Electrode potential of the half Pt(s)|Hg(l)|`Hg_(2)Cl_(2)(s)`|`Cl^(-)(aq)` can be incresed by :

Calculate single electrode potential of Pt, Cl_(2)//Cl^(-) (0.01)(E^(@)= +1.36V)

Standard electrode potential (E^(0)) for OCl^(-) // Cl^(-) and Cl^(-)// (1)/(2) Cl_2 are respectively 0.94 V and -1.36 V . The E^(@) value of OCl^(-) //Cl_2 will be

E_(1//2Cl_(2)|Cl^(-))^(@)= + 1.36V . The single electrode potential of Pt, Cl_(2)(1 "atm") |Cl^(-)(0.1M) is

Given the following standard electrode potentials , PbBr_2(s) + 2e^(-) to Pb(s) + 2Br^(-) (aq) , E^@ - 0.248 V Pb^(2+)(aq) + 2e^(-) to Pb(s) , E^(@) - 0.126 V . If the K_(sp) for PbBr_2 is 7.4 xx 10^(-x) , x is

E^(@) Values of the half cells Mg^(2+)//Mg and Cl_(2)//Cl^(-) are respectively -2.36V and +1.36 V. The E^(@) vlaue of the cell Mg//Mg^(2+)// // Cl_(2)//Cl^(-) is

Calculate electrode potential of Zn^(2+)(0.1M)//Zn"||"Cl^(-)(0.01)//Cl_(2), Pt E^(@)Zn^(2+)//Zn = -0.762V , E^(@) 1/2 Cl_(2)//Cl^(-) = + 1.36V

At 25^@C potential of the cell, Pt, H_2(g), HCl (aq)"//"AgCl(s), Ag(s) is 0.22 V. If E^@ of silver electrode is 0.8 V , calculate the solubility of AgCI in water .

The potential of the cell Cu, Cu^(2+) (0.1M)"//"HCl (xM), Cl_(2), Pt is 1.07 V. If the standard potential of copper and chlorine electrodes are 10.34 V and 1.36 V, calculate the concentration of HCI.