PRINCIPLES OF INSTRUMENTAL ANALYSIS
PRINCIPLES OF INSTRUMENTAL ANALYSIS
7th Edition
ISBN: 9789353506193
Author: Skoog
Publisher: CENGAGE L
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Chapter 22, Problem 22.5QAP
Interpretation Introduction

(a)

Interpretation:

The potential of a silver electrode in contact with solution, which is 0.0255M in I2 and saturated with AgI should be determined.

Concept introduction:

The electrode potential of the cell is the difference of potential difference of two electrodes. Here, the electrode potential of the cell is potential difference of electrode and solution.

Expert Solution
Check Mark

Answer to Problem 22.5QAP

The potential of a silver electrode in contact with solution of 0.0255M in I2 and saturated with AgI is 0.0567V.

Explanation of Solution

The concentration of I2 is 0.0255M.

The he half cell reaction for AgI is:

AgI(s)+eAg(s)+I

The initial electrode potential is 0.151V.

The expression for the Nernst equation for the above reaction is:

E=E00.0592nlogaPaR ...... (I)

Here, the initial electrode potential is E0, the number of electrons is n, the activity of the product is aP, and the activity of the reactant is aR.

The number of electrons for half cell reaction is 1 and the activity of the product is 1M.

Substitute 1M for aP, 1 for n, 0.0255M for aR, and 0.151V for E0 in Equation (I).

E=(0.151V)(0.0592V1)log(0.0255M1M)=(0.151V)(0.0592V)(1.593)=(0.151V)+0.0943V=0.0567V

Interpretation Introduction

(b)

Interpretation:

The potential of a silver electrode in contact with solution, which is 0.0035M in CN and 0.0550M in Ag(CN)2 should be determined.

Concept introduction:

The electrode potential of the cell is the difference of potential difference of two electrodes. Here, the electrode potential of the cell is potential difference of electrode and solution.

Expert Solution
Check Mark

Answer to Problem 22.5QAP

The potential of a silver electrode in contact with solution, which is 0.0035M in CN and 0.0550M in Ag(CN)2 is 0.093V.

Explanation of Solution

The concentration in CN is 0.0035M and concentration in Ag(CN)2 is 0.0550M.

The half cell reaction for Ag(CN)2 is:

Ag(CN)2(aq)+eAg(s)+2CN(aq)

The initial electrode potential is 0.31V.

Substitute [Ag(CN)2] for aR and [CN]2 for aP in Equation (I).

E=E00.0592nlog[CN]2[Ag(CN)2] ...... (III)

The number of electrons for half cell reaction is 1 and the activity of the product is 1M.

Substitute 0.0035M for [CN], 0.0550M for [Ag(CN)2], 1 for n, and 0.31V for E0 in Equation (III).

E=(0.31V)(0.0592V1)log((0.0035M)20.0550M)=(0.31V)(0.0592V)(3.652)=(0.31V)+0.2162V=0.093V

Interpretation Introduction

(c)

Interpretation:

The potential of a silver electrode in contact with solution, which is mixture of 25.0mL of 0.0500MKBr and 20.0mL of 0.100MAg+ should be determined.

Concept introduction:

The electrode potential of the cell is the difference of potential difference of two electrodes. Here, the electrode potential of the cell is potential difference of electrode and solution.

Expert Solution
Check Mark

Answer to Problem 22.5QAP

The potential of a silver electrode in contact with solution, which is mixture of 25.0mL of 0.0500MKBr and 20.0mL of 0.100MAg+ is 0.695V.

Explanation of Solution

The concentration in KBr is 0.0500M, the volume of KBr is 25.0mL, the volume of Ag+ is 20.0mL, and concentration in Ag+ is 0.100M.

The expression for the concentration in KBr is:

MKBr=nBrVKBr ...... (II)

Here, the solution volume of KBr is VKBr, and the number of moles of Br is nBr.

The expression for the concentration in Ag+ is:

MAg+=nAg+VAg+ ...... (III)

Here, the solution volume of Ag+ is VAg+, and the number of moles of Ag+ is nAg+.

The expression for the total number of moles in after the reaction is:

nT=nAg+nBr ...... (IV)

The expression for the total volume is:

VT=VKBr+VAg+ ...... (V)

The expression for the concentration of [Ag+] is:

MAg+=nTVT ...... (VI)

Substitute [Ag+] for aR and 1M for aP in Equation (I).

