Chiral Phosphorous Based Ligands in Earth-Abundant Transition Metal Catalysis
Junliang Zhang (Redaktør) ; Wenbo Li (Redaktør)
Chiral Phosphorous Based Ligands in Earth-Abundant Transition Metal Catalysis summarizes the most significant progress in
the field of chiral phosphine ligand chemistry and a broad range of earth-abundant transition metal/chiral phosphine ligand-catalyzed enantioselective transformations. Les mer
- Vår pris
- 2970,-
(Paperback)
Fri frakt!
Leveringstid:
Usikker levering*
*Vi bestiller varen fra forlag i utlandet.
Dersom varen finnes, sender vi den så snart vi får den til lager
Paperback
Legg i
Paperback
Legg i
Vår pris:
2970,-
(Paperback)
Fri frakt!
Leveringstid:
Usikker levering*
*Vi bestiller varen fra forlag i utlandet.
Dersom varen finnes, sender vi den så snart vi får den til lager
Chiral Phosphorous Based Ligands in Earth-Abundant Transition Metal Catalysis summarizes the most significant progress in
the field of chiral phosphine ligand chemistry and a broad range of earth-abundant transition metal/chiral phosphine ligand-catalyzed
enantioselective transformations. The book provides an authoritative and in-depth understanding of important topics about
asymmetric catalysis based on earth-abundant transition metals/chiral phosphine ligands, making it ideal for organic chemistry
researchers working in the field of asymmetric catalysis, synthetic methodologies and total synthesis.
The development of new chiral phosphine ligands to achieve precise stereo control in many earth-abundant transition metal-catalyzed reactions is a very important field in organic synthesis, materials science and medicinal chemistry. The asymmetric synthesis promoted by transition metal/chiral phosphine ligands provides one of the most ideal ways to produce valuable optically active chemicals.
The development of new chiral phosphine ligands to achieve precise stereo control in many earth-abundant transition metal-catalyzed reactions is a very important field in organic synthesis, materials science and medicinal chemistry. The asymmetric synthesis promoted by transition metal/chiral phosphine ligands provides one of the most ideal ways to produce valuable optically active chemicals.
- FAKTA
-
Utgitt:
2023
Forlag: Elsevier - Health Sciences Division
Innbinding: Paperback
Språk: Engelsk
ISBN: 9780323852258
Format: 23 x 15 cm
- KATEGORIER:
- VURDERING
-
Gi vurdering
Les vurderinger
1. Asymmetric transformations under iron catalysis
2. Asymmetric transformations under cobalt catalysis
3. Asymmetric transformations under nickel catalysis
4. Asymmetric transformations under copper catalysis
5. An outlook: roadmap for the future
2. Asymmetric transformations under cobalt catalysis
3. Asymmetric transformations under nickel catalysis
4. Asymmetric transformations under copper catalysis
5. An outlook: roadmap for the future
Prof. Junliang Zhang obtained his B.S. degree in Chemistry in 1997 from Tianjin University and PhD degree from the Shanghai
Institute of Organic Chemistry, Chinese Academy of Sciences in 2002 under the supervision of Prof. Shengming Ma. Then he worked
as a postdoctoral fellow successively in University of Cologne (Humboldt Fellowship) and then University of Chicago. In 2006,
he joined East China Normal University as a full professor. Then he moved to Fudan University in 2017 as professor of chemistry.
His recent research interests include enyne chemistry, small ring chemistry and recently focus on developing novel chiral
sulfinamide-based phosphine ligands in asymmetric catalysis. He has got several international awards, and published over 150
scientific articles and 5 book chapters. Dr. Wenbo Li obtained her B.S. degree in Chemistry in 2008 and PhD degree in 2013
from East China Normal University under the supervision of Professor Junliang Zhang. Then she began her academic career at
East China Normal University in Junliang Zhang’s research group and promoted to associate professor in 2016. Her research
focuses on the development of novel reactions and asymmetric transformations. She has authored/co-authored 24 papers and 2
book chapters.