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Technical Webinars
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Webinar Topic: Discovery of Sustainable Catalytic Asymmetric Reactions
09 August 2024
Research Topics
Asymmetric Synthesis
Catalysis and Inorganic Chemistry
Reactions
Metal Catalysts
Ligands
Directing Groups
Photoredox Catalysts
Summary
The demand for enantiopure or enantioenriched chiral molecules in various industrial sectors, mainly pharmaceutical, agrochemical, cosmetic, food chemistry, and material science, has driven significant advancements in asymmetric synthesis, and particularly asymmetric catalysis, during recent decades. The discovery of sustainable catalytic asymmetric reactions has gained attention among academic and industrial research due to environmental concerns. Particularly, organic synthesis laboratories and pharmaceutical industries are focused on developing sustainable catalytic asymmetric reaction processes involving reduced amounts of hazardous reagents and solvents, fewer purification steps, and low energetic consumption.
The demand for enantiopure or enantioenriched chiral molecules in various industrial sectors, mainly pharmaceutical, agrochemical, cosmetic, food chemistry, and material science, has driven significant advancements in asymmetric synthesis, and particularly asymmetric catalysis, during recent decades. The discovery of sustainable catalytic asymmetric reactions has gained attention among academic and industrial research due to environmental concerns. Particularly, organic synthesis laboratories and pharmaceutical industries are focused on developing sustainable catalytic asymmetric reaction processes involving reduced amounts of hazardous reagents and solvents, fewer purification steps, and low energetic consumption.
TCI Product Links
- Asymmetric Synthesis
- Catalysis and Inorganic Chemistry
- C-H Bond Activation Action
- Metal Catalysts - Palladium, Rhodium, Ruthenium, Iridium, Cobalt, Manganese, Iron
- Ligands
- Directing Groups
- Photoredox Catalysts
Speaker Bio
Prof. Dhevalapally B. Ramachary, FTAS, FRSC, FASc, FNASc
School of Chemistry, University of Hyderabad
Webinar Topic: C-H Bond Activation
07 January 2022
Research Topics
Reactions
Metal Catalysts
Ligands
Oxidants
Directing Groups
Photoredox Catalysts
You can see the webinar content in the following link.
C-H Bond Activation Link: (PDF file)
Summary
C-H bond activation is a methodology for directly forming carbon-carbon bonds by activating a carbon-hydrogen bond, which is the most fundamental linkage in organic chemistry.C-H activation is defined as the cleavage of unreactive C-H bond, followed by C-C or C-X (X=N,O,S) bond formation to give rise to a desired functionalized molecule.
TCI Product Links
- C-H Bond Activation Action
- Metal Catalysts - Palladium, Rhodium, Ruthenium, Iridium, Cobalt, Manganese, Iron
- Ligands
- Directing Groups
- Photoredox Catalysts
Speaker Bio
Dr. Donka Rajashekar
Postdoctoral from UFS-South Africa-Specialization in Chemistry
Webinar Topic: Organic Transistors
26 November 2020
Research Topics
Materials Science
Nanotechnology
Organic Electronics
Organic Transistors
You can see the webinar content in the following link.
Technical Webinar Presentation Document (PDF file)
Summary
Organic semiconductors have been receiving much attention as promising materials for “printed electronics” owing to their flexibility and solubility. TCI offers several special reagents of guaranteed very high-quality for these purposes, including typical and cutting-edge semiconducting materials utilized for organic field effect transistors (OFET), organic photovoltaics (OPV), or organic electroluminescence devices (OLED). We continue to recognize and value the real performance of our materials research products as a quality standard, wherein conventional analytical methods are not accurate enough to reveal performance deficiencies due to impurities.
TCI Product Links
- Organic Transistor (OFET) Materials
- High-Mobility/High-Solubility p-Type Organic Semiconductor Ph-BTBT-n Series
- High Performance S-shaped Organic Semiconductor S-DNTT-10
- High Mobility n-Type Semiconductors TU-1, TU-3
- p-Type Organic Semiconductor: High-purity and High-performance Pentacene
- Super Performance Organic Semiconductor: Ph-BTBT-10
- Stable p-Type Organic Semiconductor: Dimethylanthradithiophene (DMADT)
- n-Type Semiconductor Materials - Soluble Fullerene Derivatives
Speaker Bio
Dr. Yuji Yamaguchi
Team Leader,
Device Evaluation Team,
Organic Electronics Material Development,
Oji R&D
Career:
2013 : Ph.D. degree in engineering at Yamagata university.
2013 - 2016 : Postdoctoral researcher, JST-CREST, Yamagata University.
2016 - Present : Tokyo Chemical Industry Co., LTD. (TCI).
Webinar Topic: Chemistry/Analytical Chemistry
14 & 16 October 2020
Contents
Cross Coupling Reactions
Presentation Document for Cross Coupling Reactions (PDF file)
Asymmetric Synethesis
Coming Soon!
GC Derivatization Reagents
Coming Soon!
Summary
Cross-coupling reactions are a subset of coupling reactions, and is often used in arylations. Its mechanism includes Oxidative addition, Transmetallation and Reductive eliminations. TCI offers a wide range of transition metal catalysts to support your research. The mechanism of the Suzuki reaction is best viewed from the perspective of the palladium catalyst. This is used for General organic synthesis, synthesis of compounds having pharmacological activity, material synthesis of electronic materials. TCI introduces different varieties of reaction partners in addition to the organoboron compounds, such as metal catalysts and phosphine ligands to explore the versatile applicability of the Suzuki-Miyaura cross-coupling reaction.