E=E00.0592nlog1M[Ag+] ...... (VII)

The number of electrons for half cell reaction is 1 and the activity of the product is 1M.

The initial electrode potential of this reaction is 0.799V.

Substitute 0.0500M for MKBr and 25.0mL for VKBr in Equation (II).

0.0500M=nBr25.0mLnBr=(0.0500M)(1mol/L1M)(25.0mL)(103L1mL)nBr=(0.0500mol/L)(25.0×103L)nBr=1.25×103mol

Substitute 20.0mL for VAg+ and 0.100M for MAg+ in Equation (III).

0.100M=nAg+20.0mLnAg+=(0.100M)(1mol/L1M)(20.0mL)(103L1mL)nAg+=2×103mol

Substitute 2×103mol for nAg+ and 1.25×103mol for nBr in Equation (IV).

nT=2×103mol1.25×103mol=0.75×103mol

Substitute 25.0mL for VKBr and 20.0mL for VAg+ in Equation (V).

VT=25.0mL+20.0mL=45.0mL

Substitute 0.65×103mol for nT for 45.0mL for VT in Equation (VI).

MAg+=0.75×103mol(45.0mL)(103L1mL)=(0.017mol/L)(1M1mol/L)=0.017M

Substitute 0.017M for [Ag+], 1M for

1 for n, and 0.799V for E0 in Equation (VII).

E=(0.799V)(0.0592V1)log(1M0.017M)=(0.799V)(0.0592V)(1.77)=(0.799V)0.104V=0.695V

Interpretation Introduction

(d)

Interpretation:

The potential of a silver electrode in contact with solution, which is mixture of 25.0mL of 0.0500MAg+ and 20.0mL of 0.100MKBr should be determined.

Concept introduction:

The electrode potential of the cell is the difference of potential difference of two electrodes. Here, the electrode potential of the cell is potential difference of electrode and solution.

Expert Solution
Check Mark

Answer to Problem 22.5QAP

The potential of a silver electrode in contact with solution, which is mixture of 25.0mL of 0.0500MAg+ and 20.0mL of 0.100MKBr is 0.182V.

Explanation of Solution

The concentration in Ag+ is 0.0500M, the volume of Ag+ is 25.0mL, the volume of KBr is 20.0mL, and concentration in KBr is 0.100M.

The expression for the total number of moles in after the reaction is:

nT=nBrnAg+ ...... (VIII)

The expression for the concentration of [Br] is:

MBr=nTVT ...... (IX)

Substitute [Br] for aR and 1M for aP in Equation (I).

E=E00.0592nlog1M[Br] ...... (VII)

The number of electrons for half cell reaction is 1 and the activity of the product is 1M.

The initial electrode potential of this reaction is 0.799V.

Substitute 0.100M for MKBr and 20.0mL for VKBr in Equation (II).

0.100M=nBr20.0mLnBr=(0.100M)(1mol/L1M)(20.0mL)(103L1mL)nBr=(0.100mol/L)(20.0×103L)nBr=2×103mol

Substitute 25.0mL for VAg+ and 0.0500M for MAg+ in Equation (III).

0.0500M=nAg+25.0mLnAg+=(0.0500M)(1mol/L1M)(25.0mL)(103L1mL)nAg+=1.25×103mol

Substitute 1.25×103mol for nAg+ and 2×103mol for nBr in Equation (VIII).

nT=1.25×103mol2×103mol=0.75×103mol

Substitute 20.0mL for VKBr and 25.0mL for VAg+ in Equation (V).

VT=20.0mL+25.0mL=45.0mL

Substitute 0.65×103mol for nT for 45.0mL for VT in Equation (VI).

MBr=0.65×103mol(45.0mL)=0.65×103mol(45.0mL)(103L1mL)=(0.014mol/L)(1M1mol/L)=0.014M

Substitute 0.014M for [Br], 1 for n, and 0.073V for E0 in Equation (VII).

E=(0.073V)(0.0592V1)log(0.014M1M)=(0.073V)(0.0592V)(1.853)=(0.073V)+0.1097V=0.182V

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