ADVANCED INORGANIC CHEMISTRY

Degree course: 
Corso di Second cycle degree in CHEMISTRY
Academic year when starting the degree: 
2023/2024
Year: 
1
Academic year in which the course will be held: 
2023/2024
Course type: 
Compulsory subjects, characteristic of the class
Credits: 
6
Period: 
First Semester
Standard lectures hours: 
48
Detail of lecture’s hours: 
Lesson (48 hours)
Requirements: 

Solid knowledge of General and Inorganic Chemistry (especially the principles of Coordination Chemistry) and basic Organic Chemistry and Physical Chemistry are required.

Final Examination: 
Orale

The final evaluation will be based on an oral examination concerning the topics covered in the course. The final grade will be expressed in thirtieths.
In particular, in formulating the final grade, the lecturer will carefully evaluate the ability to discursively organize knowledge; rigor in exposition; the ability to critically reason about the study carried out; the quality of exposition, with particular reference to the use of specific language.
The lecturer will award praise when all the above components are met.

Assessment: 
Voto Finale

The course will provide students with an in-depth knowledge about several aspects related to homogeneous catalysis. The first part of the course (48 hours of classroom lessons) concerns the deepening of the main catalytic processes, from the synthetic and the mechanistic point of view, with attention both to laboratory-scale and to industrial processes. The second part (24 hours of laboratory experiments) will focus on the attainment of the aptitude of students to apply the previously acquired knowledge to practical experiments where they will prepare and characterize some organometallic catalysts and will use them in hydrogenation and/or C-C bond-forming catalytic reactions

1) Metal-ligand bonding in coordination compounds (8 h):
Crystal field theory and Russell-Saunders coupling scheme: term symbols for an isolated transition metal ion, term splitting in the presence of crystal field. Orgel diagrams, Racah parameters, Tanabe-Sugano diagrams and d-d transitions.
Angular Overlap Model: sigma e pi interactions, d orbitals splitting according to AOM.
2) Coordination and organometallic compounds: synthesis and main properties (20 h):
18 electron rule adn electron counting in complexes. Carbene complexes. Olefin complexes. Complexes with cyclic polyenes. N2 and O2 as ligands. Nitrosyl complexes.
3) Coordination and organometallic compounds reactivity (20 h):
Ligand substitution reactions. Oxidative addition and reductive elimination. Migratory-insertion reactions. Introduction to homogeneous catalysis.

1) Metal-ligand bonding in coordination compounds (8 h):
Crystal field theory and Russell-Saunders coupling scheme: term symbols for an isolated transition metal ion, term splitting in the presence of crystal field. Orgel diagrams, Racah parameters, Tanabe-Sugano diagrams and d-d transitions.
Angular Overlap Model: sigma e pi interactions, d orbitals splitting according to AOM.
2) Coordination and organometallic compounds: synthesis and main properties (20 h):
18 electron rule adn electron counting in complexes. Carbene complexes. Olefin complexes. Complexes with cyclic polyenes. N2 and O2 as ligands. Nitrosyl complexes.
3) Coordination and organometallic compounds reactivity (20 h):
Ligand substitution reactions. Oxidative addition and reductive elimination. Migratory-insertion reactions. Introduction to homogeneous catalysis.

Classroom lectures with the aid of power-point projections.

Office hours
Daily, 10 a.m. to noon and 2 p.m. to 5 p.m.

Professors