On-Surface Cyclization of ortho-Dihalotetracenes to Four- and Six-Membered Rings

Sánchez-Sánchez, Carlos, Nicolaï, Adrien, Rossel, Frédéric, Cai, Jinming, Liu, Junzhi, Feng, Xinliang, Müllen, Klaus, Ruffieux, Pascal, Fasel, Roman, Meunier, Vincent

06 January 2020

We report on the surface-catalyzed formal [2+2] and [2+2+2] cycloadditions of ortho-activated tetracene species on a Ag(111) substrate under ultrahigh vacuum conditions. Three different products are obtained: tetracene dimers, trimers, and tetramers. The former results from the formation of a four-membered ring while the other two arise from cyclization into six-membered rings. These on-surface reactions have been monitored by scanning tunneling microscopy and rationalized by density functional theory calculations. Our approach, based on the reaction of ortho-dihalo precursor monomers via formal cycloadditions, establishes an additional method for the highly active field of on-surface synthesis and enables the development of novel 1D and 2D covalent carbon nanostructures.

Surface, Cyclization, Dihalotetracenes

info:eu-repo/classification/ddc/540

ddc:540

Synthese neuer Furo[3,2-a]- und Pyrano[3,2-a]carbazolalkaloide

Spindler, Benedikt

17 September 2020

Für die Synthese neuer Furo[3,2-a]- und Pyrano[3,2-a]carbazolalkaloide wurde eine Sequenz aus oxidativer Cyclisierung verschiedener Diarylamine verwendet. Über diese Strategie konnten drei verschiedene Furo[3,2-a]carbazole dargestellt werden und aufgrund eines Vergleichs der analytischen Daten eine fehlerhafte Strukturzuweisung bei der Isolierung zweier dieser Verbindungen aus natürlichen Quellen festgestellt werden. Die Synthese von Furoclausin-B konnte durch diese Strategie erfolgreich durchgeführt werden und führte ferner zur Aufklärung der absoluten Konfiguration dieser Verbindung. Desweiteren konnte über eine ähnliche Synthesestrategie die racemische Synthese zweier Pyrano[3,2-a]carbazole erfolgen, namentlich Guillauminin-B und Clausin-T. Durch Studien zur enantioselektiven Epoxidierung konnte die Grundlage für eine zukünftige enantioselektive Synthese dieser Verbindungen gelegt werden.

info:eu-repo/classification/ddc/540

ddc:540

Palladium-Catalyzed Synthesis of Alkylcarbazoles and Their Identification in Petroleum and Source Rocks

Theumer, Gabriele, Bauer, Ingmar, Jäger, Anne, Schwark, Lorenz, Knölker, Hans-Joachim

18 April 2024

We describe the synthesis of seven C2-alkylcarbazoles via a sequence of Buchwald–Hartwig coupling of arylamines with aryl halides followed by oxidative cyclization of the resulting diarylamines. Methyl groups at the positions 4 and 5 were introduced by taking advantage of the ortho-directed palladation of meta-pivaloyloxy-substituted diarylamines and subsequent conversion of the pivaloyloxy to methyl groups through Stille coupling of intermediate triflates. The obtained ethyl- and dimethylcarbazoles served as analytical standards for their identification in petroleum samples and source rocks.

info:eu-repo/classification/ddc/540

ddc:540

Cyclisierungsreaktionen mehrfach ungesättigter Systeme - Theorie und Experiment / Cyclization Reactions of Polyunsaturated Systems - Theory and Experiment

Prall, Matthias

20 June 2002

No description available.

