Q: What does SECS stand for and walk through drawing a Lewis structure using it.
A: SECS = Structure (draw skeleton — least electronegative atom in center, H always terminal), Electrons (count all valence electrons — add 1 per negative charge, subtract 1 per positive charge), Connect (place 2 electrons per bond between atoms), Satisfy (complete octets — start with outer atoms, then center; H needs only 2). Example: SO2 — S is center (less electronegative than O). Count: S(6) + O(6) + O(6) = 18 electrons. Connect: S-O-S uses 4. Remaining 14 fill octets. Check: S may need double bond. Result: O=S-O with lone pairs, S has 10 electrons (expanded octet allowed for period 3+).
Q: Explain VSEPR theory — what does it stand for and how do you predict molecular geometry?
A: VSEPR = Valence Shell Electron Pair Repulsion. Electron groups (bonding pairs AND lone pairs) repel each other and arrange to maximize separation. Count electron groups around central atom: 2 groups = linear (180°), 3 = trigonal planar (120°), 4 = tetrahedral (109.5°), 5 = trigonal bipyramidal, 6 = octahedral. Lone pairs compress bond angles more than bonding pairs. H2O: 4 electron groups (2 bonds + 2 lone pairs) = tetrahedral electron geometry but BENT molecular geometry (104.5°). NH3: 4 groups (3 bonds + 1 lone pair) = trigonal pyramidal (107°). Always distinguish electron geometry from molecular geometry.
Q: What are the three intermolecular forces (LDH) and what determines their relative strength?
A: LDH from weakest to strongest: London dispersion forces (L) — present in ALL molecules; caused by temporary dipoles from electron movement; strength increases with molecular size/surface area and number of electrons. Dipole-dipole forces (D) — in polar molecules; permanent dipoles attract; stronger than London for similar-sized molecules. Hydrogen bonding (H) — special strong dipole-dipole between H bonded to N, O, or F and a lone pair on N, O, or F on another molecule; explains water's unusually high boiling point. These forces explain boiling points, solubility ('like dissolves like'), and surface tension.
Q: What is hybridization and how do you determine it from a Lewis structure?
A: Hybridization is the mixing of atomic orbitals to form new equivalent orbitals for bonding. Count electron groups (bonding + lone pairs) around central atom: 2 = sp (linear, 180°), 3 = sp² (trigonal planar, 120°), 4 = sp³ (tetrahedral, 109.5°), 5 = sp³d (trigonal bipyramidal), 6 = sp³d² (octahedral). Key: double bonds count as ONE electron group. BF3 has 3 bonding groups = sp². CO2 (O=C=O) has 2 electron groups = sp. Ethylene (C2H4) each carbon has 3 groups (1 double + 2 single) = sp². Acetylene (C2H2) each carbon has 2 groups = sp. Hybridization determines geometry and bond angles.
Q: Compare ionic, covalent, and metallic bonding — properties of each.
A: Ionic bonding (metal + nonmetal): electron transfer creates cations and anions held by electrostatic attraction. Properties: high melting point, brittle, conducts electricity only when melted or dissolved (ions must be mobile), soluble in polar solvents. Covalent bonding (nonmetal + nonmetal): electron sharing. Molecular covalent: low melting point, nonconducting, variable solubility. Network covalent (diamond, SiO2): extremely high melting point, very hard, non-conducting. Metallic bonding (metal + metal): 'electron sea' — cations in mobile electron cloud. Properties: conducts electricity in solid state (mobile electrons), malleable (layers slide), lustrous (electrons reflect light), variable melting points.