Efficient Hydrocarbon Reactions in Orga

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Informationen zum Autor Dr. Ruimao Hua is a Professor of Chemistry at the Department of Chemistry, Tsinghua University (TU) in Beijing, China. Having obtained his PhD degree from Tokyo Institute of Technology, he spent six years working at AIST in Japan before taking up his present appointment at TU. Professor Hua has over 110 published scientific papers and more than 120 authorized patents contributing to organic synthetic methodologies and organic materials for displays (liquid crystal display & OLED display). He is also the member of editorial board of several academic journals. Klappentext This book is not only a comprehensive overview of efficient synthetic methodologies using unsaturated hydrocarbons as starting materials, but also a collection of conceptual and practical hints for designing the high atom efficient reactions for synthesis of functionalized molecules. It is a valuable resource for researchers and chemists from academia and industry wishing to refresh their knowledge, as well as an excellent reference for chemistry majors. Inhaltsverzeichnis Chapter 1. Dimerization of Alkynes and Alkenes1.1 Markovnikov Dimerization of Terminal Alkynes1.2 anti-Markovnikov (head-to-head) Dimerization of Terminal Alkynes1.3 Dimerization and Cross-dimerization of Terminal Alkenes1.4 Cross-Dimerization of Different Alkynes or Alkynes with AlkenesChapter 2. Addition of C(sp)-H Bonds to Unsaturated Compounds2.1 Addition of Terminal Alkynes to Carbonyl Compounds2.2 Addition of Terminal Alkynes to Alkenes2.3 Addition of Terminal Alkynes to Imines2.4 Addition of Terminal Alkynes to Other CompoundsChapter 3. Functionalized Alkenes from Hydrofunctionalization of Alkynes3.1 Hydroborations of Alkynes3.2 Hydrosilylation of Alkynes3.3 Hydrostannation of Alkynes3.4 Hydroamination of Alkynes3.4.1 Hydroamination of alkynes with primary amines3.4.2 Hydroamination of alkynes with secondary amines3.4.3 Cyclohydroamination of alkynes3.4.4 Aminocarbonylation of alkynes3.5 Hydrophosphination of Alkynes and Related H-P(O) Addition3.5.1 Hydrophosphination of Alkynes3.5.2 Addition of PV(O)-H bond to alkynes3.6 Hydrothiolation of Alkynes3.6.1 Markovnikov hydrothiolation of alkynes3.6.2 anti-Markovnikov hydrothiolation of alkynes3.7 Addition of O-Nucleophiles to Alkynes3.7.1 Addition of alcohols and phenols to alkynes3.7.2 Addition of acids to alkynesChapter 4. Hydrofunctionalization of Carbon-Carbon Double Bonds4.1 Hydroboration of Alkenes4.1.1 Markovnikov hydroboration of alkenes4.1.2 anti-Markovnikov hydroboration of alkenes4.1.3 Hydroboration of allenes and 1,3-dienes4.1.4 Asymmetric hydroboration of alkenes4.2 Hydrosilylation of Carbon-Carbon Double Bonds4.2.1 Markovnikov and anti-Markovnikov hydrosilylation of alkenes4.2.2 Hydrosilylation of allenes4.2.3 Hydrosilylation of 1,3-dienes4.2.4 Asymmetric hydrosilylation of alkenes4.3 Hydrostannation of Carbon-Carbon Double Bonds4.4 Hydroamination of Carbon-Carbon Double Bonds4.4.1 Markovnikov hydroamination of alkenes4.4.2 anti-Markovnikov hydroamination of alkenes4.4.3 Hydroamination of allenes and 1,3-dienes4.4.4 Asymmetric hydroamination of alkenes4.4.5 Nitrogen-heterocycles from intramolecular hydroamination of alkenes4.5 Hydrophosphination of Alkenes and Related PV(O)-H Addition4.6 Hydrothiolation of Carbon-Carbon Double Bonds4.7 Addition of O-Nucleophiles to AlkenesChapter 5. Double Functionalization of Alkynes and Alkenes by Addition of Element-Element Bonds5.1 Addition Reaction of Group 13 Element-Element Bonds5.1.1 cis-Addition reactions to alkynes5.1.2 trans-Addition reactions to alkynes5.1.3 Addition reactions to alkenes5.1.4 Synthesis of 1,1-diborylalkanes/alkenes via addition of B-B bond5.2 Addition Reaction of Group 14 Element-Element Bonds5.3 Addition Reaction of Group 15 Element-Element Bond5.4 Addition Reactions of Group 16 Element-Element Bond5.4.1 cis-Addition reactions to alkynes5.4.2 trans-Ad...

