For hydrogen gas electrode `E_(H2)` is calculated through to Nernst equation, where `E_(H2)^0` is always

A hydrogen electrode is prepared by using a sample of HCl solution with pH=4 and H_(2) gas at 1 atm pressure. What is the electrode potential of the electrode?

Calculating the cell emf for Nonstandard condition : A galvanic cell is constructed at 298 K as follows. One half-cell consists of a chlorine gas electrode (i.e. Cl_(2)//Cl^(-) couple) with the partial pressure of Cl_(2) = 0.100 bar and C_(CI-) = 0.100 M . The other half-cell involves the MnO_(4)^(-)//Mn^(2+) couple in acidic solution with C_(MnO_(4)^(-)) = 0.100 M, C_(Mn^(2+)) = 0.100 M , and C_(H+) = 1.00 M . Apply the Nernst equation to datermine the cell potenital for this cell. Strategy: First datermine the overall cell reaction and then calculate the standard cell potential (E_("cell")^(@)) from the standard electrode potenital in Table 3.1. then use the Nernst equation to find the cell potential (E) under cited conditions.

Planck's constant (h) and de Broglie wavelength (lambda) are related through the equation h=lambdasqrt(2mE) , where 'm' and 'E' denote the mass and kinetic energy respectively of the moving particle. The dimensional formula of h is given by

At what pH of HCl solution, will hydrogen gas electrode show electrode potential of -0.118 V ? H_(2) gas is bubbled at 298 K and 1 atm pressure.

A hydrogen electrode X was placed in a buffer solution of sodium acetate ad acetic acid in the ratio a:b and another hydrogen electrode Y was placed in a buffer solution of sodium acetate ad acetic in the ratio b:a if reduction potential values for two cells are found to be E_(1) and E_(2) respectively w.r.t. standard hydrogen electrode, the pK_(a) value of the acid can be given as (A) (E_(1)-E_(2))/(0.118) (B). -(E_(1)+E_(2))/(0.118) (C). (E_(1))/(E_(2))xx0.118 (D). (E_(2)-E_(1))/(0.118)

The quinhydrone electrode (Q,H^(o+)|H^(2)Q) is used in conjunction with a saturated calomel electrode, as represented below : EMF_(cell)=0.264V at 30^(@)C . Calculate the pH of unknown solution at this temperature. Given :E_(calomel)=0.24V and E^(c-)._(2H^(o+),Q|H_(2)Q)=0.7V

Given below are a set of half-cell reactions (acidic medium) along with their E_(@) with respect to normal hydrogen electrode values. Using the data obtain the correct explanation to question given below. {:(I_(2)+2e^(-)rarr2I^(-),E^(@)=0.54),(Cl_(2)+2e^(-)rarr2Cl^(-),E^(@)=1.36),(Mn^(2+)+e^(-)rarrMn^(2+),E^(@)=1.50),(Fe^(3+)+e^(-)rarrFe^(2+),E^(@)=0.77),(O_(2)+4H^(+)+4e^(-)rarr2H_(2)O,E^(@)=1.23):} While Fe^(2+) is stable, Mn^(3+) is not stable in acid solution because:

Given below are a set of half-cell reactions (acidic medium) along with their E_(@) with respect to normal hydrogen electrode values. Using the data obtain the correct explanation to question given below. {:(I_(2)+2e^(-)rarr2I^(-),E^(@)=0.54),(Cl_(2)+2e^(-)rarr2Cl^(-),E^(@)=1.36),(Mn^(2+)+e^(-)rarrMn^(2+),E^(@)=1.50),(Fe^(3+)+e^(-)rarrFe^(2+),E^(@)=0.77),(O_(2)+4H^(+)+4e^(-)rarr2H_(2)O,E^(@)=1.23):} Among the following, identify the correct statement: