Presentation is loading. Please wait.

Presentation is loading. Please wait.

Stoichiometry of Excess-Limiting Reactions. Excess-Limiting Concept Consider the simple reaction: A + B  C It means that 1 mole of “A” reacts with 1.

Published byPrudence Osborne Modified over 8 years ago

Similar presentations

Presentation on theme: "Stoichiometry of Excess-Limiting Reactions. Excess-Limiting Concept Consider the simple reaction: A + B  C It means that 1 mole of “A” reacts with 1."— Presentation transcript:

1 Stoichiometry of Excess-Limiting Reactions

2 Excess-Limiting Concept Consider the simple reaction: A + B  C It means that 1 mole of “A” reacts with 1 mole of “B” and produces 1 mole of “C”. + A = B = C = ? ? + But, what if we actually put 2 moles of “A” into a container with only 1 mole of “B” ? There is one excess “A” left over when the reaction is finished. Why does this happen ? EXCESS

3 Excess-Limiting Concept A + B  C According to the equation, they MUST combine in a 1:1 ratio. After the 1 mole of B is all used up, we will have only used 1 mole of A and there will still be 1 mole of A left over. ? ? + EXCESS A = B = C = Because there is more than enough A for the reaction, A is called the excess reactant. When B is used up, the reaction stops. B is called the limiting reactant because it limits how much C the reaction can make.

4 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 Suppose we have 10. grams of Mg and 5.0 g of N 2 for this reaction. How much product will we be able to make? 10. g 5.0 g ? We can quickly see that this reaction requires 3 moles of Mg to every 1 mole of N 2. In other words, it takes 3 times as many Mg atoms as it does N 2 molecules.

5 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? The other issue is molar mass. Mg has a molar mass of 24.3 g/mol and the N 2 has a molar mass of 28.0 g/mol. How does this relate? It’s important because if we have equal masses of these two, we will actually have more Mg atoms than N 2 molecules since each Mg is lighter in mass.

6 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We need to identify the limiting reactant… the one that will be used up first, before we can determine the amount of product that can be made in this situation. This is done by using the usual stoichiometric process of: grams A  moles A; moles A  moles B; moles B  grams B

7 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We begin by using what we “have” of each reactant and calculate the amount of each that we would “need”. We “have” this much We “need” this much

8 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We “have” this much We “need” this much To react all of the 10.g of Mg that we “have”, we “need” 3.84g of N 2. 5.0g of N 2 – 3.84g N 2 needed leaves 1.16 g excess N 2. We already “have” 5.0 g of N 2 so since we only “need” 3.84g of N 2, we have more than we need.

9 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We “have” this much We “need” this much 5.0g of N 2 – 3.84g N 2 needed leaves 1.16 g excess N 2. The 1.16 g of excess N 2 will not react because there is not enough Mg to react with it. Since there will be left over N 2 that is un-reacted, we call the N 2 the excess reactant. Excess

10 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We “have” this much We “need” this much Comparing the 10. g of Mg that we “have” to the 13 g of Mg that we “need”, we see that we don’t “have” enough Mg to react with all of the N 2. When the 10. g of Mg is used up, the reaction will stop. Excess

11 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We “have” this much We “need” this much With all of the Mg gone, no more N 2 can be used and no more product can be made. Mg is called the limiting reactant because when it is gone, the reaction stops. It therefore “limits” the amount of product that can be made. Excess Limiting

12 Excess-Limiting Let’s see how this works with an actual reaction. Consider the reaction: 3 Mg + N 2  Mg 3 N 2 10. g 5.0 g ? We “have” this much We “need” this much Now we can answer the original question which was how much product will we make? Excess Limiting Using the Limiting

13 Have we learned it yet? Try this one on your own: Al 2 O 3 + 6 HF  2 AlF 3 + 3 H 2 O How many grams of H 2 O can be made with 150g of aluminum oxide and 150g of hydrofluoric acid? Follow these steps: Use the 150g of Al 2 O 3 to find the mass of HF needed. Use the 150 g of HF to find the mass of Al 2 O 3 needed. Compare the amounts you “have” to the amounts you “need” and determine the limiting reactant (have<need). Use the limiting reactant amount to calculate the mass of H 2 O that will be produced.

