Pacemakers are electronic devices that help regulate the heart rate. Currently, lithium-iodine cells are commonly used to power pacemakers and have replaced zinc-mercury cells. Table 1 provides the operating cell potential, E, for each cell. Table 2 provides the standard reduction potentials for several half-reactions related to zinc-mercury and zinc-air cells. The use of zinc-mercury cells in hearing aids has been replaced by zinc-air cells that operate using the oxidation of Zn by O2 from the air, generating a potential of +1.60 V. Table 2 provides the standard reduction potentials for the half-reactions used in zinc-mercury and zinc-air cells. Which of the following best explains the modification to the cell design that is mostly responsible for the difference in standard cell potentials for zinc-mercury and zinc-air cells? The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the thermodynamically more favorable reduction of Oz compared to A HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the greater number of moles of e required to reduce Oz compared to B HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the thermodynamically less favorable reduction of Oz compared to HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the greater number of moles of hydroxide ions required to reduce D Zn(OH), compared to Zn(OH),-

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CollegeBoard AP Classroom Unit 9 Progress Check: MCQ Ebraam Awad 11 12 13 27 « < 2 of 30 Zinc-mercury +1.35 Table 2 Half-Reaction Standard Reduction Potential, E (V) [Zn(OH),J- + 2 e Zn + 4 OH Zn(OH), + 2e- → Zn + 2 OH -1.20 -1.25 Hgo + H20 + 2 e → Hg + 2OH +0.10 O2 + 2 H20 + 4e 4 OH +0.40 Pacemakers are electronic devices that help regulate the heart rate. Currently, lithium-iodine cells are commonly used to power pacemakers and have replaced zinc-mercury cells. Table 1 provides the operating cell potential, E, for each cell. Table 2 provides the standard reduction potentials for several half-reactions related to zinc-mercury and zinc-air cells. The use of zinc-mercury cells in hearing aids has been replaced by zinc-air cells that operate using the oxidation of Zn by O2 from the air, generating a potential of +1.60 V. Table 2 provides the standard reduction potentials for the half-reactions used in zinc-mercury and zinc- cell potentials for zinc-mercury and zinc-air cells? cells. Which of the following best explains the modification to the cell design that is mostly responsible for the difference in standard The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the thermodynamically more favorable reduction of O2 compared to A HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the greater number of moles of e required to reduce Oz compared to B HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the thermodynamically less favorable reduction of O, compared to HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the greater number of moles of hydroxide ions required to reduce D Zn(OH),- compared to Zn(OH),- Q Search or enter website name

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A apclassroom.collegeboard.org CollegeBoard AP Classroom Unit 9 Progress Check: MCQ Ebraam Awad 9 12 13 14 (16 21 « < 2 of 30 > >»> Table 1 Cell Type Operating Cell Potential for Commercial Batteries, E (V) Lithium-iodine +2.80 Zinc-mercury +1.35 Table 2 Submit Half-Reaction Standard Reduction Potential, E (V) [Zn(OH),- + 2 e Zn + 4 OH -1.20 Zn(OH), + 2e- + Zn + 2 OH HgO + H20 + 2 e Hg + 2OH -1.25 +0.10 O2 + 2 H2O + 4 e +4 OH +0.40 Pacemakers are electronic devices that help regulate the heart rate. Currently, lithium-iodine cells are commonly used to power pacemakers and have replaced zinc-mercury cells. Table 1 provides the operating cell potential, E, for each cell. Table 2 provides the standard reduction potentials for several half-reactions related to zinc-mercury and zinc-air cells. The use of zinc-mercury cells in hearing aids has been replaced by zinc-air cells that operate using the oxidation of Zn by Oz from the air, generating a potential of +1.60 V. Table 2 provides the standard reduction potentials for the half-reactions used in zinc-mercury and zinc-air cells. Which of the following best explains the modification to the cell design that is mostly responsible for the difference in standard cell potentials for zinc-mercury and zinc-air cells? The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the thermodynamically more favorable reduction of O, compared to HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the greater number of moles of e required to reduce O, compared to B HgO. The greater standard cell potential of the Zn-air cell compared to that of the zinc-mercury cell most likely results from the thermodynamically less favorable reduction of O, compared to