000 Allgemeines

Wissenschaft

Mathematics and Computer Science

Cyclisierung

Computerchemie

Biradikal

Endiin

Bergman-Reaktion

cyclization

computational chemistry

biradical

enediyne

Bergman reaction

35.00

35.06

35.11

35.52

SF000

SUB000

SUD000

SUD450

SUD900

SUH800

SUJ200

SUL200

SUS000

Ferrocenyl-Alkynes and Butadiynes: Reaction Behavior towards Cobalt and Iron Carbonyl Compounds / Ferrocenyl-Alkine und Butadiine: Reaktionsverhalten gegenüber Cobalt- und Eisencarbonyl-verbindungen

Filipczyk, Grzegorz Paweł

22 December 2017

Die vorliegende Dissertation beschreibt die Synthese und Charakterisierung von neuartigen perferrocenylierten, cyclischen Komplexen unter Anwendung der Cobalt-vermittelten Cyclomerisierung in Kombination mit einer C-H-Bindungsaktivierung als auch die Bildung von ferrocenylierten Phosphinoalkinid-Komplexen mit Eisen- und Cobaltcarbonylen. Die elektrochemischen Eigenschaften und die Elektronentransfer-prozesse zwischen den terminalen Ferrocenyleinheiten in den unterschiedlichen cyclischen Verbindungen wurden unter Einbeziehung der Struktur/chemischen Zusammensetzung der Brückenbausteine ermittelt. Elf perferrocenylierte, cyclische Komplexe wurden mittels [2+2] bzw. [2+2+2] Cyclomerisierung von 1,4-Diferrocenylbutadiin FcC≡C–C≡CFc (Fc = Fe(η5-C5H4)(η5-C5H5)) unter Verwendung von Dicarbonylcyclopentadienylcobalt Co(η5-C5H5)(CO)2 erhalten. Diese können in drei Gruppen unterteilt werden: (i) Produkte der Cyclodimerisierung mit zusätzlicher Kettenverlängerung, welche Cyclobutadienyl-einheiten als zentrale Brückenbausteine besitzen (3a,b und 4a,b), (ii) Produkte der Cyclodimerisierung mit gleichzeitiger CO-Insertion (6a,b,c und 7), und (iii) Produkte der Cyclotrimerisierung gefolgt von einem Ringschluss durch eine C-H-Bindungsaktivierung (5a,b,c). Die Optimierung der Reaktionsbedingungen wurde zur Ausbeutemaximierung der jeweiligen Verbindungsfamilien durchgeführt. Ein weiterer Teil dieser Forschungsarbeit bezieht sich auf die verschiedenen Reaktionsmuster von (Ferrocenylethinyl)diphenylphosphan- mit zweikernigen Eisen- bzw. Cobaltcarbonylverbindungen in Form von Dieisennonacarbonyl und Dicobaltoctacarbonyl als Reagenzien. Dabei konnten sechs gemischte Carbonyl- und Ferrocenyl-funktionalisierte Phosphinoacetylid-Komplexe mit Eisen(0) und Cobalt(0) erhalten und charakterisiert werden. / The present PhD study focuses on the synthesis and characterization of novel perferrocenylated cyclic complexes utilizing cobalt - mediated cyclomerization in combination with C–H bond activation as well as formation of ferrocenylated phosphino-alkyne compounds with iron and cobalt carbonyls. Electrochemical properties and electron-transfer processes between terminal ferrocenyl units in the diverse cyclic compounds are explored in relation to the chemical composition of the building blocks connecting them. Eleven perferrocenylated cyclic compounds were obtained via [2 + 2] and [2 + 2 + 2] cyclomerization of 1,4-diferrocenylbutadiyne FcC≡C–C≡CFc (Fc = Fe(η5-C5H4)(η5-C5H5)) by the reaction with dicarbonylcyclopentadienylcobalt Co(η5-C5H5)(CO)2. They are subdivided into three groups: (i) products of cyclodimerization with additional chain extension, possessing cyclobutadienyl moieties as a central linkage unit (3a,b and 4a,b), (ii) products of cyclodimerization with consecutive CO insertion (6a,b,c and 7), and (iii) products of cyclotrimerization followed by cycle formation via C–H bond activation (5a,b,c). Optimization of the reaction conditions was made in order to maximize the amount of each group of compounds. Furthermore, another part of this research work focuses on diverse reaction patterns of (ferrocenylethynyl)diphenylphosphane with diironnonacarbonyl and dicobaltocta-carbonyl. Six mixed carbonyl and ferrocenyl-functionalized phospinoalkynyl compounds of iron(0) and cobalt(0) were obtained and characterized.

