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Chapter 8 Covalent Bonding Guided Reading Answer Key

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Covalent Bonds

Learning Objectives
  • Define covalent bond.
  • Illustrate covalent bond formation with Lewis electron dot diagrams.

Ionic bonding typically occurs when it is easy for one atom to lose one or more electrons and another atom to gain one or more electrons. However, some atoms won't give up or gain electrons easily. Yet they still participate in compound formation. How?

There is another mechanism for obtaining a complete valence shell: sharing electrons. When electrons are shared between two atoms, they make a bond called a covalent bond.

Let us illustrate a covalent bond by using H atoms, with the understanding that H atoms need only two electrons to fill the 1s subshell. Each H atom starts with a single electron in its valence shell:

- A Lewis structure of Hydrogen atoms showing one valence electron.

The two H atoms can share their electrons:

- A Hydrogen molecule shows one pair of shared electrons by both atoms (covalent bond).

We can use circles to show that each H atom has two electrons around the nucleus, completely filling each atom's valence shell:

- The Hydrogen molecule (H2) has one single covalent bond formed by two valence electrons, one from each Hydrogen atom.

Because each H atom has a filled valence shell, this bond is stable, and we have made a diatomic hydrogen molecule. (This explains why hydrogen is one of the diatomic elements.) For simplicity's sake, it is not unusual to represent the covalent bond with a dash, instead of with two dots:

H–H

Because two atoms are sharing one pair of electrons, this covalent bond is called a single bond.

As another example, consider fluorine. F atoms have seven electrons in their valence shell:

- A Lewis structure of Fluorine atom showing seven valence electrons.

These two atoms can do the same thing that the H atoms did; they share their unpaired electrons to make a covalent bond.

- A Flourine molecule shows one pair of shared electrons by both atoms (covalent bond). The Fluorine molecule (F2) has one single covalent bond (short line) formed by two valence electrons, one from each Fluorine atom.

Note that each F atom has a complete octet around it now:

- Each Fluorine atom has 8 electrons in the outermost energy level once they are part of the covalent Fluorine molecule.

We can also write this using a dash to represent the shared electron pair:

- Covalent bond in the Fluorine molecule represented with a line.

There are two different types of electrons in the fluorine diatomic molecule. The bonding electron pair makes the covalent bond. Each F atom has three other pairs of electrons that do not participate in the bonding; they are called lone electron pairs. Each F atom has one bonding pair and three lone pairs of electrons.

Covalent bonds can be made between different elements as well. One example is HF. Each atom starts out with an odd number of electrons in its valence shell:

- Hydrogen atom (one valence electron) and Fluorine atom (seven valence electrons)

The two atoms can share their unpaired electrons to make a covalent bond:

- The covalent molecule Hydrogen fluoride has one single covalent bond (short line) formed by two valence electrons, one from each atom. The lone pairs of electrons on Fluorine atom that are not part of the covalent bond are also shown.

We note that the H atom has a full valence shell with two electrons, while the F atom has a complete octet of electrons.

Example 4

Use Lewis electron dot diagrams to illustrate the covalent bond formation in HBr.

Solution

HBr is very similar to HF, except that it has Br instead of F. The atoms are as follows:

- A Lewis structure of Hydrogen and Bromine atoms showing valence electrons

The two atoms can share their unpaired electron:

- A Hydrogen Bromide molecule shows one pair of shared electrons by both atoms (covalent bond). The Hydrogen bromide molecule (HBr) has one single covalent bond formed by two valence electrons, one from each Hydrogen atom. The lone pairs of electrons on Bromine atom that are not part of the covalent bond are also shown.

Test Yourself

Use Lewis electron dot diagrams to illustrate the covalent bond formation in Cl2.

Answer

- A Chlorine molecule shows one pair of shared electrons by both atoms (covalent bond/short line). The molecule has one single covalent bond formed by two valence electrons, one from each Chlorine atom.The lone pairs of electrons on both Chlorine atoms that are not part of the covalent bond are also shown.

More than two atoms can participate in covalent bonding, although any given covalent bond will be between two atoms only. Consider H and O atoms:

- A Lewis structure of Hydrogen and Oxygen atoms showing valence electrons

The H and O atoms can share an electron to form a covalent bond:

- This diagram shows an incomplet octet surrounding Oxygen atom.

The H atom has a complete valence shell. However, the O atom has only seven electrons around it, which is not a complete octet. We fix this by including a second H atom, whose single electron will make a second covalent bond with the O atom:

- A water molecule shows two pairs of shared electrons between Oxygen atom and each Hydrogen atom. The water molecule has two single covalent bonds formed by two valence electrons, one from Oxygen and the other one from each Hydrogen atom. The lone pairs of electrons on Oxygen atom that are not part of the covalent bond are also shown.

(It does not matter on what side the second H atom is positioned.) Now the O atom has a complete octet around it, and each H atom has two electrons, filling its valence shell. This is how a water molecule, H2O, is made.

