Co-ordination Compounds – Inorganic Chemistry
Co-ordination Compounds – Inorganic Chemistry, available at $54.99, has an average rating of 4.75, with 29 lectures, based on 4 reviews, and has 22 subscribers.
You will learn about Appreciate the postulates of Werner’s theory of coordination compounds Know the meaning of the terms: coordination entity, central atom/ ion, ligand, coordination number, coordination sphere, coordination polyhedron, oxidation numb Learn the rules of nomenclature of coordination compounds Write the formulas and names of mononuclear coordination compounds Define different types of isomerism in coordination compounds Understand the nature of bonding in coordination compounds in terms of the Valence Bond and Crystal Field theories Appreciate the importance and applications of coordination compounds in our day to day life This course is ideal for individuals who are Parents whose wards are Students preparing for Indian Engineering and Medical entrance Exams or IIT JEE | JEE Main | JEE Advanced | BITSAT | NEET | AIPMT | KVPY | SAT | GATE | MSAT It is particularly useful for Parents whose wards are Students preparing for Indian Engineering and Medical entrance Exams or IIT JEE | JEE Main | JEE Advanced | BITSAT | NEET | AIPMT | KVPY | SAT | GATE | MSAT.
Enroll now: Co-ordination Compounds – Inorganic Chemistry
Summary
Title: Co-ordination Compounds – Inorganic Chemistry
Price: $54.99
Average Rating: 4.75
Number of Lectures: 29
Number of Published Lectures: 29
Number of Curriculum Items: 29
Number of Published Curriculum Objects: 29
Original Price: ₹1,199
Quality Status: approved
Status: Live
What You Will Learn
- Appreciate the postulates of Werner’s theory of coordination compounds
- Know the meaning of the terms: coordination entity, central atom/ ion, ligand, coordination number, coordination sphere, coordination polyhedron, oxidation numb
- Learn the rules of nomenclature of coordination compounds
- Write the formulas and names of mononuclear coordination compounds
- Define different types of isomerism in coordination compounds
- Understand the nature of bonding in coordination compounds in terms of the Valence Bond and Crystal Field theories
- Appreciate the importance and applications of coordination compounds in our day to day life
Who Should Attend
- Parents whose wards are Students preparing for Indian Engineering and Medical entrance Exams
- IIT JEE | JEE Main | JEE Advanced | BITSAT | NEET | AIPMT | KVPY | SAT | GATE | MSAT
Target Audiences
- Parents whose wards are Students preparing for Indian Engineering and Medical entrance Exams
- IIT JEE | JEE Main | JEE Advanced | BITSAT | NEET | AIPMT | KVPY | SAT | GATE | MSAT
SUMMARY
The chemistry of coordination compounds is an important and challenging area of modern inorganic chemistry. During the last fifty years, advances in this area, have provided development of new concepts and models of bonding and molecular structure, novel breakthroughs in chemical industry and vital insights into the functioning of critical components of biological systems.
The first systematic attempt at explaining the formation, reactions, structure and bonding of a coordination compound was made by A. Werner. His theory postulated the use of two types of linkages (primary and secondary) by a metal atom/ion in a coordination compound. In the modern language of chemistry these linkages are recognised as the ionisable (ionic) and non-ionisable (covalent) bonds, respectively. Using the property of isomerism, Werner predicted the geometrical shapes of a large number of coordination entities.
The Valence Bond Theory (VBT) explains with reasonable success, the formation, magnetic behaviour and geometrical shapes of coordination compounds. It, however, fails to provide a quantitative interpretation of magnetic behaviour and has nothing to say about the optical properties of these compounds.
The Crystal Field Theory (CFT) to coordination compounds is based on the effect of different crystal fields (provided by the ligands taken as point charges), on the degeneracy of d orbital energies of the central metal atom/ion. The splitting of the d orbitals provides different electronic arrangements in strong and weak crystal fields. The treatment provides for quantitative estimations of orbital separation energies, magnetic moments and spectral and stability parameters. However, the assumption that ligands consititute point charges creates many theoretical difficulties.
The metal–carbon bond in metal carbonyls possesses both σ and π character. The ligand to metal is σ bond and metal to ligand is π bond. This unique synergic bonding provides stability to metal carbonyls.
Coordination compounds are of great importance. These compounds provide critical insights into the functioning and structures of vital components of biological systems. Coordination compounds also find extensive applications in metallurgical processes, analytical and medicinal chemistry.
Course Curriculum
Chapter 1: CO-ORDINATION COMPOUNDS
Lecture 1: Werner's Theory
Lecture 2: Double Salts and Coordination Compound
Lecture 3: Ligands and Classification of Ligands Part – 1
Lecture 4: Ligands and Classification of Ligands Part – 2
Lecture 5: Chelating Ligands
Lecture 6: Co-ordination Number
Lecture 7: Types of Complex
Lecture 8: Effective Atomic Number
Lecture 9: Isomerism in Co-ordination Complexes Introduction
Lecture 10: Structural Isomerism
Lecture 11: Geometrical Isomerism Part -1
Lecture 12: Geometrical Isomerism Part – 2
Lecture 13: Optical Isomerism
Lecture 14: Valence Bond Theory Part – 1
Lecture 15: Valence Bond Theory Part – 2
Lecture 16: Valence Bond Theory Part – 3
Lecture 17: Limitations of VBT
Lecture 18: Crystal Field Theory Part-1
Lecture 19: Crystal Field Theory Part-2
Lecture 20: Crystal Field Theory Part – 3
Lecture 21: Limitations of CFT
Lecture 22: Stability of Coordination Complexes
Lecture 23: Application of Co-ordination Compounds
Lecture 24: IUPAC Nomenclature Part-1
Lecture 25: IUPAC Nomenclature Part – 2
Lecture 26: Distribution of Electrons in Splitted d-orbitals
Lecture 27: Bonding in Metal Carbonyls
Lecture 28: Colour of Coordination Complexes
Lecture 29: Magnetic Nature of Co-ordination Complexes
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