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Bond Polarity and Electronegativity

Bond Polarity and Electronegativity. In a covalent bond, electrons are shared. Equal sharing of electrons to form a covalent bond forms a nonpolar molecule. There are some covalent bonds in which the electrons are located closer to one atom than the other.

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Bond Polarity and Electronegativity

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  1. Bond Polarity and Electronegativity • In a covalent bond, electrons are shared. • Equal sharing of electrons to form a covalent bond forms a nonpolar molecule. • There are some covalent bonds in which the electrons are located closer to one atom than the other. • Unequal sharing of electrons results in polar bonds.

  2. Bond Polarity and Electronegativity • Electronegativity • The ability of one atom in a chemical bond to attract electrons to itself is called electronegativity. • Electronegativity is a scale from 0.7 (Cs) to 4.0 (F). • Electronegativity increases • across a period and • down a group.

  3. Electronegativity

  4. Electronegativity and Bond Polarity • Difference in electronegativity is a gauge of bond polarity. If differences are: • around 0…then the covalent bond is non-polar • around 2…then the covalent bond is polar • around 3…then the bond is ionic There is no sharp distinction between bonding types. • The positive end (or pole) in a polar bond is represented + and the negative pole -.

  5. Polarity of Molecules Polar molecules interact with electric fields. If the centers of negative and positive charge do not coincide, then the molecule is polar.

  6. If two charges, equal in magnitude and opposite in sign, are separated by a distance r, then a dipole is established. The dipole moment, m, is given by m = Qr where Q is the magnitude of charge. Dipole Moments of Polyatomic Molecules In a polyatomic molecule, each bond can be a dipole. The orientation of these individual dipole moments determines whether the molecule has an overall dipole moment.

  7. Dipole Moments of Polyatomic Molecules Example: in CO2, each C-O dipole is canceled because the molecule is linear. In H2O, the H-O dipoles do not cancel because the molecule is bent.

  8. Dipole Moments of Polyatomic Molecules

  9. Dipole Moments of Polyatomic Molecules • It is possible for a molecule with polar bonds to be either polar or non-polar. • For diatomic molecules: • polar bonds always result in an overall dipole moment. • For triatomic molecules it depends on the geometry: • trigonal pyramidal, there is an overall dipole moment; • trigonal planar and all three bonds are identical, there is no overall dipole moment; • is trigonal planar and one or two bonds are different, there is an overall dipole moment.

  10. Dipole Moments of Polyatomic Molecules • For tetraatomic molecules with identical bonds: • tetrahedral or square planar, then the molecules are nonpolar; • see-saw, the molecule is polar. • For tetraatomic molecules in which one, two, or three bonds are different: • the molecule is polar.

  11. Acid-Base Behavior and Chemical Structure Factors That Affect Acid Strength Consider H-X. For this substance to be an acid we need: • H-X bond to be polar with H+ and X- (if X is a metal then the bond polarity is H-, X+ and the substance is a base), • the H-X bond must be weak enough to be broken, • the conjugate base, X-, must be stable.

  12. Binary Acids

  13. Binary Acids • Acid strength increases across a period and down a group. • Conversely, base strength decreases across a period and down a group. • HF is a weak acid because the bond energy is high. • The electronegativity difference between C and H is so small that the C-H bond is non-polar and CH4 is neither an acid nor a base.

  14. Oxyacids • Oxyacids contain O-H bonds. • All oxyacids have the general structure Y-O-H. • The strength of the acid depends on Y and the atoms attached to Y. • If Y is a metal (low electronegativity), then the substances are bases. • If Y has intermediate electronegativity (e.g. I, EN = 2.5), the electrons are between Y and O and the substance is a weak oxyacid.

  15. Oxyacids • If Y has a large electronegativity (e.g. Cl, EN = 3.0), the electrons are located closer to Y than O and the O-H bond is polarized to lose H+. • The number of O atoms attached to Y increase the O-H bond polarity and the strength of the acid increases (e.g. HOCl is a weaker acid than HClO2 which is weaker than HClO3 which is weaker than HClO4 which is a strong acid).

  16. Oxyacids

  17. Carboxylic Acids • These are organic acids which contain a COOH group (R is some carbon containing unit):

  18. Carboxylic Acids • When the proton is removed, the negative charge is delocalized over the carboxylate anion: • The acid strength increases as the number of electronegative groups on R increases.

  19. Lewis Acids and Bases • Brønsted-Lowry acid is a proton donor. • Focusing on electrons: a Brønsted-Lowry acid can be considered as an electron pair acceptor. • Lewis acid: electron pair acceptor. • Lewis base: electron pair donor. • Note: Lewis acids and bases do not need to contain protons. • Therefore, the Lewis definition is the most general definition of acids and bases.

  20. Lewis acids generally have an incomplete octet (e.g. BF3). • Transition metal ions are generally Lewis acids. • Lewis acids must have a vacant orbital (into which the electron pairs can be donated). • Compounds with p-bonds can act as Lewis acids: H2O(l) + CO2(g)  H2CO3(aq)

  21. Hydrolysis of Metal Ions • Metal ions are positively charged and attract water molecules (via the lone pairs on O). • The higher the charge, the smaller the metal ion and the stronger the M-OH2 interaction. • Hydrated metal ions act as acids: • The pH increases as the size of the ion increases (e.g. Ca2+ vs. Zn2+) and as the charge increases (Na+ vs. Ca2+ and Zn2+ vs. Al3+).

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