Single Replacement Reactions

Similar documents
Chapter 5. Chemical Reactions and Equations. Introduction. Chapter 5 Topics. 5.1 What is a Chemical Reaction

Chemistry Themed. Types of Reactions

Chemical Equations. Chemical Equations. Chemical reactions describe processes involving chemical change

NET IONIC EQUATIONS. A balanced chemical equation can describe all chemical reactions, an example of such an equation is:

Balancing Chemical Equations Worksheet

Experiment 1 Chemical Reactions and Net Ionic Equations

Chemical Equations and Chemical Reactions. Chapter 8.1

Chapter 8 - Chemical Equations and Reactions

2. DECOMPOSITION REACTION ( A couple have a heated argument and break up )

Chapter 8: Chemical Equations and Reactions

Experiment 5. Chemical Reactions A + X AX AX A + X A + BX AX + B AZ + BX AX + BZ

6 Reactions in Aqueous Solutions

Writing and Balancing Chemical Equations

Aqueous Solutions. Water is the dissolving medium, or solvent. Some Properties of Water. A Solute. Types of Chemical Reactions.

Stoichiometry Review

Chapter 6 Notes Science 10 Name:

Solution. Practice Exercise. Concept Exercise

EXPERIMENT 8: Activity Series (Single Displacement Reactions)

Chapter 16: Tests for ions and gases

David A. Katz Chemist, Educator, Science Communicator, and Consultant Department of Chemistry, Pima Community College

Moles. Moles. Moles. Moles. Balancing Eqns. Balancing. Balancing Eqns. Symbols Yields or Produces. Like a recipe:

Writing, Balancing and Predicting Products of Chemical Reactions.

Moles, Molecules, and Grams Worksheet Answer Key

Decomposition. Composition

Reactions in Aqueous Solution

Steps for balancing a chemical equation

Writing Chemical Equations

Experiment 8 - Double Displacement Reactions

Santa Monica College Chemistry 11

Types of Reactions. CHM 130LL: Chemical Reactions. Introduction. General Information

General Chemistry Lab Experiment 6 Types of Chemical Reaction

Name: Class: Date: 2 4 (aq)

Department of Chemical Engineering Review Sheet Chemical Reactions Prepared by Dr. Timothy D. Placek from various sources

UNIT (4) CALCULATIONS AND CHEMICAL REACTIONS

SCH 4C1 Unit 2 Problem Set Questions taken from Frank Mustoe et all, "Chemistry 11", McGraw-Hill Ryerson, 2001

Molarity of Ions in Solution

Chemistry: Chemical Equations

IB Chemistry. DP Chemistry Review

NAMING QUIZ 3 - Part A Name: 1. Zinc (II) Nitrate. 5. Silver (I) carbonate. 6. Aluminum acetate. 8. Iron (III) hydroxide

HOMEWORK 4A. Definitions. Oxidation-Reduction Reactions. Questions

neutrons are present?

Chemical Reactions in Water Ron Robertson

W1 WORKSHOP ON STOICHIOMETRY

Unit 10A Stoichiometry Notes

stoichiometry = the numerical relationships between chemical amounts in a reaction.

GCSE Chemistry. Making Salts Instructions and answers for teachers

Chapter 12: Oxidation and Reduction.

Chapter 3 Mass Relationships in Chemical Reactions

Balancing Chemical Equations Practice

2. Write the chemical formula(s) of the product(s) and balance the following spontaneous reactions.

1. Read P , P & P ; P. 375 # 1-11 & P. 389 # 1,7,9,12,15; P. 436 #1, 7, 8, 11

Chemistry Post-Enrolment Worksheet

Topic 4 National Chemistry Summary Notes. Formulae, Equations, Balancing Equations and The Mole

Chapter 11. Electrochemistry Oxidation and Reduction Reactions. Oxidation-Reduction Reactions. Oxidation-Reduction Reactions

1. When the following equation is balanced, the coefficient of Al is. Al (s) + H 2 O (l)? Al(OH) 3 (s) + H 2 (g)

Periodic Table, Valency and Formula

H 2 + O 2 H 2 O. - Note there is not enough hydrogen to react with oxygen - It is necessary to balance equation.

