Chemistry
Chemistry
4th Edition
ISBN: 9780078021527
Author: Julia Burdge
Publisher: McGraw-Hill Education
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Chapter 19, Problem 46QP

If the cost of electricity to produce magnesium by the electrolysis of molten magnesium chloride is $155 per ton of metal, what is the cost (in dollars) of the electricity necessary to produce (a) 10.0 tons of aluminum, (b) 30.0 tons of sodium, and (c) 50.0 tons of calcium?

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Interpretation Introduction

Interpretation:

The cost of electricity required to form 10.0 tons of aluminum, 30.0 tons of sodium, and 50.0 tons of calcium is to be calculated with given cost of per ton of metal.

Concept introduction:

Electrolysis is thetechnique used to produce a chemical change in the given substance by passing an electric current through it.

Magnesium chloride is the compound of magnesium used in wind erosion. Magnesium is formed by the electrolysis of molten magnesium chloride.

The relationship between grams and tons can be represented as: 1 ton = 9.072×105 g

To Convert of 1 a mole of electron of element into a ton of element, the conversion factor is

M=(1 molelement mol e)×(molarmass)×(1 ton9.072×105 g).

The cost of electricity to form tons of element is calculated as: Cost =Cost of electricity per ton of metal×moles in per ton MgMoles in per ton of metal×Amount of metal

Answer to Problem 46QP

Solution:

(a)

The cost of electricity to form 10.0 tons of aluminum is $2.10×103.

(b)

The cost of electricity to form 30.0 tons of sodium is $2.46×103.

(c)

The cost of electricity to form 50.0 tons of calcium is $4.70×103.

Explanation of Solution

a) 10.0 tons of aluminum

The ton of the metal formed by 1 mole of the electron is to be calculated for the reduction reaction.

The reduction reaction is as follows:

Mg2++2eMg

1 ton = 9.072×105 g and the molar mass of Mg is 24.31 g.

Conversion of 1 a mole of electron of Mg into a ton of Mg is as follows:

M=(1 molelement mol e)×(molarmass)×(1 ton9.072×105 g)

MMg=(1 mol Mg2 mol e)×(24.31 g Mg1 mol Mg)×(1 ton9.072×105 g)MMg=1.340×105 ton Mg/mol e

Therefore, one mole of the electrons of Mg produces 1.340×105 ton Mg/mol e.

The reduction reaction for Al is as follows:

Al3++3eAl

1 ton = 9.072×105 g and the molar mass of Al is 26.98 g.

The conversion of 1 mole of the electrons of Al into a ton of Al is as follows:

M=(1 molelement mol e)×(molarmass)×(1 ton9.072×105 g)

MAl=(1 mol Al3 mol e)×(26.98 g Al1 mol Al)×(1 ton9.072×105 g)MAl=9.913×106 ton Al/mol e

Therefore, per mole of electrons forms 9.913×106 ton Al/mol e.

The amount given ofAl is 10.0 tons.

The cost of electricity to form 10.0 tons of aluminum is calculated as follows: Cost =Cost of electricity per ton of metal×moles in per ton MgMoles in per ton of metal×Amount of metal

Substitute the values in the above equation:

Cost=($1551 ton Mg)×(1.340×105 ton Mg1 mol e)×(1 mol e9.913×106 ton Al)×(10 ton Al)Cost=$2.10×103

Thus, the cost of electricity to form 10.0 tons of aluminum is $2.10×103.

b) 30.0 tons of sodium

The reduction reaction for Na is as follows:

Na++eNa

1 ton = 9.072×105 g and the molar mass of Al is 22.99 g.

The conversion of 1 mole of the electrons of Na into a ton of Na is as follows:

M=(1 molelement mol e)×(molarmass)×(1 ton9.072×105 g)

MNa=(1 mol Na1 mol e)×(22.99 g Na1 mol Na)×(1 ton9.072×105 g)MNa=2.534×105 ton Na/mol e

Therefore, per mole of electrons forms 2.534×105 ton Na/mol e.

The amount given ofNa is 30.0 tons.

