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42-0186-00-02-EXPOxidation-ReductionActivitySeries.pdf

Oxidation-Reduction Activity Series Hands-On Labs, Inc. Version 42-0186-00-02

Review the safety materials and wear goggles when working with chemicals. Read the entire exercise before you begin. Take time to organize the materials you will need and set aside a safe work space in which to complete the exercise.

Experiment Summary:

You will perform redox reactions and identify oxidizing and reducing agents. You will investigate the reactivity of metals and develop an activity series.

EXPERIMENT

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Learning Objectives Upon completion of this laboratory, you will be able to:

● Discuss oxidation-reduction reactions and identify oxidizing and reducing agents.

● Summarize the rules for assigning oxidation numbers.

● Describe single displacement reactions, spectators ions and activity series.

● Perform single displacement reactions on metals to develop an activity series.

● Write redox reactions based on experimental results.

● Apply the appropriate rules for assigning oxidation numbers.

Time Allocation: 2.5 hours

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Experiment Oxidation-Reduction Activity Series

Materials Student Supplied Materials

Quantity Item Description 1 Pair of scissors 1 Pencil 1 Pocket knife, disposable nail file, or sandpaper 1 Roll of paper towels 1 Sheet of white paper 1 Timer or clock

HOL Supplied Materials

Quantity Item Description 1 Pair of gloves 1 Pair of safety goggles 1 Plastic tweezers 1 Test tube, 13 x 100 mm 1 Test tube cleaning brush 1 Well plate - 24 1 Experiment Bag: Oxidation/Reduction Activity Series:

1 - Copper (II) sulfate, 1 M - 3 mL in pipet 1 - Copper foil, 4 pieces in bag 2” x 3” 1 - Lead metal, 4 pieces in bag 2” x 3” 1 - Lead (II) nitrate, 0.2 M - 2 mL in pipet 1 - Mossy zinc, 6-8 pieces in bag 2” x 3” 1 - Silver nitrate, 0.1 M - 6 mL in dropper bottle 1 - Zinc nitrate, 2 M - 3 mL in pipet

Note: To fully and accurately complete all lab exercises, you will need access to:

1. A computer to upload digital camera images.

2. Basic photo editing software such as Microsoft Word® or PowerPoint®, to add labels, leader lines, or text to digital photos.

3. Subject-specific textbook or appropriate reference resources from lecture content or other suggested resources.

Note: The packaging and/or materials in this LabPaq kit may differ slightly from that which is listed above. For an exact listing of materials, refer to the Contents List included in your LabPaq kit.

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Experiment Oxidation-Reduction Activity Series

Background Chemical Reactions

An oxidation-reduction reaction, or redox reaction, is a chemical reaction that occurs when electrons are transferred from one reactant to another. For example, hydrogen (H2) and fluorine (F2) react to produce hydrogen fluoride (HF). In the reaction, there is a partial transfer of one electron from the hydrogen atom to the fluorine atom, causing a chemical bond. The chemical equation for the redox reaction is shown in Equation 1.

The oxidation number, often referred to as the oxidation state, represents the charge an atom would have if electrons were completely transferred. In truth, hydrogen only partially donates an electron to fluorine, but for purposes of understanding the movement of the electron, charges can be assigned to each element. In hydrogen fluoride, the hydrogen atom has an oxidation number of +1 because one negative electron was lost, and the fluorine atom has an oxidation number of -1 because one electron was gained. It may be said that the hydrogen atom is in the +1 oxidation state, while the fluorine atom is in the -1 oxidation state. For the purpose of visualization, oxidation numbers can be written under each atom of the chemical equation, as shown in Equation 2. Notice that the charge for each of the reactants, elemental hydrogen and elemental fluorine, is 0.

Oxidation and Reduction

Oxidation is the loss of electrons by a substance undergoing a chemical reaction. During oxidation, the oxidation number of the element increases and becomes more positive. Reduction is the gain of electrons by a substance undergoing a chemical reaction. During reduction, the oxidation number of the element decreases and becomes more negative. In Equation 2, hydrogen is oxidized, it loses an electron, and its oxidation number increases; fluorine is reduced, it gains an electron, and its oxidation number decreases. Hydrogen may be referred to as the reducing agent because it donates electrons and reduces fluorine. Conversely, fluorine may be referred to as the oxidizing agent because it accepts electrons and oxidizes hydrogen.

A mnemonic device for remembering whether electrons are lost or gained is “OIL RIG”:

Oxidation Is Loss, Reduction Is Gain.