Molar Mass Worksheet Answer Key

Chem 1100 Chapter Three Study Guide Answers Outline I. Molar Mass and Moles A. Calculations of Molar Masses

CHEMICAL REACTIONS OF COPPER AND PERCENT YIELD KEY

Atomic Structure. Name Mass Charge Location Protons 1 +1 Nucleus Neutrons 1 0 Nucleus Electrons 1/ Orbit nucleus in outer shells

Monatomic Ions. A. Monatomic Ions In order to determine the charge of monatomic ions, you can use the periodic table as a guide:

Nomenclature and Formulas of Ionic Compounds. Section I: Writing the Name from the Formula

Periodic Table Questions

Unit 9 Stoichiometry Notes (The Mole Continues)

Chapter 6: Writing and Balancing Chemical Equations. AB A + B. CaCO3 CaO + CO2 A + B C. AB + C AC + B (or AB + C CB + A)

Chapter 7: Chemical Reactions

1332 CHAPTER 18 Sample Questions

CHAPTER 5: MOLECULES AND COMPOUNDS

Stoichiometry. Lecture Examples Answer Key

WRITING CHEMICAL FORMULA

Word Equations and Balancing Equations. Video Notes

Appendix D. Reaction Stoichiometry D.1 INTRODUCTION

Solution a homogeneous mixture = A solvent + solute(s) Aqueous solution water is the solvent

Chemistry 12 Worksheet Measuring Reaction Rates

Number of moles of solute = Concentration (mol. L ) x Volume of solution (litres) or n = C x V

Chapter 17. How are acids different from bases? Acid Physical properties. Base. Explaining the difference in properties of acids and bases

Balancing Reaction Equations Oxidation State Reduction-oxidation Reactions

Nomenclature of Ionic Compounds

Balancing Chemical Equations

11-1 Stoichiometry. Represents

Chapter 4 Chemical Reactions

Naming Compounds Handout Key

Formulae, stoichiometry and the mole concept

Physical Changes and Chemical Reactions

Unit 4 Conservation of Mass and Stoichiometry

Instructions Answer all questions in the spaces provided. Do all rough work in this book. Cross through any work you do not want to be marked.

EXPERIMENT 7 Reaction Stoichiometry and Percent Yield

Chapter 5, Calculations and the Chemical Equation

Aqueous Ions and Reactions

YIELD YIELD REACTANTS PRODUCTS

Chemistry Final Study Guide

Moles. Balanced chemical equations Molar ratios Mass Composition Empirical and Molecular Mass Predicting Quantities Equations

Chapter 3 Stoichiometry

Question Bank Electrolysis

Problem Solving. Percentage Composition

CHAPTER 21 ELECTROCHEMISTRY

Chapter 17. The best buffer choice for ph 7 is NaH 2 PO 4 /Na 2 HPO 4. 19)

Multiple Choice Identify the letter of the choice that best completes the statement or answers the question.

Transcription:

Single Replacement Reactions CW single replacement reactions content 032112.doc As you have found out from your overview of chemical reactions, a single replacement reaction is one where an element reacts with a compound (often in aqueous solution) and an element and a compound are produced. A single replacement reaction is the chemical equivalent of "cutting in" at the chemical prom. Continuing our theme of studying the behavior of ions in solution, we will concentrate on single replacement reactions that occur in aqueous solution. If a reaction occurs and the element is a metal, then it will replace the metal in the compound. If a reaction occurs, and the element is a halogen, then it will replace the halogen in the compound. Zn(s) + Cu(NO 3 ) 2 (aq) Zn(NO 3 ) 2 (aq) + Cu(s) Cl 2 (aq) + 2NaI(aq) 2NaCl(aq) + I 2 (aq) Goals for your study of single replacement reactions: 1. Recognize a reaction as being single replacement. 2. Be able to predict if a reaction will occur or not (using the activity series). 3. Determine the formulas of the products (paying attention to oxidation numbers). 4. Determine if the compound that is formed is insoluble in water (solubility rules). 5. Balance the molecular equation. 6. Write a balanced net ionic equation. And just like some couples refuse to let someone cut in, some single replacement reactions simply don't occur. For instance, zinc metal will react with copper ions in solution... Zn(s) + Cu(NO 3 ) 2 (aq) Zn(NO 3 ) 2 (aq) + Cu(s) which means that zinc can "cut in", but copper metal won't react with zinc ions at all. Cu(s) + Zn(NO 3 ) 2 (aq) no reaction Zinc nitrate doesn't allow copper to "cut in". So just why do some single replacement reactions occur and others do not?

