Module 4 Part B: Dot Structures of Molecules Study Notes:

In Section 9.4 of the 6^th edition of Kotz (CHM 2045C) there is an excellent explanation of covalent bonds and drawing dot structures of molecules. We will focus in Part B only on those molecules which can be explained by the octet rule for the nonmetals (and duet rule for hydrogen). Page 384-5 lists five steps where you do a little math in step 2 to calculate all the valence electrons and the number of bonds and lone pairs. Examples 9.2 and 9.3 show simple binary molecular compounds. Please note the Problem-Solving tip on page 388.  Tables 9.4 and 9.5 show the comparison of molecules and polyatomic ions.

Kotz’s five steps (#2 was expanded to Steps 2 and 3 below):

1.      Decide on the central atom (usually not oxygen or hydrogen). The central atom is usually the one with the lowest electron affinity. In formaldehyde, CH₂O, the central atom is carbon.

2.      Determine the total number of valence electrons in the molecules or the ion. I a neutral molecule this number will be the sum of the valence electrons of each atom. For a negative ion add the charge to this total number. For a positive ion subtract the positive charge from this total number. For CH₂O:  C=4, H=1(x2) , O=6 this would be 4+2+6 = 12 total valence electrons.

3.      Take this total number of electrons and divide by two to determine the number of electron pairs. For CH₂O:  12/2 = 6 electron pairs

4.      Place one pair of electrons between each pair of bonded atoms to form a single bond. You can either show a pair of dots, or draw a single stick between the two atoms to represent the single covalent bond.

5.      Use any remaining pairs as lone pairs around each atom (except hydrogen) so that each atom is surrounded by eight electrons. (There is never a lone pair on a carbon except in Carbon moxide)

6.      If the central atom has fewer than eight electrons at this point, move one or more of the lone pairs on the terminal atoms in a position intermediate between the center and the terminal atom to form  multiple bonds. (As a general rule double or triple bonds are formed when both atoms are from the following nonmetals: C, N, O, S. That is, bonds such as C=C, C=n, C=O, S=O will be incountered frequently.

In the Kotz 7^th edition Chapter 9 has become Chapter 8 as the two atomic theory chapters 7& 8 have been combined into one chapter 7. The five steps are on pages 353-4 and example 8.1 should be studies on pages 354-355.

McMurray’s Text (CHM 2045C) has Covalent Bonds and Molecular structure in Chapter 7. In section 7.5 McMurray summaries the dot structures of compounds of the nonmetals in the second row of the periodic table pages 229-232. The mathematical process similar to Kotz’s six steps above is found on pages 235-236.

Brady’s text (CHM 2045C) covers covalent bonding in Chapter 9: Chemical Bonding-General Concepts. Brady covers drawing dot/stick structures of molecules in section 9.7 On page 377, the six step similar to the above are listed.

In the CHM 1020 text, Hill, (Chemistry for Changing Times-11^th edition) Chapter 5 discusses chemical bonds.  Covalent bonds are introduced in section 5.7. However, section 5.11(Rules for Writing Lewis Formulas) on pages 132 and 133 list the five general rules for drawing Lewis Dot Structures. Table 5.5 on page 135 is a good summary:

 If you still have your Corwin CHM 1025C text, (Introductory Chemistry-Concepts & Connections – 5^th Edition) sections 12.4 and 12.5 beginning on page 330 has a simpler discussion. On the bootm of page 334 Corwin has the four rules similar to above

John Taylor’s Method for Drawing Dot Structures

On my web site I have a length study guide for Polyatomic ions:
http://www.hccfl.edu/faculty/john_taylor/chm1025/polyions/polyionstudyguide.html

From that study guide I have the following seven steps which I reviewed the first day of class:

Using your envelope of paper atoms, assemble a reasonable dot structure of each polyatomic ion of molecular acids (not in water) using the following criteria (You may print out the following pages and cut out the atoms: O, H, S and C, Cl, P, N ):

1. Place the nonmetal which is not oxygen or hydrogen in the middle of your desk.
2. First using all single bonds, hook all oxygens in the formula to the central nonmetal (Simple covalent or coordinate covalent bonds). Never hook oxygen to oxygen except in peroxides.
3. If oxygen is present, hook the hydrogen written first in the chemical formula to an oxygen. Hydrogen requires only two electrons to fill it's orbital. Notice the change in the polyion's charge when a hydrogen is placed on the oxygen. If hydrogen is written second in the formula after another nonmetal, then hook that hydrogen to that nonmetal, not to oxygen such as (CH₃-COOH written organically) acetic acid HC₂H₃O₂ or oxalic acid H₂C₂O₄ both hydrogens are attached to the oxygens.
4. If using all single bonds connecting the oxygen to the central nonmetal, the count of electrons around each element should total eight electrons (octet rule). This includes the element's original outer surface (valence) electrons plus the electrons being shared from the bonded element.
   
   Try the following:
   1. phosphate (no Plug in needed)    ToolBook Demo of Phosphorus ions and molecules (Neuron plug in needed)
   2. sulfate(no plug in needed)    Demo of sulfur ions and molecules (Neuron plug in Needed)
   3. chlorate, chlorite, hypochlorite, and perchlorate
5. If the count is 7-7, then add a second bond, a double covalent bond (four electrons being shared between two atoms.
6. If the count is 6-6, then make a triple covalent bond between the two elements (six electrons shared between the two atoms).
   
   
   

 

 

7. Try the following:
   1. carbonate(no Plug in)    
       ToolBook Demo carbonate and molecules (Neuron Plug in Needed).
   2. Nitrate
   3. cyanide CN^1-
   4. carbon dioxide CO₂
   5. Nitrogen gas N₂
   6. oxygen gas O₂ and ozone O₃
   7. ethylene C₂H₄
   8. acetylene C₂H₂
   
   
8. If the count is 8-6, then make a coordinate covalent bond. Hook the six (vacant) orbital onto an unshared pair of the eight. A coordinate covalent bond is still a single bond. In making double, triple bonds you may also use one or two coordinate covalent bonds to predict a structure using the octet rule, if necessary as in carbon monoxide.
   

Table 9.4 from Kotz displays Common Hydrogen containing Compounds and Ions:

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Table 9.5 from Kotz displays common oxoacids and their anions: