A. Types of Chemical Bonds Ch12 Chemical Bonding A. Types of Chemical Bonds Bond – force that holds groups of atoms together and makes them function as a unit Bond energy – energy required to break a chemical bond
Ionic Bonding (b) (a) Ionic compound results when a metal reacts with a nonmetal
Covalent Bonding A covalent bond results when electrons are shared by nuclei
Covalent Bonding (continued) A polar covalent bond results when electrons are shared unequally by nuclei One atom attracts the electrons more than the other atom
B. Electronegativity Electronegativity – the relative ability of an atom in a molecule to attract shared electrons to itself Increases from left to right across a period Decreases down a group of representative elements
The polarity of a bond depends on the difference between the electronegativity values of the atoms forming the bond
C. Bond Polarity and Dipole Moments A dipole moment results when a polar molecule has a center for positive charge separate from a center for negative charge
Water molecule dipole moment
The polarity of water affects its properties Permits ionic compounds to dissolve in it Causes water to remain liquid at higher temperature
D. Stable Electron Configurations and Charges on Ions
Atoms in stable compounds usually have a noble gas electron configuration Metals lose electrons to reach noble gas configuration Nonmetals gain electrons to reach noble gas configuration
Predicting Formulas of Ionic compounds Chemical compounds are always electrically neutral
E. Ionic bonding and Structures of Ionic Compounds Ions are packed together to maximize the attractions between ions
Structures of Ionic Compounds Cations are always smaller than the parent atom Anions are always larger than the parent atom
Ionic Compounds Containing Polyatomic Ions Polyatomic ions work in the same way as simple ions The covalent bonds hold the polyatomic ion together so it behaves as a unit
F. Writing Lewis Structures In writing Lewis structures we include only the valence electrons Most important requirement Atoms achieve noble gas electron configuration (octet rule, duet rule)
Bonding pairs are shared between 2 atoms Unshared pairs (lone pairs) are not shared and not involved in bonding
Rules for Covalent Bonds 1. Determine the total number of valence electrons 2. Write the skeleton structure and join the atoms in this structure by single covalent bonds 3. For each single bond formed, subtract 2 from the total number of valence electrons 4. With the remaining valence electrons first complete the octet (or duet) of the outside atoms, then complete the octet of inner atoms 5. If the inner atom lacks an octet, form multiple bonds by sharing more electrons from outer atoms to inner atoms Double bond 2 pair e- Triple bond 3 pair e-
G. Lewis Structures of Molecules with Multiple Bonds Single bond – covalent bond in which 1 pair of electrons is shared by 2 atoms Double bond – covalent bond in which 2 pairs of electrons are shared by 2 atoms Triple bond – covalent bond in which 3 pairs of electrons are shared by 2 atoms
A molecule shows resonance when more than one Lewis structure can be drawn for the molecule
H. Molecular Structure Three dimensional arrangement of the atoms in a molecule Water - bent
Linear structure – atoms in a line Carbon dioxide
Trigonal planar – atoms in a triangle BF3
Tetrahedral structure methane
I. The VSEPR Model Valence shell electron pair repulsion (VSEPR) model Molecular structure is determined by minimizing repulsions between electron pairs
Two Pairs of Electrons BeCl2 180o - linear
Three Pairs of Electrons BF3 120o – trigonal planar
Four Pairs of Electrons CH4 120o – tetrahedral
J. Molecules with Double Bonds When using VSEPR model to predict molecular geometry of a molecule a double bond is counted the same as a single electron pair