This course will enable the students to
understand the fundamental concepts of atomic structure, comprehend the general characteristics of s, p, d, and f block elements including periodic trends in physical properties, acquire a thorough understanding of various bonding types in main group elements, explore the concept of hybridization, analyze the geometry of covalent molecules, and examine the shapes of atomic and molecular orbitals.
Course outcomes (COs):
Course |
Learning Outcome (at course level) |
Learning and Teaching Strategies |
Assessment Strategies |
|
Course Code |
Course title |
|||
24CCHY 111
|
Inorganic Chemistry I: Atomic Structure & Chemical Bonding (Theory) |
CO1: Describe the principles of quantum mechanics, interpret the graphical representations of atomic orbitals, and explain electronic configurations of atoms. CO2: Explain the periodicity of s and p block elements. Calculate effective nuclear charge using Slater’s rule and electronegativity using different scales. CO3: Discuss ionic and covalent bonding, predict the shapes of inorganic molecules and ions using VSEPR theory and hybridization. CO4: Construct molecular orbital diagrams of diatomic and triatomic molecules and determine the bond order. CO5: Discuss the different theories of metallic bonding, hydrogen bonding and Vander Waals interaction. CO6: Contribute effectively in course-specific interaction. |
Approach in teaching: Interactive lectures, tutorials, group discussions and e-learning.
Learning activities for the students: Peer learning, e-learning, problem solving through tutorials and group discussions.
|
Written examinations, assignments and quiz.
|
Bohr’s theory, its limitations and atomic spectrum of hydrogen atom. Wave mechanics: de Broglie equation, Heisenberg’s uncertainty principle and its significance, Schrödinger’s wave equation, significance of ψ and ψ², quantum numbers and their significance, normalized and orthogonal wave functions, sign of wave functions, radial and angular wave functions for hydrogen atom, radial and angular distribution curves, shapes of s, p, d and f orbitals, contour boundary and probability diagrams. Pauli’s exclusion principle, Hund’s rule of maximum multiplicity, Aufbau’s principle and its limitations, variation of orbital energy with atomic number.
s, p, d, f block elements, the long form of periodic table. Detailed discussion of the following properties of the elements, with reference to s and p-block:
Electronegativity, Pauling’s/ Mulliken’s/ Allred Rachow’s/ and Mulliken-Jaffé’s electronegativity scales, variation of electronegativity with bond order, partial charge, hybridization, group electronegativity, Sanderson’s electron density ratio.
Ionic bond: General characteristics, types of ions, size effects, radius ratio rule and its limitations,packing of ions in crystals, Born-Landé equation with derivation and importance of Kapustinskii expression for lattice energy, Madelung constant, Born-Haber cycle and its application, solvation energy.
Covalent bond: Lewis structure, Valence Bond theory (Heitler-London approach). energetics of hybridization, equivalent and non-equivalent hybrid orbitals, Bent’s rule, resonance and resonance energy, formal charge, Valence Shell Electron Pair Repulsion theory (VSEPR), shapes of simple molecules and ions containing lone pairs and bond pairs of electrons, multiple bonding (σ and π bond approach) and bond lengths, covalent character in ionic compounds, polarizing power and polarizability, Fajan’s rules and consequences of polarization.
Ionic character in covalent compounds: Bond moment and dipole moment, percentage ionic character from dipole moment and electronegativity difference.
LCAO approach, molecular orbital diagrams of diatomic and simple polyatomic molecules N2, O2, C2, B2, F2, CO, NO, and their ions, HCl, BeF2, CO2(idea of s-p mixing and orbital interaction to be given).
Metallic Bond: Qualitative idea of valence bond and band theories, semiconductors and insulators, defects in solids.
Weak Chemical Forces: van der Waals forces, ion-dipole forces, dipole-dipole interactions, induced dipole interactions, instantaneous dipole-induced dipole interactions, repulsive forces. Hydrogen bonding (theories of hydrogen bonding, valence bond treatment), effects of chemical force, melting and boiling points, solubility energetics of dissolution process.
e-Resources: