The speed of sound in hydrogen at `0^@C` is `1280 m s^(-1)`. The density of hydrogen at STP is `0.089 kg m^(-3)`. Calculate the molar heat capacities `(C_p and C_v)` of hydrogen.

An ideal gas having density 1.7 xx 10^(-3) g cm ^(-3) at a pressure 1.5 xx 10^(5)Pa is filled in Kundt tube. When the gas is resonated at a frequency of 3.0 KHz , nodes are formed at a separation of 6.0 cm . Calculate the molar heat capacites (C_p and C_v) of the gas.

Standing waves of frequency 5.0 kHz are produced in a tube filled with oxygen at 300K . The separation between the consecutive nodes is 3.3 cm . Calculate the specific heat capacities (C_p and C_v) of the gas.

Calculate the speed of sound in oxygen from the following data. The mass of 22.4 litre of oxygen at STP (T = 273 K and p = 1.0 xx 10^5N m^-2) is 32 g, the molar heat capacity of oxygen at constant volume is C_V= 2.5 R and that at constant pressure is C_p = 3.5 R.

The density of carbon dioxide is equal to 1.965 kg m^(-3) at 273 K and 1 atm pressure. Calculate the molar mass of CO_(2) .

An experiment is performed to measure the molar heat capacity of a gas at constant pressure using Regnault's method. The gas is initially contained in a cubical reservoir of size 40 cm xx 40 cm xx 40 cm xx at 600 kPa at 27^0C . A part of the gas is brought out, heated to 100^0C and is passed through a calorimeter at constant pressure. The water equivalent of the calorimeter and its contents increases from 20^0C to 30^0C during the experiment and the pressure in the reservoir decresases to 525 kPa . Specific heat capacity of water = 4200 J kg^(-1) K^(1). Calculate the molar heat capacity Cp from these data.

The density of water at 4^0C is supposed to be 1000 kg m^(-3) . It is same at the sea level and at a high altitude?

Find the speed of sound in air at 23^(@)C . (consider the speed of sound in air at 0^(@)C is 331.3ms^(-1) ).