When you compare a cup of water at `100^@C` and a bucket of water at `100^@C`, you observe that …….

compared to burn due to air at 100^(@) a burn due to steam at 100^(@)C is

When you make ice cubes, the entropy of water

What is the free energy change, 'DeltaG' When 1.0 mole of water at 100^(@)C and 1 atm pressure is converted into steam at 100^(@)C and 1 atm pressure

At 100^@C , K_w =10^(-12) . PH of pure water at 100^@C will be

The degree of dissociation of Ca(NO_(3))_(2) in a dilute aqueous solution, containing 7.0 g of the salt per 100 g of water at 100^(@)C is 70% . If the vapour pressure of water at 100^(@)C is 760 mm , calculate the vapour pressure of the solution.

A bucket contains 8 kg of water at 25^@ C. 2 kg of water at 80^@ C is poured into it. Neglecting the heat energy absorbed by the bucket, calculate the final temperature of water.

If there is no heat loss, the heat released by the condensation of x gram of steam at 100^@C into water at 100^@C can be used to convert y gram of ice at 0^@C into water at 100^@C . Then the ratio of y:x is nearly [Given L_l = 80 cal//gm and L_v= 540 cal//gm ]

How much work is done on the steam when 1.00 mol of water at 100^(@)C boils and becomes 1.00 mole of steam at 100^(@)C at 1.00 atm pressure? Assume the steam to behave as an ideal gas , determine the change in the internal energy of the material as it vapourizes.

The boiling point of a glucose solution containing 12 g of glucose in 100 g of water is 100.34^@C . Boiling point of water is 100^@C . The molal elevation constant of water is

1gm water at 100^(@)C is heated to convert into steam at 100^(@)C at 1atm . Find out chage in internal energy of water. It is given that volume of 1gm water at 100^(@)C = 1c c , volume of 1gm steam at 100^(@)C = 167 1 c c . Latent heat of vaporization = 540 cal//g . (Mechanical equivalent of heat J = 4.2J//cal)