The cell `Pt(H_(2))(1atm) |H^(+) (pH =?) T^(-) (a=1)AgI(s), Ag` has emf, `E_(298KK) =0`. The electrode potential for the reaction `AgI +e^(-) rarr Ag + I^(Theta)` is `-0.151` volt. Calculate the `pH` value:-

For the cell Pt_((s)), H_(2) (1 atm)|H^(+) (pH=2)||H^(+) (pH=3)|H_(2) (1atm),Pt The cell reaction is

Pt(H_(2))(1atm)|H_(2)O , electrode potential at 298K is

Ag^(+) + e^(-) rarr Ag, E^(0) = + 0.8 V and Zn^(2+) + 2e^(-) rarr Zn, E^(0) = -076 V . Calculate the cell potential for the reaction, 2Ag + Zn^(2+) rarr Zn + 2Ag^(+)

Pt |{:((H_(2))),(1atm):}:| pH = 2:|:|:pH =3 |:{:((H_(2))Pt),(1atm):}:| . The cell reaction for the given cell is:-

The cell Pt|H_(2)(g) (1atm)|H^(+), pH = x || Normal calomal electrode has EMF of 0.64 volt at 25^(@)C . The standard reduction potential of normal calomal electrode is 0.28V . What is the pH of solution in anodic compartment. Take (2.303RT)/(F) = 0.06 at 298K .

The pK_(sp) of AgI is 16.07 if the E^(@) value for Ag^(+)//Ag is 0.7991V , find the E^(@) for the half cell reaction AgI(s) +e^(-) rarr Ag+I^(-)

The emf of the cell, Pt|H_(2)(1atm)|H^(+) (0.1M, 30mL)||Ag^(+) (0.8M)Ag is 0.9V . Calculate the emf when 40mL of 0.05M NaOH is added.

The oxidation potential of a hydrogen electrode at pH=10 and p_(H_(2))=1atm is

The emf of the cell involving the following reaction, 2Ag^(+) +H_(2) rarr 2Ag +2H^(+) is 0.80 volt. The standard oxidation potential of silver electrode is:-

For the half cell, +2H^(+)2e^(-).E^(0)= 1.30 V. At pH = 2 , electrode potential of the given quinhydrone half cell is :