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Experiment Oxidation-Reduction Activity Series

During a reaction, electrons are neither created nor destroyed; they are merely transferred among atoms. Oxidation and reduction always occur together: oxidation does not occur without reduction, and reduction does not occur without oxidation. Therefore, the sum of the oxidation numbers left of the reaction arrow equals the sum of the oxidation numbers right of the reaction arrow. In Equation 2, the oxidation numbers of the reactants total 0, and the oxidation numbers of the products also total 0.

Figure 1. Walnuts are one of the most antioxidant-rich food sources available. © Pakhnyushcha

As a natural consequence of cellular

metabolism, oxidative processes cause damage to the cells and

tissues of the human body. Oxidation is widely believed to be one of the

primary causes of aging. Foods such as walnuts, artichokes, and blueberries

contain antioxidants, chemical substances that inhibit oxidation. See Figure 1.

Scientists are currently working to fully understand the role of oxidation in the

aging process and the effectiveness of consuming antioxidant-rich

foods.

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Experiment Oxidation-Reduction Activity Series

Assigning Oxidation Numbers

Many chemical compounds are composed of more than one of the same type of atom, and the oxidation numbers of each atom can be summed to find the total contribution to charge. For example, the compound magnesium chloride (MgCl2) is composed of one magnesium ion and two chloride ions. The chlorine ions each have an oxidation number equal to -1, which results in a total contribution of -2. The magnesium atom has an oxidation number equal to +2. Therefore, the MgCl2 formula unit has a total charge of zero. The oxidation numbers and the total contribution to charge can be designated simultaneously. In the following, the formula is listed in the first line, the oxidation numbers are listed in the second line, and the total contribution to charge is listed in the last line:

Molten magnesium chloride (MgCl2) can be decomposed into the pure elements magnesium (Mg) and chlorine (Cl) through electrolysis. Equation 3 shows the redox reaction. Notice that the sum of the total contribution of charge for the reactants is 0 and the total contribution of charge for the products is also 0.

The rules for assigning oxidation numbers follow. Although there are some exceptions, the rules generally work well and should be applied in the order they are listed.

Rules for Assigning Oxidation Numbers

1. When a substance is in its elemental form (existing alone without bonds to other elements), the oxidation number is 0.

2. A monoatomic ion has an oxidation number equal to its ionic charge.

3. A hydrogen atom is in the +1 oxidation state when it is combined with a nonmetal.

4. A hydrogen atom is in the -1 oxidation state when it is combined with a metal.

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Experiment Oxidation-Reduction Activity Series

5. The alkali metals of Group IA on the periodic table have the +1 oxidation state in a compound.

6. The alkaline earth metals of Group IIA on the periodic table have the +2 oxidation state in a compound.

7. Nonmetals in Group VIIA on the periodic table often have the -1 oxidation state in a compound.

8. Oxygen usually has an oxidation number of -2 in compounds. Exceptions are rare but can occur in compounds that contain more than one oxygen atom.

9. The sum of the oxidation numbers within a formula is equal to the overall charge of the formula. (In a neutral molecule, such as CH4, no charge is written next to the molecule, and the sum of the oxidation numbers is zero.)

10. The most electronegative element in a compound (the element that most attracts electrons) will have a negative oxidation number.

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Experiment Oxidation-Reduction Activity Series

Redox and Single Displacement Reactions

In this lab, single displacement reactions will be performed to demonstrate the process of oxidation and reduction. In a single displacement reaction, an element reacts with a compound and part of the compound is released to become a free molecule. For example, when iron (Fe) is placed in a solution of copper (II) sulfate (CuSO4), iron takes the place of copper to form iron (II) sulfate (FeSO4) solution; pure copper (Cu) is released as a free element. Fe is oxidized and acts as the reducing agent; Cu2+ is reduced and acts as the oxidizing agent. The sulfate ion (SO4) is considered a spectator ion because it is neither oxidized nor reduced. Equation 4 shows the chemical reaction with oxidation numbers and total charge contributions.

When an iron nail is placed in a beaker of CuSO4 solution, iron displaces copper, producing FeSO4 and pure Cu. The Cu accumulates on the outside of the nail, as shown in Figure 2.

Figure 2. Iron nail and copper (II) sulfate (CuSO4) solution. Iron reacts to displace copper in CuSO4. Pure copper accumulates on the outside of the nail.

The reaction between iron and copper (II) sulfate occurs because iron metal is more easily oxidized than copper. In other words, iron atoms are more apt to lose electrons, thus iron is more “active” than copper and replaces copper ions in solution. Electrons move from iron atoms to copper ions forming iron ions and copper atoms. These atoms have moved from a higher energy, less stable location (the active iron atoms) to a lower energy, more stable location (the less active copper atoms).

