A silver electrode is immersed in saturated `Ag_(2)SO_(4(aq))`. The potential difference between the silver and the standard hydrogen electrode is found to be `0.711V` Determine `K_(SP)(AgSO_(4))`. Given `E_(Ag^(+)//Ag)^(@)=0799V`.

Calculate standard free energy change for the reaction 2Ag+2H^(+)rarrH_(2)+2Ag^(+) Given : E_(Ag^(+)//Ag)^(@)=+0.80V

An alloy of Pb-Ag weighing 54 mg was dissolved in desired amount of HNO_(3) & volume was made upto 500ml . An Ag electrode was dipped in solution and then connected to standard hydrogen electrode anode. Then calculate % of Ag in alloy. Given: E_(cell) = 0.5V, E_(Ag^(+)//Ag)^(@) = 0.8V (2.303RT)/(F) = 0.06

Calculate the standard potential of the cell ,If the standard electrode potentials of Zn^(2+)//Zn and Ag^(+) //Ag are -0.763 V and + 0.799 V respectively .

The potential associated. with each electrode is known as electrode potential. If the concentration of each species taking part in the electrode reaction is unity (if any gås appears in the electrode reaction, it is confined to 1 atmospheric pressure) and further the reaction is carried out at 298 K, then the potential of each electrode is said to be the standard electrode potential. By convention, the standard electrode potential of hydrogen electrode is 0:0 volt. The electrode potential value for each electrode process is a measure, of relative tendency of the active species in the process to remain in the oxidized / reduced form. A negative E^@ means that the redox couple is a stronger reducing agent than the H^(+)//H_2 couple. A positive E mears that the redox couple is a weaker reducing agent than. the H^(+)//H couple. The metal with greater positive value of standard reduction potentlal forms the oxide of greater thermal stability: Given the standard reduction potentials. E_(K^(+)//K)^(@)=-2.93V, E_(Ag^(+)//Ag)^(@)=+0.80V, E_(Hg^(+)//Hg)^(@)=0.79V E_(Mg^(+)//Mg)^(@)=-2.37V, E_(Cr^(3+)//Cr)^(@)=-0.74V The correct increasing order of reducing power is:

E^@ of zinc electrode is -0.762V . Calculate the single electrode potential of Zn electrode in decimolar ZnSO_4 solution.

An aqueous solution containing Na^(+),Sn^(2+),Cl^(-) & SO_(4)^(2-) ions, all at unit concentration is electrolysed between a silver anode and a platium cathode. What changes occur at the electrodes when curret is passed through the cell? Given E_(Ag^(+)|Ag)^(0)=0.799V , E_(Sn^(2+)|Cn)^(0)=-0.14V,E_(Cl_(2)|Cr^(-))^(0)=1.36V,E_(S_(2)O_(8)^(2-)|SO_(4)^(2-))=2V,E_(Sn^(4+)|Sn^(2+))^(0)=0.13V (A). Sn^(2+) is reduced and Cl^(-) is oxidized (B). Ag is oxidized and Sn^(2+) is reduced (C). Sn^(2+) is reduced and Sn^(2+) is oxidized (D). H^(+) is reduced and Sn^(2+) is oxidised

Using the standard electrode potentials given in the Table 8.2, predict if the reaction between the following is feasible: Ag^(+)(aq) and Cu(s)

At 25^(@)C , after the addition of 110mL of 0.1NaCI solution to 100mL of 0.1N AgNO_(3) solution, the reduction potentilal of a silver electrode placed in it is 0.36V . Calculate the K_(sp) of AgCI . (Given: E^(Θ) Ag//Ag^(o+) =- 0.799V) .

A copper-silver cell is set up. The copper ion concentration in it is 0.10 M. The concentration of silver ions is not known.The cell potential measured is 0.422 V. Determine the concentration of silver ions in the cell. [Given E_(Ag^(+)//Ag)^(@)=0.80,E_(Cu^(2+)//Cu)^(@)=+0.34 V]

Using the standard electrode potentials given in the Table 8.2, predict if the reaction between the following is feasible: Ag(s) and Fe^(3+)(aq)