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

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

Calculate the Electrode potential of single electrode. Cu^(2+)(0.01M)//Cu" "(E^(@)= +0.337V)

The EMI of the cell Pt, H_(2)(2 atm) |HCl (1M)|H_2(10 atm),Pt is xV and of Pt, Cl_(2)(2 atm)|HCl (1M)|Cl_2(10 atm),Pt is yV . How are x and y related?

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

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.

The oxidation number of Pt in [Pt(C_2H_4)Cl_3]^(-) is

E^(@) values of Ni^(2+) , Ni and Cl_(2), Cl^(-) are respectively -0.25V and +1.37V . Calculate the EMF of the cell Ni, Ni^(2+) (0.01M)//Cl^(-)(0.1M), Cl_(2) , pt. Potential of nickel electrode is given as,

Oxidising power of chlorine in aqueous solution can be determined by the parameters indicated below : 1/2Cl_(2(g))overset(1/2Delta_(diss)H^(odot))(rarr) Cl_(g)overset(Delta_(cg)H^(odot))(rarr)Cl_((g))^(-) overset(Delta_(hyd)H^(odot))(rarr)Cl^(-)_(aq) The energy involved in the conversion of 1/2Cl_(2(g)) to Cl_((aq))^(-) (using the data, Delta_(diss)H_(CL_(2))^(odot)=240" "KJ" "mol^(-1), Delta_(eg)H_(Cl)^(odot)=-349 KJ" "mol^(-1) , Delta_(hyd)H_(Cl^(-))^(odot)=-381KJ" "mol^(-1) ) will be

Under certain conditions, the equilibrium constant for the decomposition of PCl_(5)(g) into PCl_(3)(g) and Cl_(2)(g) is 0.0211 "mol"L^(-1) . What are the equilibrium concentrations of PCl_(5),PCl_(3)d and Cl_(2) if the initial concentration of PCl_(5) was 1.00 M ?