The cost of electricity to form 30.0 tons of sodium is calculated as follows: Cost =Cost of electricity per ton of metal×Moles in per ton MgMoles in per ton of metal×Amount of metal

Substitute the values in the above equation:

Cost=($1551 ton Mg)×(1.340×105 ton Mg1 mol e)×(1 mol e2.534×105 ton Na)×(30 tons Na)Cost=$2.46×103

Thus, the cost of electricity to form 30.0 tons of sodium is $2.46×103.

c) 50.0 tons of calcium

The reduction reaction for Ca is as follows:

Ca2++2eCa

1 ton = 9.072×105 g and the molar mass of Ca is 40.08 g.

The conversion of 1 mole of the electrons of Ca into a ton of Ca is as follows:

M=(1 molelement mol e)×(molarmass)×(1 ton9.072×105 g)

MCa=(1 mol Ca1 mol e)×(40.08 g Ca1 mol Ca)×(1 ton9.072×105 g)MCa=2.209×105 ton Ca/mol e

Therefore, per mole of electrons forms 2.209×105 ton Ca/mol e.

The amount given ofCa is 50.0 tons.

The cost of electricity to form 50.0 tons of calcium is calculated as follows: Cost =Cost of electricity per ton of metal×moles in per ton MgMoles in per ton of metal×Amount of metal

Substitute the values in the above equation:

Cost=($1551 ton Mg)×(1.340×105 ton Mg1 mol e)×(1 mol e2.209×105 ton Ca)×(50 tons Ca)Cost=$4.70×103

Thus, the cost of electricity to form 50.0 tons of calcium is $4.70×103.

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Chapter 19 Solutions

Chemistry

Ch. 19.3 - Practice ProblemCONCEPTUALIZE A piece of nickel...Ch. 19.3 - Calculate E cell o at 25°C for a galvanic cell...Ch. 19.3 - 19.3.2 Calculate at for a galvanic cell made of a...Ch. 19.3 - 19.3.3 What redox reaction, if any. will occur at ...Ch. 19.3 - What redox reaction, if any. will occur at 25°C...Ch. 19.4 - Practice Problem ATTEMPT Calculate for the...Ch. 19.4 - Practice ProblemBUILD The hydrazinium ion, N 2 H 5...Ch. 19.4 - Practice Problem CONCEPTUALIZE Which of the...Ch. 19.4 - Calculate K at 25°C for the following reaction: Fe...Ch. 19.4 - 19.4.2 Calculate for the following reaction: Ch. 19.5 - Practice ProblemATTEMPT Calculate the equilibrium...Ch. 19.5 - Practice Problem BUILD Like equilibrium constants....Ch. 19.5 - Practice ProblemCONCEPTUALIZE Which of the...Ch. 19.5 - Calculate E at 25°C for a galvanic cell based on...Ch. 19.5 - 19.5.2 Calculate the cell potential at of a...Ch. 19.5 - 19.5.3 Calculate for a galvanic cell based on the...Ch. 19.5 - 19.5.4 Which of these would cause an increase in...Ch. 19.5 - 19.5.5 Determine the initial value of under the...Ch. 19.5 - Which of the following would cause a decrease in...Ch. 19.6 - Practice ProblemATTEMPT Will the following...Ch. 19.6 - Prob. 1PPBCh. 19.6 - Prob. 1PPCCh. 19.7 - Prob. 1PPACh. 19.7 - Prob. 1PPBCh. 19.7 - Practice Problem CONCEPTUALIZE When the circuit in...Ch. 19.7 - 19.7.1 In the electrolysis of molten , a current...Ch. 19.7 - 19.7.2 How long will a current of 0.995 A need to...Ch. 19.7 - The diagram shows an electrolytic cell being...Ch. 19.8 - Practice Problem ATTEMPT A constant current of...Ch. 19.8 - Practice Problem BUILD A constant current is...Ch. 19.8 - Practice ProblemCONCEPTUALIZE The diagram on the...Ch. 19 - How much copper metal can be produced by...Ch. 19 - What mass of cadmium will be produced by...Ch. 19 - Of the following aqueous solutions, identify the...Ch. 19 - 19.4 When a current of 5.22 A is applied over 3.50...Ch. 19 - Balance the following redox equations by the...Ch. 19 - Balance the following redox equations by the...Ch. 19 - Define the following terms: anode, cathode, cell...Ch. 19 - 19.4 Describe the basic features of a galvanic...Ch. 19 - 19.5 What is the function of a salt bridge? 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Electrolysis; Author: Tyler DeWitt;https://www.youtube.com/watch?v=dRtSjJCKkIo;License: Standard YouTube License, CC-BY