Write down 2302 m , 0.0034 m and 2.001 in the scientific way.

Four solutions of K_(2)SO_(4) with the concentrations 0.1m, 0.01m ,0.001 m, and 0.0001 m are available . The maximum value of colligative property corresponds to :

We have three aqueous solutions of NaCl labelled as A, B and C with concentration 0.1 M , 0.01 "and" 0.001 M , respectively . The value of van't Hoff factor for these solutions will be in the order :

We have three aqueous solutions of NaCl labelled as A, B and C with concentration 0.1 M , 0.01 "and" 0.001 M , respectively . The value of van't Hoff factor for these solutions will be in the order :

3.5 litre of 0.01 M NaCl is mixed with 1.5 litre of 0.05 M NaCl . What is the concentration of the final solution?

The mass and sides of cube are given as (10 kg +-0.1) and (0.1m+-0.01) the fractional density is

Arrange the following solutions as: Increasing order of boiling points- 0.001 m NaCl , 0.001 m urea 0.001 m MgCl_(2) , 0.001 m CH_(3)COOH

If L_1 = 2.02 m pm 0.01 m , L_2 = 1.02 m pm 0.01 m , determine L_1 + 2L_2

Equilibrium concentrations of A and B involved in following equilibrium are 0.01 M and 0.02 M respectively: [A(g)hArr B(g)] If 0.01 M of A is added at equilibrium, then at new equilibrium concentration of B will be

Properties such as boiling point, freezing point, and vapour pressure of a pure solvent change when solute molecules are added to get homogenous solution. These are called colligative properties. Anwer the following questions: i. 0.001 m NaCl ii.0.001 m urea iii. 0.001 m MgCl_(2) iv. 0.001 m CH_(3)COOH Increasing order of boiling points

A second order reaction requires 70 min to change the concentration of reactants form 0.08 M to 0.01 M . The time required to become 0.04 M = 2x min . Find the value of x .