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Experiment Oxidation-Reduction Activity Series

Metals can be ordered from most active (easily oxidized) to least active (not easily oxidized) in a list called an activity series. Figure 3 is an activity series for a small selection of metals.

Figure 3. Activity series of five metals.

Note that iron is listed higher than copper because it is more active and more easily oxidized. Figure 3 confirms that a reaction occurs between solid iron and copper ions in solution. On the other hand, iron is listed below chromium in the activity series. What would you expect if solid iron was placed in a solution containing chromium ions? Based on what you know, will the iron displace the chromium ions? That is, will iron atoms transfer electrons to chromium ions? In this laboratory experiment, you will create an activity series based on your observations of chemical reactions.

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Experiment Oxidation-Reduction Activity Series

Exercise 1: Describing an Oxidation-Reduction Reaction In this exercise, you will add a solution that contains silver ions to elemental copper to elicit a redox reaction. You will observe the reaction and then write an equation that describes the movement of electrons.

CAUTION! You must wear your gloves and goggles during both exercises.

Procedure

1. Gather a test tube, the silver nitrate (AgNO3) solution, the copper foil pieces (Cu), and the plastic forceps (tweezers).

Note: Use plastic forceps, as metal forceps may react with the other metals in the experiment.

2. Record initial observations of the appearance of the AgNO3 and Cu in Data Table 1 in your Lab Report Assistant.

Note: To observe the AgNO3, place a small drop on a folded piece of paper towel, plastic wrap, or a plastic baggie. Then, discard in the trash. Be careful, as AgNO3 causes stains.

3. Use the plastic forceps to add 2 pieces of Cu to the test tube.

4. Add the entire contents of the AgNO3 bottle to the test tube. Discard the empty bottle in a trash bin.

Note: Take care to avoid any skin contact with the silver nitrate.

5. Observe the reaction for about 1 minute. Describe the appearance of any solids, liquids, and gases in the test tube. Record observations in Data Table 1.

6. Allow the reaction to continue for 30 minutes, and again record observations of the appearance of liquids, gases, and solids in Data Table 1.

Note: As you wait, continue with the final steps of the exercise and complete the questions at the end of the exercise.

7. In Data Table 1, write a balanced chemical equation for the redox reaction. Include oxidation numbers and total charge contributions for the elements involved in the reaction.

8. Identify the element that is oxidized and the element that is reduced. Identify the spectator ion, the ion that exists in the same form in both the reactants and the products. Record each in Data Table 1.

9. Identify which element acted as the oxidizing agent, and identify which element acted as the reducing agent. Record each in Data Table 1.

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Experiment Oxidation-Reduction Activity Series

Cleanup:

10. Properly dispose of the reactants.

11. Clean the test tube with soap and water, dry, and place the test tube back in your kit for future use.

Questions A. Define oxidation, reduction, and oxidation number. Describe how oxidation and reduction

affect the oxidation number of an element.

B. Define oxidizing agent, reducing agent, and spectator ion.

C. In the reaction of copper and silver nitrate, a new substance appeared in the test tube. Describe the physical appearance of the substance and identify its chemical formula.

D. Given an activity series in which the most active metals are at the top of the list and the least active metals are at the bottom of the list, would copper be listed above silver or would silver be listed above copper? Support your answer with data from Data Table 1.

E. Solid copper sulfide and silver nitrate react to form copper (II) nitrate and solid silver sulfide. Write a balanced chemical equation that describes the reaction. Identify the oxidation number of each element in the reaction. (You do not need to include the total contribution of charge.) Is this reaction a redox reaction or a non-redox reaction? Explain your answer.

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Experiment Oxidation-Reduction Activity Series

Exercise 2. Creating an Activity Series In this exercise, you will make observations of copper, lead, and zinc and determine if a successful chemical reaction has occurred. Use your observations to order the metals in an activity series.

CAUTION! Make sure that you are wearing gloves and goggles. In this lab, you will handle solid lead, which can be hazardous. Handle with caution, and keep children and pets away from this and any experiment.

Procedure

1. Locate a 24 well plate. See Figures 4 and 5 for examples of labeling.

Note: Row and column labels for each well are etched in the plastic of the well plate, as shown in Figure 4. Labeling a white piece of paper and placing it under the well plate can help you accurately add the chemicals to each well. See Figure 5 for an example of labeling. In this lab, you will only need to label wells A1, A2, B1, B2, C1, and C2.