List of contents

Chapter 1. Dimerization of Alkynes and Alkenes
1.1 Markovnikov Dimerization of Terminal Alkynes
1.2 anti-Markovnikov (head-to-head) Dimerization of Terminal Alkynes
1.3 Dimerization and Cross-dimerization of Terminal Alkenes
1.4 Cross-Dimerization of Different Alkynes or Alkynes with Alkenes
Chapter 2. Addition of C(sp)-H Bonds to Unsaturated Compounds
2.1 Addition of Terminal Alkynes to Carbonyl Compounds
2.2 Addition of Terminal Alkynes to Alkenes
2.3 Addition of Terminal Alkynes to Imines
2.4 Addition of Terminal Alkynes to Other Compounds
Chapter 3. Functionalized Alkenes from Hydrofunctionalization of Alkynes
3.1 Hydroborations of Alkynes
3.2 Hydrosilylation of Alkynes
3.3 Hydrostannation of Alkynes
3.4 Hydroamination of Alkynes
3.4.1 Hydroamination of alkynes with primary amines
3.4.2 Hydroamination of alkynes with secondary amines
3.4.3 Cyclohydroamination of alkynes
3.4.4 Aminocarbonylation of alkynes
3.5 Hydrophosphination of Alkynes and Related H-P(O) Addition
3.5.1 Hydrophosphination of Alkynes
3.5.2 Addition of PV(O)-H bond to alkynes
3.6 Hydrothiolation of Alkynes
3.6.1 Markovnikov hydrothiolation of alkynes
3.6.2 anti-Markovnikov hydrothiolation of alkynes
3.7 Addition of O-Nucleophiles to Alkynes
3.7.1 Addition of alcohols and phenols to alkynes
3.7.2 Addition of acids to alkynes
Chapter 4. Hydrofunctionalization of Carbon-Carbon Double Bonds
4.1 Hydroboration of Alkenes
4.1.1 Markovnikov hydroboration of alkenes
4.1.2 anti-Markovnikov hydroboration of alkenes
4.1.3 Hydroboration of allenes and 1,3-dienes
4.1.4 Asymmetric hydroboration of alkenes
4.2 Hydrosilylation of Carbon-Carbon Double Bonds
4.2.1 Markovnikov and anti-Markovnikov hydrosilylation of alkenes
4.2.2 Hydrosilylation of allenes
4.2.3 Hydrosilylation of 1,3-dienes
4.2.4 Asymmetric hydrosilylation of alkenes
4.3 Hydrostannation of Carbon-Carbon Double Bonds
4.4 Hydroamination of Carbon-Carbon Double Bonds
4.4.1 Markovnikov hydroamination of alkenes
4.4.2 anti-Markovnikov hydroamination of alkenes
4.4.3 Hydroamination of allenes and 1,3-dienes
4.4.4 Asymmetric hydroamination of alkenes
4.4.5 Nitrogen-heterocycles from intramolecular hydroamination of alkenes
4.5 Hydrophosphination of Alkenes and Related PV(O)-H Addition
4.6 Hydrothiolation of Carbon-Carbon Double Bonds
4.7 Addition of O-Nucleophiles to Alkenes
Chapter 5. Double Functionalization of Alkynes and Alkenes by Addition of Element-Element Bonds
5.1 Addition Reaction of Group 13 Element-Element Bonds
5.1.1 cis-Addition reactions to alkynes
5.1.2 trans-Addition reactions to alkynes
5.1.3 Addition reactions to alkenes
5.1.4 Synthesis of 1,1-diborylalkanes/alkenes via addition of B-B bond
5.2 Addition Reaction of Group 14 Element-Element Bonds
5.3 Addition Reaction of Group 15 Element-Element Bond
5.4 Addition Reactions of Group 16 Element-Element Bond
5.4.1 cis-Addition reactions to alkynes
5.4.2 trans-Addition reactions to alkynes
5.4.3 Different heteroatom bond addition reactions to alkynes
5.4.4 Addition reactions to alkenes
5.5 Addition Reactions of Element-Element Bonds from Different Group Heteroatoms
5.5.1 cis-Addition reactions to alkynes
5.5.2 trans-Addition reactions to alkynes
5.5.3 Addition reactions to alkenes
Chapter 6. Double Functionalization of Alkynes by Addition of Carbon-Element Bonds
6.1 Addition Reactions of Carbon-Group 13 Bonds
6.2 Addition Reactions of Carbon-Group 14 Bonds
6.2.1 Addition reactions of carbon-silicon bonds
6.2.2 Addition reactions of carbon-germanium bonds
6.2.3 Addition reactions of carbon-tin bonds
6.3 Addition Reactions of Carbon-Group 15 Bonds
6.4 Addition Reactions of Carbon-Group 16 Bonds
6.4.1 Addition reactions of carbon-oxygen bonds
6.4.2 Addition reaction of carbon-sulfur bonds
6.4.3 Addition reactions of carbon-seleni