Alkin

Cyclisierung

C–H Aktivierung

Eisencarbonyl

Cobaltcarbonyl

Phospinoalkin

P–C Bindungsspaltung

Spektro-Elektrochemie

Iron

Cobalt

Ferrocene

Alkyne

Cyclization

C–H Activation

Iron Carbonyl

Cobalt Carbonyl

Phospinoalkyne

P–C Bond Cleavage

Electrochemistry

Spectro-electrochemistry.

ddc:540

Eisen

Cobalt

Ferrocen

Alkine

Cyclisation

Elektrochemie

Ferrocenyl-Alkynes and Butadiynes: Reaction Behavior towards Cobalt and Iron Carbonyl Compounds

Filipczyk, Grzegorz Paweł

04 December 2017

Die vorliegende Dissertation beschreibt die Synthese und Charakterisierung von neuartigen perferrocenylierten, cyclischen Komplexen unter Anwendung der Cobalt-vermittelten Cyclomerisierung in Kombination mit einer C-H-Bindungsaktivierung als auch die Bildung von ferrocenylierten Phosphinoalkinid-Komplexen mit Eisen- und Cobaltcarbonylen. Die elektrochemischen Eigenschaften und die Elektronentransfer-prozesse zwischen den terminalen Ferrocenyleinheiten in den unterschiedlichen cyclischen Verbindungen wurden unter Einbeziehung der Struktur/chemischen Zusammensetzung der Brückenbausteine ermittelt. Elf perferrocenylierte, cyclische Komplexe wurden mittels [2+2] bzw. [2+2+2] Cyclomerisierung von 1,4-Diferrocenylbutadiin FcC≡C–C≡CFc (Fc = Fe(η5-C5H4)(η5-C5H5)) unter Verwendung von Dicarbonylcyclopentadienylcobalt Co(η5-C5H5)(CO)2 erhalten. Diese können in drei Gruppen unterteilt werden: (i) Produkte der Cyclodimerisierung mit zusätzlicher Kettenverlängerung, welche Cyclobutadienyl-einheiten als zentrale Brückenbausteine besitzen (3a,b und 4a,b), (ii) Produkte der Cyclodimerisierung mit gleichzeitiger CO-Insertion (6a,b,c und 7), und (iii) Produkte der Cyclotrimerisierung gefolgt von einem Ringschluss durch eine C-H-Bindungsaktivierung (5a,b,c). Die Optimierung der Reaktionsbedingungen wurde zur Ausbeutemaximierung der jeweiligen Verbindungsfamilien durchgeführt. Ein weiterer Teil dieser Forschungsarbeit bezieht sich auf die verschiedenen Reaktionsmuster von (Ferrocenylethinyl)diphenylphosphan- mit zweikernigen Eisen- bzw. Cobaltcarbonylverbindungen in Form von Dieisennonacarbonyl und Dicobaltoctacarbonyl als Reagenzien. Dabei konnten sechs gemischte Carbonyl- und Ferrocenyl-funktionalisierte Phosphinoacetylid-Komplexe mit Eisen(0) und Cobalt(0) erhalten und charakterisiert werden.:Table of contents Bibliografische Beschreibung und Referat iii Abstract iv Ort und Zeitraum der Durchführung v Widmung vi Präambel vii List of Abbreviations xii CHAPTER A Introduction 15 References 16 CHAPTER B State of Knowledge 19 1 (Spectro)electrochemical studies of mixed-valent transition metal complexes. Theoretical background 19 1.1 Mixed-valent compounds – classification 20 1.2 Spectroelectrochemistry 21 1.3 Electrochemistry 25 2 (Di)ferrocenylalkynes – synthesis and reactions 28 2.1 1,4-Diferrocenylbutadiyne 29 2.2 Other (poly)ferrocenyl substituted alkyne derivatives 35 3 Dicarbonylcyclopentadienylcobalt – [2+2] and [2+2+2] cyclo-addition reactions 37 3.1 [2+2] and [2+2+2] cycloaddition – cyclobutadiene, cyclopentadienone, benzene and pyridine based systems 38 3.2 Mechanism of [2+2] and [2+2+2] cycloaddition/cyclization and [2+2] cycloaddition/cyclization with CO insertion mediated by CoCp(CO)2 40 4 Chelation-assisted C–H bond activation mediated by cobalt species 42 5 Phosphinoalkynes and their reaction with iron and cobalt carbonyls 44 5.1 Mechanism of the P–C(sp) bond cleavage in phosphinoalkynes 48 6 Complexes setup by (ferrocenylethynyl)diphenylphosphane 50 References 56 CHAPTER C Multiferrocenyl Cobalt-Based Sandwich Compounds 64 1 Introduction 64 2 Results and Discussion 65 2.1 Synthesis and Characterization 65 2.2 Solid-State Structures 71 2.3 Electrochemistry 73 2.4 Spectroelectrochemistry 76 3 Experimental Section 79 3.1 Instrumentation 79 3.2 General Conditions 81 3.3 Reagents 81 3.4 General Procedure - Reaction of 1 with 2 81 3.4.1 Compound 3a 82 3.4.2 Compound 3b 82 3.4.3 Compound 4b 83 3.4.4 Compound 5c 83 3.4.5 Compound 6a 84 3.4.6 Compound 6b 84 3.4.7 Compound 6c 85 3.4.8 Compound 7 85 4 Supporting information 86 5 References 86 CHAPTER D Combining Cobalt-Assisted Alkyne Cyclotrimerization and Ring Formation through C–H Bond Activation: A “One-Pot” Approach to Complex Multimetallic Structures 91 1 Introduction 91 2 Results and Discussion 92 3 Experimental Section (Supporting information) 98 3.1 General Information 98 3.2 Starting Materials 98 3.3 Synthesis of 3a and 3b from 2 99 3.3.1 Complex 3a: 99 3.3.2 Complex 3b: 100 3.4 Synthesis of 9a and 9b from 1-Ferrocenylethynyl-2-Ferrocenyl Benzene (8) 101 3.4.1 Synthesis of 1-Bromo-2-Ferrocenylethynyl Benzene (7) 101 3.4.2 Synthesis of 1-Ferrocenylethynyl-2-Ferrocenyl Benzene (8) 102 3.4.3 Synthesis of 9a and 9b from 8 103 3.5 Synthesis of 3a and 3b from 1,3,5-Triethynylferrocenyl-2,4,6-Triferrocenyl Benzene (4) 105 3.5.1 Synthesis of 1,3,5-Trichloro-2,4,6-Triethynylferrocenyl Benzene (12) 105 3.5.2 Synthesis of 1,3,5-Triethynylferrocenyl-2,4,6-Triferrocenyl Benzene (4) 105 3.5.3 Synthesis of 3a and 3b from 4 106 4 Supporting information 107 4.1 Spectroelectrochemistry of 3a,b 107 4.2 Conversion of Isomer 9a to 9b – Electrochemical and Chemical oxidation 109 4.3 Chemical oxidation experiment 110 5 References 111 CHAPTER E Coordination Behavior of (Ferrocenylethynyl)diphenyl-phosphane Towards Binuclear Iron and Cobalt Carbonyls 114 1 Introduction 114 2 Results and Discussion 115 3 Experimental Section 126 3.1 Instrumentation 126 3.2 General 128 3.3 Reagents 128 3.4 Synthesis of 4 128 3.5 Synthesis of 4, 5 and 6 129 3.6 Synthesis of 6 by reacting 4 with 2 131 3.7 Synthesis of 7 and 8 131 3.8 Synthesis of 8 from 1 with 3 132 3.9 Synthesis of 9 in the reaction of 7 with 2 133 3.10 Synthesis of 9 in the reaction of 4 with 3 133 4 Electronic Supplementary Material (Supporting information) 