Chapter A2 2.4 – Voltaic Cells

Voltaic cells The rest of the chapter focuses on WHY this occurs. the focus on metals so far been been what happening on the surface of the metal tarnishing/ rusting, (aka color change), precipitate formation or bubbles/ gas formation The rest of the chapter focuses on WHY this occurs. a focus on the movement of electrons between the two metals

Voltaic cells though commonly a voltaic cell is referred to as a “battery”, technically cells are only referred to as a battery when several are together when an electronic device is operating, voltaic cells provide a continuous flow (current) of electrons, which is converted into current to power the device

Voltaic cells the voltaic cell that you know looks like this: this is the version of the voltaic cell we will make in the lab.

Voltaic cells an electrode is a solid piece of metal that is suspended in a solution (of the same metal ions as the electrode) and connected to an external circuit.

Voltaic cells the electrode zinc, is immersed into an electrolyte solution, where the zinc electrode acquires an excess of electrons, becoming negatively charged

Voltaic cells the other electrode is usually composed of a different material (copper) and will become positively charged

Voltaic cells once a circuit is closed between the two electrodes, the electrons will repel from the negative zinc electrode, pass through the circuit and flow through to the positive electrode

Voltaic cells the reaction will continue until the negative electrode can no longer be supply electrons.

Voltaic cells

Voltaic cells a salt bridge is a glass U-shaped tube that is filled with an ionic solution this is to allow for free flow of electrons from one solution to the other

How the cell works: because it is the more reactive of the two metals, the zinc electrode will become oxidized, (lose electrons) these electrons will travel from the electrode, through a metal wire, and then into an electronic device the device; a voltmeter, measures the quantity of electrons passing through it (= amount of electricity)

How the cell works: the electrons will pass through the device, back through another wire, into the copper electrode these electrons will be attracted to the Cu2+(aq) ions in the solution and they will be reduced. over time, the zinc electrode shrinks in size (as Zn  Zn2+) and the copper electrode grows (Cu2+  Cu)

How the cell works: if the two solutions were NOT connected, the zinc would run out of electrons and the cell would stop working the solution in the salt bridge allows a continuous flow of electrons back into the zinc solution

How the cell works:

Analyzing a voltaic cell: Step #1: identify the electrode where oxidation occurs locate the two metals on the activity series (right side) the metal closer to the BOTTOM will be OXIDIZED = reducing agent the electrode that is oxidized is called the anode the other electrode is reduced, and is called the cathode

Analyzing a voltaic cell: Step #2: describe the oxidation process in the anode write the oxidation half-reaction Eg. Pb(s)  Pb2+(aq) +2e- electrons leave the anode and travel to the external circuit running the electronic device the voltmeter measures the quantity of electrons (amount of electricity) being produced because the anode is the electrode where the electrons originate, it is considered the negative electrode

Analyzing a voltaic cell: Step #3: describe the reduction process in the anode the electrons travel through the voltmeter and into the cathode the electrons are attracted to the positively-charge metal ions in the cathode solution the cathode ions will unite with the electrons and form a solid metal, which is deposited on the electrode Eg. Ag+ (aq) + e-  Ag (s)

Analyzing a voltaic cell: Step #4: describe how the salt bridge completes the circuit all electrical circuits require a complete circuit in order to function. the salt bridge connects the cathode back to the anode to replenish the electrons on the anode side the salt bridge contains a third ionic solution the positive ions from the salt bridge solution will be attracted to the cathode, while the negative ions from the salt bridge solution will migrate toward the anode.

Voltaic Cell- Example in this voltaic cell: anode cathode KCl zinc is the _________ – it is oxidized copper is the __________– it is reduced the solution in the salt bridge is _____________ (aq) chloride ions are a spectator ion – their job is to replenish the electron supply at the anode anode cathode KCl

Cell Notation anode salt bridge cathode voltaic cells can also be represented using short hand cell notation Zn(s) | Zn2+(aq) || Cu2+(aq) | Cu(s) anode salt bridge cathode  oxidation reduction the anode is listed on the left, the cathode on the right (think alphabetical order) the vertical line | represents a boundary between a metal and its solution the double line || represents the salt bridge

Practice Problem #1: a) Draw a voltaic cell using the following supplies: two beakers U-tube & cotton balls wire & voltmeter tin and magnesium strips solutions of SnSO4(aq), MgSO4(aq), and NaNO3(aq) b) Label the direction of e- flow, the anode, cathode, OA, RA, - and + electrodes, voltmeter and salt bridge c) Write the short hand cell notation

Practice Problem #1 (Solution):

Assignment: Practice problem (page 87) Practice problems (page 91) 34 Practice problems (page 91) 37 & 39 Practice problem (page 92) 40 2.4 Summary 9page 94) Q’s 2, 3 & 6 pg 94