Example 5

Use a Lewis electron dot diagram to show the covalent bonding in NH3.

Solution

The N atom has the following Lewis electron dot diagram:

- A Lewis structure of Nitrogen atom showing five valence electrons

It has three unpaired electrons, each of which can make a covalent bond by sharing electrons with an H atom. The electron dot diagram of NH3 is as follows:

- A Nitrogen trihydride (Ammonia) molecule shows three pairs of shared electrons between Nitrogen and each of the three Hydrogen atoms in the molecule. Each covalent bond is formed by two valence electrons, one from each Hydrogen atom and one from Nitrogen. The lone pairs of electrons on Nitrogen atom that are not part of the covalent bond are also shown.

Test Yourself

Use a Lewis electron dot diagram to show the covalent bonding in PCl3.

Answer

- A Phosphorus trichloride molecule shows three pairs of shared electrons between Phosphorus and each of the three Chlorine atoms in the molecule. Each covalent bond is formed by two valence electrons, one from each Chlorine atom and one from Phosphorus. The lone pairs of electrons on Phosphorus and Chlorine atoms that are not part of the covalent bonds are also shown.

There is a simple set of steps for determining the Lewis electron dot diagram of a simple molecule. First, you must identify the central atom and the surrounding atoms. The central atom is the atom in the center of the molecule, while the surrounding atoms are the atoms making bonds to the central atom. The central atom is usually written first in the formula of the compound (H2O is the notable exception). After the central and surrounding atoms have been identified, follow these steps:

  1. Count the total number of valence electrons. Add extra if the species has negative charges and remove some for every positive charge on the species.
  2. Write the central atom and surround it with the surrounding atoms.
  3. Put a pair of electrons between the central atom and each surrounding atom.
  4. Complete the octets around the surrounding atoms (except for H).
  5. Put remaining electrons, if any, around the central atom.
  6. Check that every atom has a full valence shell.

Let us try these steps to determine the electron dot diagram for BF4 . The B atom is the central atom, and the F atoms are the surrounding atoms. There is a negative sign on the species, so we have an extra electron to consider.

1. Count the total number of electrons. B has 3, each F has 7, and there is one extra electron: 3 + 7 + 7 + 7 + 7 + 1 = 32.

2. Write the central atom surrounded by surrounding atoms.

- A Bromine tetrafluoride molecule formed by four atoms of Fluorine and one atom of Bromine. The valence electrons involved in the covalent bonds are not shown.

3. Put a pair of electrons between the central atom and each surrounding atom. This uses up eight electrons, so we have 32 − 8 = 24 electrons left.

- A Bromine tetrafluoride molecule shows four pairs of shared electrons between Bromine and each of the four Fluorine atoms in the molecule. Each covalent bond is formed by two valence electrons, one from each Fluorine atom and one from Bromine. The lone pairs of electrons on Bromine and Fluorine atoms that are not part of the covalent bonds are not shown.

4. Complete the octets around the surrounding atoms (except for H). This uses up 24 more electrons, leaving 24 − 24 = 0 electrons left.

- A Bromine tetrafluoride molecule shows four pairs of shared electrons between Bromine and each of the four Fluorine atoms in the molecule. Each covalent bond is formed by two valence electrons, one from each Fluorine atom and one from Bromine. The lone pairs of electrons on Bromine and Fluorine atoms that are not part of the covalent bonds are also shown.

5. Put remaining electrons, if any, around the central atom. There are no additional electrons to add to the central atom.

6. Check. The B atom has eight electrons around it, as does each F atom. Each atom has a complete octet. This is a good Lewis electron dot diagram for BF4 .

Sometimes, however, these steps don't work. If we were to follow these steps for the compound formaldehyde (CH2O), we would get the following:

- This electron configuration is not correct as the C only has six electrons around it.

The H and O atoms have the proper number of electrons, but the C atom has only six electrons around it, not the eight electrons for an octet. How do we fix this?

We fix this by recognizing that two atoms can share more than one pair of electrons. In the case of CH2O, the O and C atoms share two pairs of electrons, with the following Lewis electron dot diagram as a result:

- These two electron configurations are correct. C and O have 8 electrons around it.

By circling the electrons around each atom, we can now see that the O and C atoms have octets, while each H atom has two electrons:

- These two electron configurations are correct. C and O have 8 electrons around it.

Each valence shell is full, so this is an acceptable Lewis electron dot diagram. If we were to use lines to represent the bonds, we would use two lines between the C and O atoms:

- This formula representation shows the double bond between C and O. This represents two bonding pairs of electrons

The bond between the C and O atoms is a double bond and represents two bonding pairs of electrons between the atoms. If using the rules for drawing Lewis electron dot diagrams don't work as written, a double bond may be required.

Example 6

What is the proper Lewis electron dot diagram for CO2?

Solution

The central atom is a C atom, with O atoms as surrounding atoms. We have a total of 4 + 6 + 6 = 16 valence electrons. Following the rules for Lewis electron dot diagrams for compounds gives us

Two double bonds between Carbon, one with each Oxygen atom (second example) is the correct way to represent this molecule. The three atoms have a complete octet.

The O atoms have complete octets around them, but the C atom has only four electrons around it. The way to solve this dilemma is to make a double bond between carbon and each O atom:

(second example) is the correct way to represent this molecule. The three atoms have a complete octet.

Each O atom still has eight electrons around it, but now the C atom also has a complete octet. This is an acceptable Lewis electron dot diagram for CO2.

Test Yourself

What is the proper Lewis electron dot diagram for carbonyl sulfide (COS)?

Answer

Two double bonds between Carbon and Sulfur and, two double bonds between Carbon and Oxygen is the correct way to represent this molecule. The three atoms have a complete octet.

It is also possible to have a triple bond, in which there are three pairs of electrons between two atoms. Good examples of this are elemental nitrogen (N2) and acetylene (C2H2):

Three pairs of electrons (triple covalent bonds) between atoms in Nitrogen and Ethyne (acetylene molecules. The lone pair of electrons are also represented in Nitrogne.

Acetylene is an interesting example of a molecule with two central atoms, which are both C atoms.

Polyatomic ions are bonded together with covalent bonds. Because they are ions, however, they participate in ionic bonding with other ions. So both major types of bonding can occur at the same time.

Food and Drink App: Vitamins and Minerals

Vitamins are nutrients that our bodies need in small amounts but cannot synthesize; therefore, they must be obtained from the diet. The word vitamin comes from "vital amine" because it was once thought that all these compounds had an amine group (NH2) in it. This is not actually true, but the name stuck anyway.

All vitamins are covalently bonded molecules. Most of them are commonly named with a letter, although all of them also have formal chemical names. Thus vitamin A is also called retinol, vitamin C is called ascorbic acid, and vitamin E is called tocopherol. There is no single vitamin B; there is a group of substances called the B complex vitamins that are all water soluble and participate in cell metabolism. If a diet is lacking in a vitamin, diseases such as scurvy or rickets develop. Luckily, all vitamins are available as supplements, so any dietary deficiency in a vitamin can be easily corrected.

A mineral is any chemical element other than carbon, hydrogen, oxygen, or nitrogen that is needed by the body. Minerals that the body needs in quantity include sodium, potassium, magnesium, calcium, phosphorus, sulfur, and chlorine. Essential minerals that the body needs in tiny quantities (so-called trace elements) include manganese, iron, cobalt, nickel, copper, zinc, molybdenum, selenium, and iodine. Minerals are also obtained from the diet. Interestingly, most minerals are consumed in ionic form, rather than as elements or from covalent molecules. Like vitamins, most minerals are available in pill form, so any deficiency can be compensated for by taking supplements.

Supplement facts label.

Every entry down through pantothenic acid is a vitamin, and everything from calcium and below is a mineral.

Key Takeaways
  • Covalent bonds are formed when atoms share electrons.
  • Lewis electron dot diagrams can be drawn to illustrate covalent bond formation.
  • Double bonds or triple bonds between atoms may be necessary to properly illustrate the bonding in some molecules.

Exercises

  1. How many electrons will be in the valence shell of H atoms when it makes a covalent bond?

  2. How many electrons will be in the valence shell of non-H atoms when they make covalent bonds?

  3. What is the Lewis electron dot diagram of I2? Circle the electrons around each atom to verify that each valence shell is filled.

  4. What is the Lewis electron dot diagram of H2S? Circle the electrons around each atom to verify that each valence shell is filled.

  5. What is the Lewis electron dot diagram of NCl3? Circle the electrons around each atom to verify that each valence shell is filled.

  6. What is the Lewis electron dot diagram of SiF4? Circle the electrons around each atom to verify that each valence shell is filled.

  7. Draw the Lewis electron dot diagram for each substance.

    1. SF2
    2. BH4

  8. Draw the Lewis electron dot diagram for each substance.

    1. PI3
    2. OH

  9. Draw the Lewis electron dot diagram for each substance.

    1. GeH4
    2. ClF

  10. Draw the Lewis electron dot diagram for each substance.

    1. AsF3
    2. NH4 +

  11. Draw the Lewis electron dot diagram for each substance. Double or triple bonds may be needed.

    1. SiO2
    2. C2H4 (assume two central atoms)

  12. Draw the Lewis electron dot diagram for each substance. Double or triple bonds may be needed.

    1. CN
    2. C2Cl2 (assume two central atoms)

  13. Draw the Lewis electron dot diagram for each substance. Double or triple bonds may be needed.

    1. CS2
    2. NH2CONH2 (assume that the N and C atoms are the central atoms)

  14. Draw the Lewis electron dot diagram for each substance. Double or triple bonds may be needed.

    1. POCl
    2. HCOOH (assume that the C atom and one O atom are the central atoms)

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Chapter 8 Covalent Bonding Guided Reading Answer Key

Source: https://guides.hostos.cuny.edu/che105/chapter8

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