134 5 References 134 CHAPTER F Summary 139 1 Conclusions of Chapter C (Appendix A) 139 2 Conclusions of Chapter D (Appendix B) 141 3 Conclusions of Chapter E (Appendix C) 142 Appendix 145 1 Appendix D (Chapter C) 145 2 Appendix E (Chapter D) 146 3 Appendix F (Chapter E) 147 Curriculum Vitae 150 Publications 152 Acknowledgements 154 Selbstständigkeitserklärung 155 / The present PhD study focuses on the synthesis and characterization of novel perferrocenylated cyclic complexes utilizing cobalt - mediated cyclomerization in combination with C–H bond activation as well as formation of ferrocenylated phosphino-alkyne compounds with iron and cobalt carbonyls. Electrochemical properties and electron-transfer processes between terminal ferrocenyl units in the diverse cyclic compounds are explored in relation to the chemical composition of the building blocks connecting them. Eleven perferrocenylated cyclic compounds were obtained via [2 + 2] and [2 + 2 + 2] cyclomerization of 1,4-diferrocenylbutadiyne FcC≡C–C≡CFc (Fc = Fe(η5-C5H4)(η5-C5H5)) by the reaction with dicarbonylcyclopentadienylcobalt Co(η5-C5H5)(CO)2. They are subdivided into three groups: (i) products of cyclodimerization with additional chain extension, possessing cyclobutadienyl moieties as a central linkage unit (3a,b and 4a,b), (ii) products of cyclodimerization with consecutive CO insertion (6a,b,c and 7), and (iii) products of cyclotrimerization followed by cycle formation via C–H bond activation (5a,b,c). Optimization of the reaction conditions was made in order to maximize the amount of each group of compounds. Furthermore, another part of this research work focuses on diverse reaction patterns of (ferrocenylethynyl)diphenylphosphane with diironnonacarbonyl and dicobaltocta-carbonyl. Six mixed carbonyl and ferrocenyl-functionalized phospinoalkynyl compounds of iron(0) and cobalt(0) were obtained and characterized.:Table of contents Bibliografische Beschreibung und Referat iii Abstract iv Ort und Zeitraum der Durchführung v Widmung vi Präambel vii List of Abbreviations xii CHAPTER A Introduction 15 References 16 CHAPTER B State of Knowledge 19 1 (Spectro)electrochemical studies of mixed-valent transition metal complexes. Theoretical background 19 1.1 Mixed-valent compounds – classification 20 1.2 Spectroelectrochemistry 21 1.3 Electrochemistry 25 2 (Di)ferrocenylalkynes – synthesis and reactions 28 2.1 1,4-Diferrocenylbutadiyne 29 2.2 Other (poly)ferrocenyl substituted alkyne derivatives 35 3 Dicarbonylcyclopentadienylcobalt – [2+2] and [2+2+2] cyclo-addition reactions 37 3.1 [2+2] and [2+2+2] cycloaddition – cyclobutadiene, cyclopentadienone, benzene and pyridine based systems 38 3.2 Mechanism of [2+2] and [2+2+2] cycloaddition/cyclization and [2+2] cycloaddition/cyclization with CO insertion mediated by CoCp(CO)2 40 4 Chelation-assisted C–H bond activation mediated by cobalt species 42 5 Phosphinoalkynes