Figure 4. Labeled 24-well plate.

Figure 5. Examples of well plate labels. A. Drawing rows and columns of the well plate. B. Well plate over a hand-labeled sheet of white paper.

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Experiment Oxidation-Reduction Activity Series

2. Locate the copper foil pieces (Cu) and plastic forceps.

3. Place a piece of copper in well A1 and well A2 of the well plate.

4. Locate the lead (II) nitrate (Pb(NO3)2) pipet, and snip the tip off with scissors. Add 15 drops of Pb(NO3)2 to well A1.

5. Observe well A1 for about 1 minute and record any immediate signs of a chemical reaction in Data Table 2 in your Lab Report Assistant.

Note: Some examples of indicators of a chemical reaction include darkening of the metal and formation of bubbles. A chemical reaction may or may not occur.

6. Note the time, as observations will again be made after 30 minutes.

7. Locate the zinc nitrate (Zn(NO3)2) pipet, and snip the tip off with scissors. Add 15 drops of Zn(NO3)2 to well A2.

8. Observe well A2 for about 1 minute and record any immediate signs of a chemical reaction in Data Table 2.

9. Gather 2 lead squares (Pb) and a paper towel. Use the forceps to place the 2 pieces of lead on the paper towel.

10. Locate a pocket knife, nail file, or piece of sandpaper. Carefully scrape the surface of the lead, removing any rust that may have accumulated.

CAUTION! Always keep the lead on top of the paper towel, as lead shavings can be hazardous. Scrape the surface of the lead until it looks shiny, as shown in Figure 6. Gently wipe each square on the paper towel to remove any lead shavings.

Figure 6. Lead square (left) and prepared lead that has been cleaned of rust (right).

11. Place the prepared lead squares in wells B1 and B2 of the well plate.

12. Carefully dispose of the paper towel and all lead particles. If using a nail file or piece of sandpaper, dispose of the item in a trash bin. If using a pocket knife, thoroughly wash the knife with soap and tap water. Alternatively, you may take the lead to a waste disposal station.

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Experiment Oxidation-Reduction Activity Series

13. Remove your gloves, carefully turning them inside out and placing them in the trash. Wash your hands with soap and water; dry them with paper towels. Dispose of the paper towels in the trash bin.

14. Put on a new pair of gloves before continuing the exercise.

15. Locate the copper (II) sulfate (CuSO4) pipet and snip the tip off with scissors. Add 15 drops of CuSO4 to well B1. Record observations after about 1 minute in Data Table 2.

Note: Forceps may be used to lift the lead from the copper solution for closer examination. Rinse the forceps with tap water. See Figure 7.

Figure 7. Using the forceps to examine lead.

16. Add about 15 drops of Zn(NO3)2 to well B2. Record observations after about 1 minute in Data Table 2.

17. Locate 2 pieces of mossy zinc (Zn). Place a piece of zinc in well C1 and well C2.

18. Add about 15 drops of CuSO4 to well C1 and record observations after about 1 minute in Data Table 2.

19. Add about 15 drops of Pb(NO3)2 to well C2 and record observations after about 1 minute in Data Table 2.

20. After 30 minutes have passed, again record observations for all reactions.

21. Use the observations recorded in Data Table 2 to determine whether a chemical reaction occurred in each instance. Use Data Table 3 of your Lab Report Assistant to record “yes” or “no” to indicate whether or not a reaction occurred.

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Experiment Oxidation-Reduction Activity Series

22. In Data Table 3, for each instance that you recorded “yes,” write a balanced chemical equation that represents the reaction. Include oxidation numbers and the total contribution of charge for the elements involved in the reaction underneath each element or compound (as demonstrated in the Background). For each instance you recorded “no,” write “no reaction” in place of the chemical equation.

Cleanup:

23. Properly dispose of remaining reactants and pipets.

24. Wash and dry the equipment and return to the kit for future use.

Questions A. List each of the metals tested in Exercise 2. Indicate the oxidation number when each element

is pure and the oxidation number when each element is in a compound.

B. Which of the metals in Exercise 2 was the strongest oxidizing agent? Was there an instance when this metal also acted as a reducing agent? Explain your answer using data from Data Table 3.

C. Which of the metals in Exercise 2 was the strongest reducing agent? Was there an instance when this metal also acted as an oxidizing agent? Explain your answer using data from Data Table 3.

D. How does ease of oxidation correlate with activity? Do highly active metals tend to donate electrons or accept electrons from other metals?

E. Create an activity series for copper, lead, and zinc. Place the most active metal at the top of the list.