativamente, a literatura cita outros métodos eficientes usando ácidos borônicos, compostos arilbismuto e compostos organochumbo. Neste trabalho foi estudada a arilação seletiva de ânions ambidentados pelo sal de iodo polivalente cloreto de difenil iodônio, em diferentes condições de reação, visando a otimização da síntese: 1) reação térmica (agitação magnética), sem catalisador, e em diferentes solventes, ou mistura de solventes; 2) reação sonoquímica, sem catalisador e em diferentes soluções; 3) reação térmica e sonoquímica na presença de catalisador CuCl (10%). Sacarinato de sódio, acesulfame de potássio, e ftalimida potássica foram escolhidos como ânions ambidentados derivados de sulfoimidas e imidas a serem arilados. No caso de N-fenil sacarina a quemiosseletividade e o melhor rendimento são observados com acetonitrila/água (1:1, v/v), sob refluxo para formação do par iônico intermediário (ou o iodano correspondente), seguido por fusão térmica na ausência de solvente. O acesulfame potássico, por sua vez, forneceu seletivamente produtos de N- ou O-fenilação, de acordo com as seguintes condições estabelecidas: 1) produto de fenilação por via térmica ou sonoquímica em etanol; 2) produto de O-fenilação, por via térmica ou sonoquímica em acetonitrila. A ftalimida potássica, na ausência de catalisador, é arilada em baixos rendimentos. A melhor condição de síntese é encontrada com acetonitrila e CuCl (10%), sendo 92% o rendimento por via sonoquímica e 78% por via térmica. A seletividade verificada foi analisada em termos das interações dos ânions ambidentados e dos solventes em questão. / The arylation of organic compounds gives place to a wide number of applications: concerning to their biological properties as HIV-1, protease inhibitor, as well as synthetic intermediates in pharmaceuticals, agrochemical and polymer chemistry. New methodologies and reagents have been developed as consequence of this. It is already known that N-arylation of several amines, catalyzed by palladium, with aryl halides and trifflates is a valuable tool to various reported organic synthesis. In the same way, it has been published that the N-arylation of certain -amino acids by aryl halides, proceeds smoothly when catalized by CuI. Alternatively, the literature reports other efficient methods using boranic acids, arylbismuth and organolead compounds. In the present work, it was studied the selective arylation of ambident anions by hypervalent iodine salts (chloride of diphenyl iodonium), in a different set of conditions, seeking the synthesis optimizations: 1) thermal reactions (silent mode, magnetic stirring), without catalyst, and, in different solvents or mixture of then; 2) sonochemical reactions, without catalyst, and in a different solvent composition; 3) thermal and sonochemical reactions carried out in the presence of (10%) CuCl as the catalyst. Sodium saccharinate, acessulfame K and potassium phthalimide were chosen as the ambident anions (derived from sulfonimides and imide functional groups) to be studied. In the N-phenyl saccharin case the chemioselectivity was achieved along the best yields when water/acetonitrila (1:1, v/v) solvent was employed in the step to form the ion pair (or the 3-iodane, intermediate), followed by the thermal fusion in the absence of solvent. The acessulfame K, for its turn, supplied selectively products of N- and O-arylation under the following established conditions: 1) N-phenylation in etanol through thermal and sonochemical approach; 2) O-phenylation product, in acetonitrila, by thermal and sonochemical method. Finally, arylation of potassium phthalimide with diaryliodonium is sluggish and gives low yields without catalyst. The best protocol to this synthesis was found with the solvent acetonitrile and (10%) CuCl catalyst addition, being 92% the yield of sonochemical reaction and 78% of the thermal one. The selectivity achieving was analyzed in accord with the solution interaction between the ambident anion and the solvent molecules.

ânions ambidentados

efeito de solventes

ultra-som

ambident anions

arylation by diphenyl iodonium

ultrasound

Strategies for Computational Investigation of Reaction Mechanisms in Organic and Polymer Chemistry Using Static Quantum Mechanics

Tchernook, Ivan

03 March 2016

This thesis presents computational studies of problems in the organic and polymer chemistry. The state-of-the art quantum chemical methods are used to gain further insight into the origin and the nature of the reactions in three different organic and polymer systems. The research questions are conceptually approached by identifying the key aspects. Then an appropriate strategy for the quantum chemical modeling is developed. In the scope of the polymer chemistry, the novel synthesis technique of nanostructured materials, the so-called twin polymerization, is investigated. Using three model systems of increasing complexity the influence of the anion (trifluoroacetate) in the reaction system is investigated. The effect of the solvent polarity as well as the effect of the entropic contributions are also considered. The rearrangement reaction of the volatile cyanotritylcarbenes is another topic. These carbenes readily rearrange to ethene main products, however also small amount of the unexpected heptafulvenes is formed. This unprecedented heptafulvene formation is modeled in detail and the energetics is systematically evaluated to identify most reasonable rearrangement pathways of the probable multiple alternative routes. Computational investigation of other tritylcarbenes with varying spectator substituents results in sophisticated data base for experimental investigations. At last, some controversial observations in experimental studies concerning the kinetics of the electrophilic alkylation of the barbiturate anion are studied. To interpret the kinetic measurements, different alkylation pathways are analyzed with respect to their energetics. Further, the influence of microsolvation is demonstrated.

Computational Chemistry

quantenchemische Modellierung

Zwillingspolymerisation

Gegenanion

Tritylcarbene

Umlagerung

Barbiturat-Anionen

Nukleophilie

ambidente Reaktivität

statische Quantenchemie

DFT

Reaktionsmechanismen

computational chemistry

quantum chemical modeling

twin polymerization

counter anion

tritylcarbene

rearrangement

barbiturate anions

nucleophilicity

ambident reactivity

static quantum chemistry

DFT

ddc:541

Chemie

Quantenchemie

Modellierung

Strategies for Computational Investigation of Reaction Mechanisms in Organic and Polymer Chemistry Using Static Quantum Mechanics

Tchernook, Ivan

12 February 2016

This thesis presents computational studies of problems in the organic and polymer chemistry. The state-of-the art quantum chemical methods are used to gain further insight into the origin and the nature of the reactions in three different organic and polymer systems. The research questions are conceptually approached by identifying the key aspects. Then an appropriate strategy for the quantum chemical modeling is developed. In the scope of the polymer chemistry, the novel synthesis technique of nanostructured materials, the so-called twin polymerization, is investigated. Using three model systems of increasing complexity the influence of the anion (trifluoroacetate) in the reaction system is investigated. The effect of the solvent polarity as well as the effect of the entropic contributions are also considered. The rearrangement reaction of the volatile cyanotritylcarbenes is another topic. These carbenes readily rearrange to ethene main products, however also small amount of the unexpected heptafulvenes is formed. This unprecedented heptafulvene formation is modeled in detail and the energetics is systematically evaluated to identify most reasonable rearrangement pathways of the probable multiple alternative routes. Computational investigation of other tritylcarbenes with varying spectator substituents results in sophisticated data base for experimental investigations. At last, some controversial observations in experimental studies concerning the kinetics of the electrophilic alkylation of the barbiturate anion are studied. To interpret the kinetic measurements, different alkylation pathways are analyzed with respect to their energetics. Further, the influence of microsolvation is demonstrated.

info:eu-repo/classification/ddc/541

ddc:541

Chemie; Quantenchemie; Modellierung