and their reaction with iron and cobalt carbonyls 44 5.1 Mechanism of the P–C(sp) bond cleavage in phosphinoalkynes 48 6 Complexes setup by (ferrocenylethynyl)diphenylphosphane 50 References 56 CHAPTER C Multiferrocenyl Cobalt-Based Sandwich Compounds 64 1 Introduction 64 2 Results and Discussion 65 2.1 Synthesis and Characterization 65 2.2 Solid-State Structures 71 2.3 Electrochemistry 73 2.4 Spectroelectrochemistry 76 3 Experimental Section 79 3.1 Instrumentation 79 3.2 General Conditions 81 3.3 Reagents 81 3.4 General Procedure - Reaction of 1 with 2 81 3.4.1 Compound 3a 82 3.4.2 Compound 3b 82 3.4.3 Compound 4b 83 3.4.4 Compound 5c 83 3.4.5 Compound 6a 84 3.4.6 Compound 6b 84 3.4.7 Compound 6c 85 3.4.8 Compound 7 85 4 Supporting information 86 5 References 86 CHAPTER D Combining Cobalt-Assisted Alkyne Cyclotrimerization and Ring Formation through C–H Bond Activation: A “One-Pot” Approach to Complex Multimetallic Structures 91 1 Introduction 91 2 Results and Discussion 92 3 Experimental Section (Supporting information) 98 3.1 General Information 98 3.2 Starting Materials 98 3.3 Synthesis of 3a and 3b from 2 99 3.3.1 Complex 3a: 99 3.3.2 Complex 3b: 100 3.4 Synthesis of 9a and 9b from 1-Ferrocenylethynyl-2-Ferrocenyl Benzene (8) 101 3.4.1 Synthesis of 1-Bromo-2-Ferrocenylethynyl Benzene (7) 101 3.4.2 Synthesis of 1-Ferrocenylethynyl-2-Ferrocenyl Benzene (8) 102 3.4.3 Synthesis of 9a and 9b from 8 103 3.5 Synthesis of 3a and 3b from 1,3,5-Triethynylferrocenyl-2,4,6-Triferrocenyl Benzene (4) 105 3.5.1 Synthesis of 1,3,5-Trichloro-2,4,6-Triethynylferrocenyl Benzene (12) 105 3.5.2 Synthesis of 1,3,5-Triethynylferrocenyl-2,4,6-Triferrocenyl Benzene (4) 105 3.5.3 Synthesis of 3a and 3b from 4 106 4 Supporting information 107 4.1 Spectroelectrochemistry of 3a,b 107 4.2 Conversion of Isomer 9a to 9b – Electrochemical and Chemical oxidation 109 4.3 Chemical oxidation experiment 110 5 References 111 CHAPTER E Coordination Behavior of (Ferrocenylethynyl)diphenyl-phosphane Towards Binuclear Iron and Cobalt Carbonyls 114 1 Introduction 114 2 Results and Discussion 115 3 Experimental Section 126 3.1 Instrumentation 126 3.2 General 128 3.3 Reagents 128 3.4 Synthesis of 4 128 3.5 Synthesis of 4, 5 and 6 129 3.6 Synthesis of 6 by reacting 4 with 2 131 3.7 Synthesis of 7 and 8 131 3.8 Synthesis of 8 from 1 with 3 132 3.9 Synthesis of 9 in the reaction of 7 with 2 133 3.10 Synthesis of 9 in the reaction of 4 with 3 133 4 Electronic Supplementary Material (Supporting information) 134 5 References 134 CHAPTER F Summary 139 1 Conclusions of Chapter C (Appendix A) 139 2 Conclusions of Chapter D (Appendix B) 141 3 Conclusions of Chapter E (Appendix C) 142 Appendix 145 1 Appendix D (Chapter C) 145 2 Appendix E (Chapter D) 146 3 Appendix F (Chapter E) 147 Curriculum Vitae 150 Publications 152 Acknowledgements 154 Selbstständigkeitserklärung 155

info:eu-repo/classification/ddc/540

ddc:540