A current of 3.7 A is passed for 6h between nickel electrodes in 0.5 L of a 2M solution of `Ni(NO_(3))_(2)`. What will be the molarity of solution at the end of electrolysis ?

A current of 1.70 A is passed through 300.0 mL of 0.160 M solution of ZnSO_(4) for 230s with a current efficiency of 90 per cent. Find out the molarity of Zn^(2+) after the deposition of zinc. Assume the volume of the solution to remain constant during electrolysis.

2.75 g of Na_2 CO_3 is present in 200 ml of Na_2CO_3 solution. Calculate the molarity of the solution.

A strip of nickel metal is dipped in a 1 molar solution of Ni (NO_(3))_(2) and a strip of silver metal is dipped in a 1 molar solution of AgNO_(3) . An electrochemical cell is created when the two solutions are joined by salt bridge and two strips are joined by wire to a voltmeter. Answer the following questions. Calculate the cell potential (E_("cell")) at 25^(@)C for the cell if the initial concentration of Ni (NO_(3))_(2) , is 0.100 molar and the initial concentration of AgNO_(3) is 1.00 molar. [E_(Ni^(2+)//Ni)= -0.25V, E_("Ag^(+)//Ag)=0.80V, log 10^(-1)= -1]

A strip of nickel metal is dipped in a 1 molar solution of Ni (NO_(3))_(2) and a strip of silver metal is dipped in a 1 molar solution of AgNO_(3) . An electrochemical cell is created when the two solutions are joined by salt bridge and two strips are joined by wire to a voltmeter. Answer the following questions. Write the balanced equation for the overall cell reaction and calculate the cell potential.

The reduction electrode potential E of 0.1 M solution of M^+ ions (E^o(rp) = -2.36V ) is :

Resistance of 0.2 M solution of an electrolyte is 50 Omega . The specific conductance of the solution is 1.3 S m^(-1) . If resistance of the 0.4 M solution of the same electrolyte is 260 Omega , its molar conductivity is