A compound `H_(2)X` with molar weight of 80 g is dissolved in solvent having density of `0.4 gm L^(-1)`. Assuming no change in volume upon dissolution, the molality of a 3.2 molar solution is :

A compound H_(2)X with molar weigth of 80g is dissolved in a solvent having density of 0.4 g mol^(-1) . Assuming no change in volume upon dissolution, the molarity of a 3.2 molar solution is

What is the molarity of 2.00 g of NaOH dissolved in a total solution volume of 250 mL?

3.0 molal NaOH solution has a density of 1.110 g//mL . The molarity of the solution is:

The pH of a solution of H_(2)SO_(4) is 1. Assuming complete ionisation, find the molarity of H_(2)SO_(4) solution :

The molality of 49% by volume of H_(2)SO_(4) solution having density 1.49 g/mL is……

A: For a given solution (density 1 gm//ml ), molality is greater than molarity. R: Molarity involves volume of solution while molality involves mass of solvent.

The molarity of 20% by mass H_(2)SO_(4) solution of density 1.02 g cm^(-3) is :

100 ml of 5 m H_2SO_4 of density 1 gm/ml is mixed with 100 ml of 8 m H_2SO_4 of density 1.25 g/mL. If there is no change in volume of resulting solution due to mixing, the molarity of the resulting mixture is -

Density of 12.25%(w/w) H_(2)SO_(4) solution is 1.0552 g/ml then molarity of solution is :-

Calculate the molality of 90% H_2SO_4 (weight/volume). The density of solution is 1.80 g mL^(-1) .