According to the reductions potentials in the table below, which statements is true under standard conditions?
`{:("Reaction", E^(@)V), (L^(2+) + 2e^(-) rightarrow L, -0.13), (M^(2+) + 2e^(-) rightarrow M, -0.44),(N^(2+) + 2e^(-) rightarrow N, -0.76):}`

What is the E^(@) value for the voltaic cell constructed from the half-cells? {: ("Reaction", E^(@)(V)), (Zn^(2+) + 2e^(-) rightarrow Zn,-0.762), (Tl^(+) + 3e^(-) rightarrow Tl, -0.036):}

Given the standard reduction potentials, which statement is correct? {:(Cu^(2)(aq) + 2e^(-) rightarrow Cu(s), E^(@) = 0.34V), (2H^(+)(aq) + 2e^(-) rightarrow H_(2)(g), E^(@)= 0.0V), (Cr^(3+)(aq) + 2e^(-) rightarrow Cr(s),E^(@) = -0.73V):}

What is the standard cell potential for the voltaic cell? Cr || Cr^(3+) || Pb^(2+)|| Pb {: ("Reaction", E_(red)^(@)//V), (Pb^(2+) + 2e^(-) rightarrow Pb, -0.13), (Cr^(3+) + 3e^(-) rightarow Cr, -0.74):}

Nickel metal is added to a solution containign 1.0 m Pb^(2+)(aq) and 1.0 M Cd^(2+)(aq) . Use the standard reduction potentials to determine which reaction(s) will occur. Reaction 1: Ni(s) + Pb^(2+)(aq) rightarrow Pb(s) + Ni^(2+)(aq) Reaction 2: Ni(s) + Cd^(2+)(aq) rightarrow Cd(s) + Ni^(2+)(aq) {:("Reaction", E^(@)), (Pb^(2+)(aq) + e^(-) rightarrow Pb(s) , -0.13V), (Ni^(2+)(aq) + 2e^(-) rightarrow Ni(s), -0.23V), (Cd^(2+)(aq) + 2e^(-) rightarrow Cd(s), -0.40V):}

Which expression gives the correct value of the standard potential for a gold-rhodium voltaic cell? {:("Half-reaction",E^(@)V), (Rh^(3+)(aq) +_ 3e^(-) rightarrow Rh(s), 0.76), (Au^(+)(aq) + e^(-) rightarrow Au(s), 1.69):}

Given these standard reduction potentials, what is the standard reduction potential for Co^(3+)(aq) + 3e^(-) rightarrow Co(s) ? Co^(3+)(aq) + e^(-) rightarrow Co^(2+)(aq) E^(@) = 1.82V Co^(2+)(aq) + 2e^(-) rightarrow Co(s) E^(@) = -0.28V

Using the standard potential values given below, decide which of the statements P,Q,R,S are correct? Choose the right answer from (a), (b), (c ) and (d). Fe^(2+) + 2e^(-) rightarrow Fe , E^(@) = -0.44V Cu^(2+) + 2e^(-) rightarrow Cu , E^(@) = +0.34V Ag^(+) + e^(-) rightarrow Ag , E^(@) = +0.80V (P) Copper can displace iron from FeSO_(4) solution (Q) Iron can displace copper from CuSO_(4) solution (S) Iron can displace silver from AgNO_(3) solution

Use the information in the table and calcualate E^(@) for this reaction. Ga(s) + 3Tl^(+)(aq) rightarrow 3Tl(s) + Ga^(3+) (aq) {: ("Reaction", E^(@)), (Ga^(3+)(aq) + 3e^(-) rightarrow Ga(s), -0.529V), (Tl^(+)(aq) + e^(-) rightarrow Tl(s), -0.336V):}

Which of the half reactions, when coupled, will make a galvanic cell that will produce the largest voltage under standard conditons? P. Cu^(2+)(aq) + 2e^(-) rightarrow Cu(s) E^(@) = +0.34V Q. Pb^(2+)(aq) + 2e^(-) rightarrow Pb(s) E^(@) = -0.13V R. Ag^(+)(aq) + 3e^(-) rightarrow Al(s) E^(@) = -1.66V

Given these standards reduction potentials, what is the free energy change (in kJ. Mol^(-) for the reaction: Pb(s) + 2Ag^(+)(aq) rightarrow Pb^(2+)(aq) + 2Ag(s) Ag^(+)(aq) + e^(-) rightarrow Ag(s) E^(@) = 0.80V Pb^(2+)(aq) + 2e^(-) rightarrow Pb(s) E^(@) = -0.13V