The density `("in" g mL^(-1))` of a `3.60 M` sulphuric acid solution that is `29% H_(2)SO_(4)` (Molar mass `=98 g mol^(-1)`) by mass will be:

Calculate the molality of a sulphuric acid solution of specific gravity 1.2 containing 27% H_(2)SO_(4) by weight.

If 250 mL of a solution contains 24.5 g H_(2)SO_(4) the molarity and normality respectively are:

30mL of CH_(3)OH (d = 0.780 g cm^(-3)) and 70 mL of H_(2)O (d = 0.9984 g cm^(-3)) are mixed at 25^(@)C to form a solution of density 0.9575 g cm^(-3) . Calculate the freezing point of the solution. K_(f)(H_(2)O) is 1.86 kg mol^(-1)K . Also calculate its molarity.

The weight of solute present in 200mL of 0.1M H_(2)SO_(4) :

During the discharge of a lead storage battery, the density of sulphuric acid fell from 1.294 g mL^(-1) to 1.139 g mL^(-) . Sulphuric acid of density 1.294 g mL^(-1) is 39% by weight and that of density 1.139 g mL^(-1) is 20% by weight. The battery hold 3.5 litre of acid and discharge. Calculate the no. of ampere hour for which the battery must have been used. The charging and discharging reactions are: Pb+SO_(4)^(2-) rarr PbSO_(4)+2e (charging) PbO_(2)+4H^(+)+SO_(4)^(2-)+2e rarr PbSO_(4)+2H_(2)O (discharging)

A 5.25% solution of a substance is isotonic with a 1.5% solution of urea (molar mass = 60g mol^(-1) ) in the same solvent. If the densities of both the solutions are assumed to be equal to 1.0 g cm^(-3) , molar mass of the substance will be:

Molarity of H_(2)SO_(4) is 18 M . Its density is 1.8 g//cm^(3) , hence molality is :