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Measurements and significant figures, chemical reactions; stoichiometry; the gaseous state; thermochemistry; electronic structure and periodicity; chemical bonding; molecular shapes; states of matter and intermolecular forces.
First Year
  
Physical properties of solutions; chemical kinetics; chemical equilibrium; acids and bases; acid-base equilibria in aqueous solutions; solubility and complex ion equilibria; chemical thermodynamics; electrochemistry.
Second Year
  

Hydrogen-like wave functions; polyelectronic systems; energy states; shielding and atomic properties;  symmetry and character table; ionic bonding: lattice energy, packing and ionic sizes, Born-Haber cycle and applications; covalent bonding: valence bond theory, molecular orbital theory; electronegativity; structure and reactivity; chemical forces.

 

Second Year
  
Some aspects of molecular structure and bonding; chemistry of hydrogen; chemistry of the main group elements: groups: IA (alkali); IIA (alkaline earth); IIIA-VIA-VIA; VIIA (halogens); VIII (noble gases); Jordanian ores: metallurgy and applications.
Third Year
  
Safety and laboratory rules; chemical observations; Avogadro’s number; stoichiometry; volumetric analysis; oxidation and reduction; colligative properties; thermochemistry and equilibrium.
Third Year
  
 Introduction to Chemistry, Stoichiometry, Reactions in Aqueous Solutions, Gases, Energy Relationships in Chemical Reactions, Electronic Structure of Atoms, Chemical Bonding I : The Covalent Bond, Chemical Bonding II : Molecular Geometry and Hybridization of Atomic Orbitals, Intermolecular forces and Liquids & Solids, Physical Properties of Solutions, Chemical Kinetics, Chemical Equilibria, Acids and Bases, Acid-Base Equilibria and Solubility Equilibria, Thermodynamics.
First Year
  
Introduces the chemistry of carbon to transition-metal bonds beginning with rules governing structure and stability; effects of metal and ancillary ligand environment; general mechanistic steps; NMR and IR spectroscopy; fluxional processes. Followed by applications in homogeneous catalysis and stoichiometric organic synthesis.
Fouth Year