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Additional Aspects of Molecular Bonding & Structure. Chapters 8 and 9 BLB 12 th. 8.2 Ionic Bonding. Energetics of Ionic Bond Formation Na(s) + ½ Cl 2 (g) → NaCl (s) Δ H f ° = −410.9 kJ Δ H = 147 kJ/ mol
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Additional Aspects of Molecular Bonding & Structure Chapters 8 and 9 BLB 12th
8.2 Ionic Bonding Energetics of Ionic Bond Formation Na(s) + ½ Cl2(g) → NaCl(s) ΔHf° = −410.9 kJ ΔH = 147 kJ/mol • Lattice energy – energy required to completely separate the ions in one mole of an ionic compound Na+(g) + Cl‾(g) → NaCl(s) ΔHlattice = −788 kJ • Lattice energy ↑ as ion charges ↑ and size ↓`
8.2 Ionic Bonding • Electron Configurations of Ions (also 7.4) • Atoms will gain or lose electrons to achieve a noble gas configuration. • Transition metal ions: selectron(s) are lost first.
8.3 Covalent Bonding • Atoms share electrons.
8.4 Bond Polarity • Unequal sharing of electrons in a covalent bond • Electronegativity – the ability of an atom in a molecule (bonded) to attract electrons to itself
8.4 Bond Polarity • Nonpolar covalent bond – electrons shared equally • Polar covalent bond – electrons shared unequally due to different electronegativity values • Greater electronegativity difference, more polar the bond (higher dipole moment) • Dipole moment – measured magnitude of a dipole. • Predict direction • No calculations
The greater the difference in electronegativity, the more polar the bond.
Electronegativity difference < 0.5 nonpolar 0.5-2.0 polar > 2.0 ionic Rough guidelines only. See p. 304. Examples: C–H N–O Na–Cl Cl–Cl Electronegativity
9.3 Molecular Polarity • Depends upon the polarities of the bonds and the molecular geometry of the molecule • Bond dipole moments are vector quantities. • A molecular dipole moment is the vector sum of its bond dipoles. • A molecule can be nonpolar, that is, have a net dipole moment of zero, even if bond dipole(s) exist.
CO2 a nonpolar molecule H2O a polar molecule
9.3 Molecular Polarity • Examples KrF2 SO2 ICl3 XeO4
8.5 Drawing Lewis Structures • Formal Charges (p. 307) • There may be more than one valid Lewis Structure for a given molecule. • Formal charges are used to determine the most reasonable structure. • Calculate a formal charge (FC) for each atom: • FC = (# valence e¯) − (# e¯ belonging to atom)
8.5 Drawing Lewis Structures • Formal Charges • Best structure? The one with the formal charges closest to zero and where the most negative charges reside on the most electronegative atoms. • For H, Be, and B, formal charges indicate that the Lewis structure with an incomplete octet is more important than the ones with double bonds.
8.6 Resonance Structures • Lewis structures and the VSEPR theory are means by which we try to mimic or predict the experimentally determined properties of molecules. • When a combination of single and multiple bonds are used, it implies that the bond lengths are unequal. • They’re not!
Resonance Structures • The measured bond lengths are an average of the representative structures; somewhere between a single and double bond length.
Resonance • The organic compound benzene, C6H6, has two resonance structures. • It is commonly depicted as a hexagon with a circle inside to signify the delocalized electrons in the ring.
8.8 Strengths of Covalent Bonds • Bond enthalpy – energy required to break a bond • Enthalpy of reaction – estimate from difference of the bonds broken minus the bonds formed
413 kJ + 242 kJ 328 kJ + 431 kJ −104 kJ
9.4 Orbital Overlap & 9.5 Hybrid Orbitals • Electrons exist in orbitals. • Valence Bond Theory – bonding model where orbitals overlap to form bonds • Hybridization combines orbitals into hybrid orbital sets that match experimentally determined geometried. • σ bond – one area of overlap • π bond – two areas of overlap
Orbital Overlap σ bonds – single area of overlap