Redox Reactions MCQs With Answers – Part 5 (Class 11 Chemistry)
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Redox Reactions MCQs with Answers – Part 5 (Class 11 Chemistry)

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401. A cell is made from \( \mathrm{M^{2+}/M} \) and the standard hydrogen electrode. If \(E^\circ_{\mathrm{M^{2+}/M}}=-0.40\,\mathrm{V}\), the reaction \( \mathrm{M+2H^+\rightarrow M^{2+}+H_2} \) has:
ⓐ. \(E^\circ_{\text{cell}}=+0.40\,\mathrm{V}\)
ⓑ. \(E^\circ_{\text{cell}}=-0.40\,\mathrm{V}\)
ⓒ. \(E^\circ_{\text{cell}}=+0.80\,\mathrm{V}\)
ⓓ. \(E^\circ_{\text{cell}}=0.00\,\mathrm{V}\)
402. A metal \( \mathrm{N} \) does not liberate \( \mathrm{H_2} \) from dilute acid under standard comparison, and \(E^\circ_{\mathrm{N^{2+}/N}}=+0.20\,\mathrm{V}\). The best explanation is:
ⓐ. \( \mathrm{N} \) has no electrons
ⓑ. hydrogen electrode has no redox half-reaction
ⓒ. positive reduction potential always means a metal dissolves in acid
ⓓ. \( \mathrm{N^{2+}} \) is easier to reduce than \( \mathrm{H^+} \)
403. A table lists half-cell data.
Half-cell\(E^\circ\)
\( \mathrm{A^{2+}+2e^-\rightarrow A} \)\(-1.00\,\mathrm{V}\)
\( \mathrm{B^{2+}+2e^-\rightarrow B} \)\(-0.20\,\mathrm{V}\)
\( \mathrm{C^{2+}+2e^-\rightarrow C} \)\(+0.60\,\mathrm{V}\)
The strongest reducing metal and strongest oxidising ion are respectively:
ⓐ. \( \mathrm{C} \) and \( \mathrm{A^{2+}} \)
ⓑ. \( \mathrm{A} \) and \( \mathrm{C^{2+}} \)
ⓒ. \( \mathrm{B} \) and \( \mathrm{B^{2+}} \)
ⓓ. \( \mathrm{A^{2+}} \) and \( \mathrm{C} \)
404. According to the data in the table, the standard reaction expected to have the largest positive cell potential is:
ⓐ. \( \mathrm{C+A^{2+}\rightarrow C^{2+}+A} \)
ⓑ. \( \mathrm{A+C^{2+}\rightarrow A^{2+}+C} \)
ⓒ. \( \mathrm{B+A^{2+}\rightarrow B^{2+}+A} \)
ⓓ. \( \mathrm{C+B^{2+}\rightarrow C^{2+}+B} \)
405. A proposed galvanic cell has \(E^\circ_{\text{cell}}=0.00\,\mathrm{V}\) under standard conditions. The safest interpretation is:
ⓐ. no net standard driving force in the written direction
ⓑ. the equation must contain no atoms
ⓒ. oxidation and reduction cannot be written as half-reactions
ⓓ. the cell potential must be multiplied by coefficients to become positive
406. A reaction has \(E^\circ_{\text{cell}}=+0.50\,\mathrm{V}\). If the reaction is reversed, the standard cell potential becomes:
ⓐ. \(+0.50\,\mathrm{V}\)
ⓑ. \(+1.00\,\mathrm{V}\)
ⓒ. \(0.00\,\mathrm{V}\)
ⓓ. \(-0.50\,\mathrm{V}\)
407. A graph plots standard reduction potential on the y-axis for \( \mathrm{A^{2+}/A} \), \( \mathrm{B^{2+}/B} \), and \( \mathrm{C^{2+}/C} \). The points are at \(-0.90\,\mathrm{V}\), \(+0.10\,\mathrm{V}\), and \(+0.80\,\mathrm{V}\), respectively. The pair giving the greatest \(E^\circ_{\text{cell}}\) is:
ⓐ. \( \mathrm{C/C^{2+}} \) as anode and \( \mathrm{A^{2+}/A} \) as cathode
ⓑ. \( \mathrm{A/A^{2+}} \) as anode and \( \mathrm{C^{2+}/C} \) as cathode
ⓒ. \( \mathrm{B/B^{2+}} \) as anode and \( \mathrm{A^{2+}/A} \) as cathode
ⓓ. \( \mathrm{C/C^{2+}} \) as anode and \( \mathrm{B^{2+}/B} \) as cathode
408. A student sees \(E^\circ_{\mathrm{Al^{3+}/Al}}=-1.66\,\mathrm{V}\) and says aluminium ion is the strongest oxidising agent because the magnitude is large. The best correction is:
ⓐ. \( \mathrm{Al^{3+}} \) is hard to reduce; \( \mathrm{Al} \) is reductant
ⓑ. negative \(E^\circ\) makes \( \mathrm{Al^{3+}} \) the strongest oxidising agent
ⓒ. magnitude alone decides oxidising strength without sign
ⓓ. aluminium cannot take part in redox reactions
409. When a standard reduction-potential table is used to predict displacement reactions, a metal \( \mathrm{M} \) can reduce \( \mathrm{N^{2+}} \) if:
ⓐ. \(E^\circ_{\mathrm{M^{2+}/M}}\) is greater than \(E^\circ_{\mathrm{N^{2+}/N}}\)
ⓑ. both reduction potentials are exactly equal
ⓒ. both ions have the same charge only
ⓓ. \(E^\circ_{\mathrm{N^{2+}/N}}\) is greater than \(E^\circ_{\mathrm{M^{2+}/M}}\)
410. Given \(E^\circ_{\mathrm{Pb^{2+}/Pb}}=-0.13\,\mathrm{V}\) and \(E^\circ_{\mathrm{Cu^{2+}/Cu}}=+0.34\,\mathrm{V}\), what happens when lead metal is placed in \( \mathrm{Cu^{2+}} \) solution under standard comparison?
ⓐ. \( \mathrm{Cu^{2+}} \) reduces \( \mathrm{Pb} \) to \( \mathrm{Pb^{2+}} \)
ⓑ. no redox direction can be compared from these values
ⓒ. \( \mathrm{Pb} \) reduces \( \mathrm{Cu^{2+}} \) to \( \mathrm{Cu} \)
ⓓ. \( \mathrm{Pb} \) must be reduced to \( \mathrm{Pb^{2+}} \)
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