The standard reduction potential of `Ag^(+)//Ag` electrode at 298 K is 0.799 V and `K_(sp)` (Agl) is `8.7 xx10^(-17)` Evaluate the potential of `Ag^(+)//Ag` electrode in saturaded solution of Agl . Also calculate the standard reductin potential of `I^(-)Agl//Ag`

The standard reduction potential of the Ag^(o+)|Ag electrode at 298K is 0.799V . Given that for AgI,K_(sp)=8.7xx10^(-17) , evaluate the potential of the Ag^(o+)|Ag electrode in a saturated solution of AgI . Also calculate the standard reduction potential of the I^(c-) |Agl|Ag electrode.

The standard reduction potential of the Ag^(o+)|Ag electrode at 298K is 0.799V . Given that for AgI,K_(sp)=8.7xx10^(-17) , evaluate the potential of the Ag^(o+)|Ag electrode in a saturated solution of AgI .

Standard electrode potential of SHE at 298 K is :

The standard reduction potential at 298 K for single electrodes are given below.l From this we can tell that

Calculate the potential of silver electrode in a saturated solution of AgBr(K_(sp)=6xx10^(-13)) containing 0.1 M KB r . E^(c-)._(Ag^(o+)|Ag)=0.80V.

The standard reduction potentials of magnesium and iron electrodes are -2.73 V and -0.44 V respectively. Which electrode will undergo oxidation and which electrode reduction ?

The standard half-cell reduction potential for Ag+|Ag is 0.7991 V at 25^(@)C . Given the experimental value K_(sp) =1.56xx10^(-10) for AgCl, calculate the standard half-cell reduction potential for the AglAgCI electrode.

The standard electrode potential a Ag^(+)//Ag is +0.80 V and of Cu^(2+)//Cu is +0.34 V. These electrodes are connected through a salt bridge and if :

If K_(SP) of Ag_(2)S is 10^(-17) , the solubility of Ag_(2) S in 0.1 M solution of Na_(2)S will be :

The standard reduction potential of zinc and silver at 298 K are E_((Zn^(2+)) /(Zn))^0 = -0.76 V , E_((Ag^(+))/(Ag))^0= 0.80V Which of the following reactions actually takes place in a cell reaction?