Goal One -- Pick out the single replacement reactions: 1) F 2 + NaBr NaF + Br 2 2) Ca(OH) 2 + Al 2 (SO 4 ) 3 CaSO 4 + Al(OH) 3 3) Mg + Fe 2 O 3 Fe + MgO 4) C 2 H 4 + O 2 CO 2 + H 2 O 5) PbSO 4 PbSO 3 + O 2 6) NH 3 + I 2 N 2 I 6 + H 2 7) H 2 O + SO 3 H 2 SO 4 8) H 2 SO 4 + NH 4 OH H 2 O + (NH 4 ) 2 SO 4 9) Na + H 2 O NaOH + H 2 10) H 2 + I 2 HI Did you find four reactions which are single replacement? List the numbers on the line below: Balance all of the reactions for practice, and identify the type of reaction for the remaining reactions. Do that on notebook paper. Goal Two -- Predict if a single replacement reaction actually will occur. Just like it is important to be able to determine if a double replacement reaction actually occurs when two compounds are mixed together by looking at the solubility rules, we must determine if a reaction occurs in a single replacement reaction. Will the element replace an element in a compound? To make that determination we use the activity series. You can find the activity series in your NCDPI reference tables on page 7. It is reprinted here for your convenience. Earlier, we mentioned the following two reactions. If a piece of zinc is added to a solution of copper(ii) nitrate the zinc will dissolve to form zinc(ii) ions (Zn 2+ ). The copper(ii) ions (Cu 2+ ) will come out of solution as copper metal and deposit on the surface of the zinc. Zn(s) + Cu(NO 3 ) 2 (aq) Zn(NO 3 ) 2 (aq) + Cu(s) If, instead, a piece of copper is added to a solution of zinc ions in solution, nothing will happen. The copper metal is not active enough to replace the zinc ions in solution. Cu(s) + Zn(NO 3 ) 2 (aq) no reaction We can predict those results by looking at the position of zinc and copper on the activity series. Zinc is well above copper, which is close to the bottom of the table. An element will replace the ions below it in the activity series, but not above it.

Look at the activity series for metals. Let s break the elements down by what they react with. Starting from the top we see alkali metals (Li, Na, K and Rb) plus the more active alkaline earth metals (Ca, Sr and Ba). These metals react easily with water. So simply adding any one of these metals to water will initiate a single replacement reaction making a solution of the metal hydroxide and liberating hydrogen gas. The Group IA metals make for some pretty exciting reactions, while the alkaline earth metals are much more tame. Look at the video: http://www.open.edu/openlearn/science-maths-technology/science/chemistry/alkali-metals In English universities they have a person who conducts the demonstrations for lecture classes. I was the demonstrator when I was in high school. My first exposure to the reactions of sodium left an indelible mark on the ceiling of my chemistry room at our sister high school. Even without being told, I instinctively knew not to throw water on a sodium fire. Below are the molecular, ionic and net ionic equations. Notice that the ionic and net ionic equations are one in the same. There are no spectator ions. 2Na(s) + 2H 2 O(l) 2NaOH(aq) + H 2 (g) 2Na(s) + 2H 2 O(l) 2Na + + 2OH - + H 2 (g) When an alkali metal is added to water which contains an acid-base indicator such as phenolphthalein, the solution will turn pink due to the excess of hydroxide ions, indicating that the solution is basic. As you can see from the photo, a great deal of heat is liberated, igniting the hydrogen gas that is produced. A problem for some teachers who may not be thinking it through completely, is to give a problem in which contains an alkali metal and a metal ion which is lower in the activity series. For instance, I ve see this reaction proposed, with the student asked to predict the products. K(s) + ZnCl 2 (aq)??? Does anyone see a problem with this? Sure, zinc is lower than potassium in the activity series, and some zinc metal may be produced, but the major reaction is going to be between the potassium and the water in the solution. So this is a bad idea. You would not use potassium metal to recover the zinc in a solution of zinc chloride. The potassium will simply react with the water that is also present. So how would you convert zinc ions in a solution of zinc chloride to metallic zinc? Choose an element above zinc, but one that won t react with the water in the solution. Something like magnesium. Mg(s) + ZnCl 2 (aq) MgCl 2 (aq) + Zn(s) In this case the magnesium, being above zinc in the activity series will go into solution as magnesium ions, Mg 2+, and the zinc ions will be converted to elemental zinc metal. This brings us to the second group of metals in the activity series. The group of metals which react with water only when it is superheated steam consist of Mg, Al, Mn, Zn, Cr, Fe and Cd. These metals will react with hot water vapor to produce the metal ion and hydrogen gas. Also keep in mind that the elements at the top of the list, Li, Na, K, Rb, Ca, Sr and Ba, will also react with hot water vapor to produce the metal ion and hydrogen gas.