Homework Check-up Zn(s) / Zn2+(aq) // Ni2+ (aq) / Ni(s) Use the cell notation below to answer the following questions. Assume the salt bridge contains a solution of potassium nitrate (KNO3(aq) ) Zn(s) / Zn2+(aq) // Ni2+ (aq) / Ni(s) Identify which metal will be oxidized and which would be reduced Identify the anode and the cathode Write the half reactions that occur at each electrode Draw the voltaic cell. Label the direction of the electron flow and the anions of the salt bridge. Homework Check-up

Zn(s) / Zn2+(aq) // Ni2+ (aq) / Ni(s) According to the activity series, zinc is the more reactive metal- so Zn(s) is oxidized and the Ni2+(aq) are reduced. Anode = Oxidation= zinc metal Cathode = Reduction = nickel metal Oxidation: Zn(s) Zn2+(aq) + 2e– Reduction: Ni2+(aq) + 2e–  Ni(s) Identify which metal will be oxidized and which would be reduced (1 mark) Identify the anode and the cathode (1 mark) Write the half reactions that occur at each electrode

Zn(s) / Zn2+(aq) // Ni2+ (aq) / Ni(s) d) Draw the voltaic cell (2 marks) Label the direction of the electron flow (1 mark) and the anions of the salt bridge. (1 mark) Cell must have 2 beakers, (one with Zn(s) and Zn2+(aq), one with Ni(s) and Ni 2+ (aq)), connected by wires to a voltmeter, and a salt bridge Electrons must leave the Zn anode and flow towards the Ni cathode The negative NO3- anions are attracted to the anode. The positive K+ cations are attracted to the cathode (think alphabetical…Anion-Anode. Cation= Cathode)

Assignment: Complete the pre-lab assignment for the Voltaic Cells Lab Your pre-lab MUST BE done, in order to participate in the lab! ? ?

Chapter A2 2.5 – Electrolytic Cells

Electrolytic vs. Voltaic an electrolytic cell is a system where a non-spontaneous redox reaction is forced to occur a reaction that is non-spontaneous will only occur if energy is added in an electrolytic cell, energy is added in the form of electricity Voltaic Electrolytic spontaneous? yes no requires energy? produces voltage? use energy source electroplating change in energy exothermic endothermic

Electroplating metals, like gold and silver, that are the most stable and corrosion-resistant are also the most expensive to manufacture a metal object that is resistant to corrosion it would NOT be cost-effective to make the whole thing out of gold instead, a thin coating of gold is applied to the surface of a more affordable metal

Electroplating the object to be coated is submerged in a solution of the metal ions (e.g. silver ions for objects that are to be coated in silver metal) an external energy source (a battery) supplies energy forcing electrons to flow into the object the negatively charged electrons will attract the positively charged metal ions from the solution, and turn them back into metal atoms, which will accumulate on the surface of the object to be plated.

Electrolytic cells Step #1: electrons from the plating (the expensive) metal cathode are attracted to the + electrode of the power source by removing electrons from the metal atoms, ions are formed and added into the solution

Electrolytic cells Step #2: Step #3: once removed from the metal, the free electrons flow through the power source. Step #3: electrons are forced out of the - end of the power source and accumulate on the surface of the object to be plated

Electrolytic cells Step #4: positive Au+(aq) from the solution are attracted to the negative electrons in the object to be plated the Au+(aq)ions gain the electrons, and turn back into solid gold coating the object.

Electroplating electroplating is a good way to protect metals that are easily oxidized, like iron metals that work as good electroplaters (coatings) are chromium (aka chrome), platinum, silver and gold

Gold jewelry solid gold gold plated two types of gold jewelry exist - that which is made out of solid gold, and that which is gold plated solid gold karats - pure gold is 24K gold is a soft metal, so it is often combined with other metals like brass (copper and zinc) and nickel to make it more durable the number of karats in the gold refers to how many 1/24th of gold it contains gold plated if you have a piece of gold plated jewelry, care must be taken to avoid any deep scratches deep scratches will expose the oxidizable metal underneath

Other uses for electrolytic cells refining metals a sample of impure metal (anode), pure metal (cathode) ions of the pure metal will travel from the anode to the cathode to build up the atoms of pure metal electrolysis decomposition of a compound by means of an electric current e.g. electrolysis of water makes it decompose into O2 and H2

Other uses for electrolytic cells producing non-metals non-metals, especially the halogens, are difficult to obtain in pure form because they are so reactive non-metal atoms will accumulate around the anode of an electrolytic cell recharging voltaic cells when you use a battery recharger, you are using an electrolytic cell to reverse the process that occurs normally in the voltaic cell you are literally re-charging the voltaic cell with a new supply of electrons

Assignment: Complete the Voltaic & Electrolytic cells Worksheet

Assignment: Prepare for your Chapter A2 Exam