500 mL 4 M of NaCl solution is electrolysed liberating `Cl_(2)(g)` at an electrode. Calculate (3) the amount of electricity required for complete electrolysis.

500 mL 4 M of NaCl solution is electrolysed liberating Cl_(2)(g) at an electrode. Calculate (1) the total number of moles of Cl_(2)

500 mL 4 M of NaCl solution is electrolysed liberating Cl_(2)(g) at an electrode. Calculate (2) the maximum amount of amalgam if Hg - cathode is used (atomic mass of Hg = 200 )

500 mL 4 (M) of NaCl solution is electrolysed liberating Cl_(2)(g) at an electrode. Calculate (i) the total number of moles of Cl_(2) (ii) the maximum amount of amalgam, if Hg- cathode is used. (Hg = 200) (iii) the amount of electricity required for complete electrolysis.

Calculate the amount of energy liberated due to combustion of 4g dihydrogen.

Aqueous solution of AgNO_(3) is electrolysed in presence of Ag electrodes. As result, 10.8 g of Ag (atomic mass = 108) is deposited at the cathode. If the same amount of electricity is used to carry out the electrolysis of an aqueous solution of CuSO_(4) in presence of Cu electrodes, then -

4.5 g Al is produced at the cathode during the electrolysis of molten Al_(2)O_(3) . If the same amount of electricity is passed through acidulated water, then at STP the volume of liberated oxygen at the anode would be -

20g of a metal reacts with dilute H_(2)SO_(4) to liberate 0.504g of H_(2) gas. Calculate the amount of metal oxide formed from 2.0g of the metal.

To one molar solution of a trivalent metal salt, electrolysis was carried out and 0.667 M was the concentration remaining after electrolysis. Calculate the quantity of electricity passed.

Electrolysis of aqueous solution of Ag_(2)SO_(4) is carried out by passing a certain amount of electricity in presence of platinum electrodes. As a result of this, 1.6g of O_(2) is produced at the anode. The amount of Ag (atomic mass = 108) deposited at the cathode is -