Al Al Passivating layer of Al 2 O 3 There is one interesting exception to this. Aluminum metal. Aluminum is an interesting metal because it appears to be very nonreactive. Your aluminum lawn furniture sits around outside for years and doesn t corrode. That s because aluminum is already corroded, and covered in a very thin layer of aluminum oxide, Al 2 O 3. Even when scratched off, the metal corrodes very quickly, reforming a layer of Al 2 O 3. The layer of aluminum oxide, Al 2 O 3, forms an impenetrable barrier of on the surface of aluminum. This barrier, called a passivating layer protects the aluminum from any further reaction with oxygen. But in a concentrated solution of base, the aluminum oxide is soluble and dissolves, exposing the bare aluminum metal. Under these conditions aluminum reacts vigorously with water, much like an alkaline earth metal, producing aluminum hydroxide and hydrogen gas. In an excess of hydroxide ions, the aluminum oxide layer dissolves to form a complex ion of aluminum and hydroxide ions. Al 2 O 3 + 2OH - + 3H 2 O 2Al(OH) 4 - Now the aluminum metal is exposed, and it can react with water to make solid aluminum hydroxide and hydrogen gas. Al(s) + H 2 O Al(OH) 3 (s) + H 2 (g) This is the basis for the chemistry of solid drain cleaners like Drano. Drano consists of solid flakes of sodium hydroxide along with small pieces of aluminum foil. When wet, the hydroxide ions allow for the dissolving the passivating layer of aluminum oxide and the aluminum metal reacts with water to make bubbles of H 2 gas. These bubbles of hydrogen gas provide the agitation needed to help the sodium hydroxide solution dissolve the hair that makes up the clog. Hair is soluble in concentrated base solutions, and hair is what is usually clogging the bathroom sink. Finally we see that all metals located above hydrogen in the activity series will react with acids (which always give hydrogen ions) to make hydrogen gas. In fact, it is the metal reacting with the hydrogen ions in the metal. Zn(s) + 2HCl(aq) ZnCl 2 (aq) + H 2 (g) None of the metals below hydrogen will react with hydrogen ions to make hydrogen gas. This is why copper metal is impervious to almost all acids. The one exception, is nitric acid. Nitric acid, HNO 3, is the exception to the rule and is the only acid that many metals below hydrogen will dissolve in. But the key to these reactions is the nitrate ion. In the case of the vigorous reaction between copper and nitric acid, the reaction is actually between copper and the nitrate ion, NO 3 -. And this brings us back to Ira Remsen and the observation that nitric acid acts upon copper. 3Cu(s) + 8HNO 3 (aq) 3Cu(NO 3 ) 2 (aq) + 2NO(g) + 4H 2 O(l)

