Chapter 7

Predicting Whether a Reaction Will Occur

Why does a reaction occur? What causes a reaction to “want” to form products?

Scientists have recognized several tendencies in reactants the DRIVE them to form products. There are several driving forces:

Formation of a solid

Formation of water

Formation of a gas

Transfer of electrons

When two or more chemicals are brought together, if any of these things can occur, a chemical change is likely to take place.

*IF NONE OF THESE FACTORS TAKE PLACE NO REACTION WILL TAKE PLACE

Our goal is to determine whether a reaction will occur and what products might form.

All chemical reactions can be placed into one of six categories:

1) Combustion: A combustion reaction is when oxygen combines with a hydrocarbon (a combination of C and H) to form water and carbon dioxide. These reactions are exothermic, meaning they produce heat. An example of this kind of reaction is the burning of napthalene:

C10H8 + 12 O2 ---> 10 CO2 + 4 H2O

2) Synthesis: A synthesis reaction is when two or more simple compounds combine to form a more complicated one. These reactions come in the general form of:

A + B ---> AB

One example of a synthesis reaction is the combination of iron and sulfur to form iron (II) sulfide:

8 Fe + S8 ---> 8 FeS

3) Decomposition: A decomposition reaction is the opposite of a synthesis reaction - a complex molecule breaks down to make simpler ones. These reactions come in the general form:

AB ---> A + B

One example of a decomposition reaction is the electrolysis of water to make oxygen and hydrogen gas:

2 H2O ---> 2 H2 + O2

4) Single displacement: This is when one element trades places with another element in a compound. These reactions come in the general form of:

A + BC ---> AC + B

One example of a single displacement reaction is when magnesium replaces hydrogen in water to make magnesium hydroxide and hydrogen gas:

Mg + 2 H2O ---> Mg(OH)2 + H2

5) Double displacement: This is when the anions and cations of two different molecules switch places, forming two entirely different compounds. These reactions are in the general form:

AB + CD ---> AD + CB

One example of a double displacement reaction is the reaction of lead (II) nitrate with potassium iodide to form lead (II) iodide and potassium nitrate:

Pb(NO3)2 + 2 KI ---> PbI2 + 2 KNO3

6) Acid-base: This is a special kind of double displacement reaction that takes place when an acid and base react with each other. The H+ ion in the acid reacts with the OH- ion in the base, causing the formation of water. Generally, the product of this reaction is some ionic salt and water: Term “salt” is used to mean ionic compound

HA + BOH ---> H2O + BA

One example of an acid-base reaction is the reaction of hydrobromic acid (HBr) with sodium hydroxide:

HBr + NaOH ---> NaBr + H2O

7*) Special Reaction Type: Redox: or oxidation-reduction reactions, primarily involve the transfer of electrons between two chemical species. The compound that loses an electron is said to be oxidized (OIL = oxidization is loss), the one that gains an electron is said to be reduced (RIG = reduced is gained).

*If the element stands alone its net charge is ZERO.

*If the element is contained in a compound then you must look at their individual oxidation numbers (periodic table)

*If it is a transition metal you must split the compound apart and figure out the charge on the transition metal based off of its partner (like you did in chapter 5 when naming)

H2 + F2 = 2HF

H2 +0 + F2 +0 = H +1 F -1

hydrogen lost an electron to become positively charged ………..OIL

Fluorine gained an electron to become negatively charged……RIG

Substance oxidized: Hydrogen Oxidation Reaction: H2 → 2H+ + 2e-
Substance reduced: FluorineReduction Reaction: F2 + 2e- → 2F-

****A lot of reactions are redox and another type of reaction from the above list.

***YOU MUST FIRST FIGURE OUT THE REACTION TYPE 1-6 AND THEN DECIDE IF IT IS ALSO A REDOX REACTION

Questions to ask yourself if you cannot figure out the type of reaction:

Follow this series of questions. When you can answer "yes" to a question, then stop!

1) Does your reaction have oxygen as one of it's reactants and carbon dioxide and water as products? If yes, then it's a combustion reaction

2) Does your reaction have two (or more) chemicals combining to form one chemical? If yes, then it's a synthesis reaction

3) Does your reaction have one large molecule falling apart to make several small ones? If yes, then it's a decomposition reaction

4) Does your reaction have any molecules that contain only one element? If yes, then it's a single displacement reaction

5) Does your reaction have water as one of the products? If yes, then it's an acid-base reaction

6) If you haven't answered "yes" to any of the questions above, then you've got a double displacement reaction

Examples to figure out:

1) NaOH + KNO3 --> NaNO3 + KOH

2) CH4 + 2 O2 --> CO2 + 2 H2O

3) 2 Fe + 6 NaBr --> 2 FeBr3 + 6 Na

4) CaSO4 + Mg(OH)2 --> Ca(OH)2 + MgSO4

5) NH4OH + HBr --> H2O + NH4Br

6) Pb + O2 --> PbO2

7) Na2CO3 --> Na2O + CO2

Solubility Tables

A Solubility Table summarizes the solubility behavior of a large group of ionic substances. How to interpret a Solubility Table?

Example 1:

Example 2:

We can use the Solubility Table to determine whether an ionic compound exist as ions in aqueous solution (soluble) or as a solid (insoluble). Once we know the compound we use the Solubility Table to determine its solubility.

For example, consider the following compounds; NaCl, BaSO4, NaC2H3O2, and CaS. Determine the solubility in water for these ionic substances.

NaCl (all chlorides are soluble except...) SOLUBLE = aqueous

BaSO4 (all sulfates are soluble except...) INSOLUBLE = solid

NaC2H3O2 (all sodium compounds are soluble) SOLUBLE = aqueous

CaS (all sulfides are insoluble...) INSOLUBLE = solid

We'll also use the information in a Solubility Table to help identify the phase of ionic substance in a chemical equation. The chemical reaction types where the Solubility Table is important are;

  • Double Replacement reactions
  • Neutralization reactions
  • Single Replacement reactions

Example 1: double displacement reaction problem;

Write the formula and identify the phase for the product(s) and balance the following reaction.

Na2SO4(aq) + CaCl2(aq) --->

Since this is a double replacement reaction we can write the formulas of the products by exchanging the cations and anions.

Na2SO4(aq) + CaCl2(aq) ---> CaSO4(?) + 2NaCl(?)

Now we'll use the Solubility Table to predict the phases of the products. According to the table CaSO4 is INSOLUBLE and NaCl is SOLUBLE.

Na2SO4(aq) + CaCl2(aq) ---> CaSO4(s) + 2NaCl(aq)

Example.2: double displacement reaction problem

Write the formula and identify the phase for the product(s) and balance the following reaction.

AgNO3(aq) + Na2CO3(aq) --->

Since this is a double replacement reaction we can write the formulas of the products by exchanging the cations and anions.

2AgNO3(aq) + Na2CO3(aq) --->Ag2CO3(?) + 2NaNO3(?)

Now we'll use the Solubility Table to predict the phases of the products. According to the table Ag2CO3 is INSOLUBLE and NaNO3 is SOLUBLE.

2AgNO3(aq) + Na2CO3(aq) ---> Ag2CO3(s) + 2NaNO3(aq)

Example 3:

KNO3(aq) + BaCl2 (aq) ) --->

Example 4:

Na2SO 4(aq) + Pb(NO3)2(aq) ) --->

Example 5:

KOH (aq) + Fe(NO3) 3(aq) ) --->