14 Al 2 O 3 + 6 HF  2 AlF 3 + 3 H 2 O Answer HAVE NEED Excess Limiting

Download ppt "Stoichiometry of Excess-Limiting Reactions. Excess-Limiting Concept Consider the simple reaction: A + B  C It means that 1 mole of “A” reacts with 1."

Similar presentations

Copyright Sautter 2003 STIOCHIOMETRY “Measuring elements” Determing the Results of A Chemical Reaction.

Copyright Sautter 2003 STIOCHIOMETRY “Measuring elements” Determing the Results of A Chemical Reaction.
Chapter 12 “Stoichiometry”

Chapter 12 “Stoichiometry”
Limiting Reactants & Percent Yield

Limiting Reactants & Percent Yield
Chapter 11: Stoichiometry

Chapter 11: Stoichiometry
Equation Stoichiometry Chemical Equation – indicates the reactants and products in a rxn; it also tells you the relative amounts of reactants and products.

Equation Stoichiometry Chemical Equation – indicates the reactants and products in a rxn; it also tells you the relative amounts of reactants and products.
Stoichiometry Practice Problems Whole Topic Review.

Stoichiometry Practice Problems Whole Topic Review.
Mass relationships in chemical reactions: Stoichiometry

Mass relationships in chemical reactions: Stoichiometry
Chapter 9 Combining Reactions and Mole Calculations.

Chapter 9 Combining Reactions and Mole Calculations.
Stoichiometry, Limiting Reactants and Percent Yield

Stoichiometry, Limiting Reactants and Percent Yield
Chapter 9 Combining Reactions and Mole Calculations.

Chapter 9 Combining Reactions and Mole Calculations.
Stoichiometry.

Stoichiometry.
Stoichiometry Adjusting To Reality Adjusting To Reality  This is not the entire story. In reality, you never have the exact amounts of both reactants.

Stoichiometry Adjusting To Reality Adjusting To Reality  This is not the entire story. In reality, you never have the exact amounts of both reactants.
 Balance the following equation.  Fe + O 2  Fe 2 O 3  4Fe + 3O 2  2Fe 2 O 3  This means that when we combine four atoms of iron with three molecules.

 Balance the following equation.  Fe + O 2  Fe 2 O 3  4Fe + 3O 2  2Fe 2 O 3  This means that when we combine four atoms of iron with three molecules.
Limiting Reactants & Percent Yield

Limiting Reactants & Percent Yield
Chapter 3 Stoichiometry.

Chapter 3 Stoichiometry.
Recap – Molar Mass and Moles

Recap – Molar Mass and Moles
Limiting and Excess Reagents.  The reagent that is completely used up or reacted is called the limiting reagent, because its quantity limit the amount.

Limiting and Excess Reagents.  The reagent that is completely used up or reacted is called the limiting reagent, because its quantity limit the amount.
CHAPTER 3 Chemical E quations & Reaction Stoichiometry.

CHAPTER 3 Chemical E quations & Reaction Stoichiometry.
Limiting Reagents Stoichiometry Luckett. What is a limiting reagent? The reagent (reactant) that determines the amount of product that can be formed by.

Limiting Reagents Stoichiometry Luckett. What is a limiting reagent? The reagent (reactant) that determines the amount of product that can be formed by.
Stoichiometry Stoichiometry is a method used in chemistry to determine the amount of materials used and produced in a chemical reaction. It is a vital.

Stoichiometry Stoichiometry is a method used in chemistry to determine the amount of materials used and produced in a chemical reaction. It is a vital.

Similar presentations

Ads by Google