The reaction of copper with nitric acid is deceptive, in that the reactants look like a single replacement reaction. There is an element reacting with a compound. But the products don t fit the pattern. Therefore, the reaction of copper with nitric acid is more complex than a simple single replacement. Therefore, let us look at some single replacement reactions that do fit the pattern and apply your six goals. Goals for your study of single replacement reactions: 1. Recognize a reaction as being single replacement. 2. Be able to predict if a reaction will occur or not (using the activity series). 3. Determine the formulas of the products (paying attention to oxidation numbers). 4. Determine if the compound that is formed is insoluble in water (solubility rules). 5. Balance the molecular equation. 6. Write a balanced net ionic equation. The following reactions come from the worksheet taken from the internet and found at http://c7chemistry.wikispaces.com/file/view/single%20replacement%20worksheet.pdf 1. Zinc metal is added to sulfur acid. We certainly have an element reacting with a compound. The reactants fit the pattern for a single replacement reaction. The metal will replace a metal or hydrogen. Zn(s) + H 2 SO 4 will zinc hydrogen ions? The since Zn is above H in the activity series, zinc will replace hydrogen and a reaction will occur. Go on to complete the remaining goals. What are the products? ZnSO4. Is ZnSO4 soluble in water? Yes. It will be in aqueous solution. The other product is hydrogen gas, and hydrogen is diatomic, so write the formula as H2(g). The balanced molecular equation is: Zn(s) + H 2 SO 4 (aq) ZnSO 4 (aq) + H 2 (g) Since zinc sulfate is soluble in water it will exist as Zn2+ ions and SO4^2- ions. But remember that sulfuric acid ionizes as H+ and HSO4- ions. Therefore, the net ionic equation and the net ion will be the same: Zn(s) + H + + HSO 4 - Zn 2+ + SO 4 2- + H 2 (g) 2. Aluminum metal is added to a solution of (barely soluble) calcium sulfide. It fits the pattern of a single replacement reaction, but since aluminum is below calcium, there will be no reaction. We would write: Al(s) + CaS(aq) no reaction 3. Chlorine gas is bubbled into a solution of potassium bromide. This is case where a halogen reacts with the halide ion (bromide ion). Will chlorine replace bromine? Yes. Look at the activity series for halogens. Chlorine is above bromine. Therefore, our balanced molecular equation is: Cl 2 (g) + 2KBr(aq) 2KCl(aq) + Br 2 (l) Pay attention to the state symbols and the solubility rules. KCl is soluble in water. Bromine and chlorine are both diatomic in the elemental state, so don t forget the subscript 2 for both of them. We would write the ionic equation as: Cl 2 (g) + 2K + + 2Br - 2K + + 2Cl - + Br 2 (l) Notice that potassium is a spectator ion, and so we can eliminate it from the net ionic equation: Cl 2 (g) + 2Br - 2Cl - + Br 2 (l)

4. Magnesium metal is placed into a solution of acetic acid (ethanoic acid). Again we have a metal reacting with a compound, in this case an acid. Since magnesium is above hydrogen in the activity series a reaction will occur. The products will be a solution of magnesium acetate, which is soluble in water, and hydrogen gas. Mg(s) + 2HC 2 H 3 O 2 (aq) Mg(C 2 H 3 O 2 ) 2 (aq) + H 2 (g) Acetate ion will be the spectator ion, since both the acid and magnesium sulfate are soluble in water. Mg(s) + 2H + Mg 2+ + H 2 (g) 5. Chlorine gas is bubbled into a solution of magnesium bromide. This reaction is basically, a repeat of the reaction in #3, where the halogen will replace the halide ion. Remember that metals replace metals and halogens replace halogens. Cl 2 (g) + 2MgBr 2 (aq) 2MgCl 2 (aq) + Br 2 (l) Since magnesium ions are spectator ions, the net ionic equation is the same as it was in #3. Cl 2 (g) + 2Br - 2Cl - + Br 2 (l) 6. Potassium metal is added to a solution of magnesium bromide. Here is an example of a teacher picking an inappropriate set of reactants. Never mind whatever else is in solution, the potassium metal will react violently with the water in the solution. Some magnesium metal may be formed, and so we will write the reaction for that. Notice that we must write the formulas correctly in light of the oxidation numbers of Mg and K. K(s) + MgBr2(aq) 2KBr(aq) + Mg(s) Bromide ion is the spectator ion, and so the net ionic equation is: K(s) + Mg 2+ 2K + + Mg(s) Exercises: Cover the six goals as you write the balanced molecular and net ionic equations for the following on notebook paper. Be sure to pay attention to writing the correct formulas of the products based on their oxidation numbers. Use the solubility rules to determine the state symbols. 1. Fe(s) + CuSO 4 (aq)??? Hint: iron in the product will be in the +2 oxidation state. 2. Rb(s) + H 2 O(l)??? Hint: This will make a big bang! 3. F 2 (g) + FeCl 3 (aq)??? 4. Zn(s) + H 2 S(aq)??? 5. Au(s) + H 2 SO 4 (aq)??? 6. Mg(s) + CrCl 3 (aq)??? 7. Mn(s) + AgNO 3 (aq)??? Hint: manganese in the product will be in the +3 oxidation state. 8. I 2 (aq) + NaCl(aq)??? 9. Ca(s) + H 2 O(l)??? 10. Co(s) + Fe(NO 3 ) 2 (aq)???

2026 © DocPlayer.net Privacy Policy | Terms of Service | Feedback  | Do Not Sell My Personal Information