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.

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.

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.

The ratio of C_p / C_v = gamma for a gas. It's molecular weight is M. It's specific heat capacity at constant volume is

In Joly's differential steam calorimeter, 3g of an ideal gas is ccontained in a rigid closed sphere at 20^@C . The sphere is heated by steam at 100^@C and it is found that an extra 0.095 g of steam has condensed into water as the temperature of the gas becomes constant. Calculate the specific heat capacity of the gas in (Jg^(-1) K^(-1). The latent heat of vaporization of water = 540 cal g ^(-1) .

A gas is enclosed in a cylindrical can fitted with a piston. The walls of the can and the piston are adiabatic. The initial pressure , volume and temperature of the gas are 100 kPa, 400cm^(3) and 300K respectively. The ratio of the specific heat capacities of the gas is (C_p / C_v = 1.5) Find the pressure and the temperature of the gas if it is (a) suddenly compressed (b) slowly compressed to 100 cm^(3) .

Two waves, each having a frequency of 100 Hz and a wavelength of 2.0 cm, are travelling in the same direction on a string. What is the phase difference between the waves (a) if the second wave was produced 0.015 s later than the first one at the same place, (b) if the two waves were produced at the same instant but the first one was produced a distance 4.0 cm behind the second one ? (c) If each of the waves has an amplitude of 2.0 mm, what would be the amplitudes of the resultant waves in part (a) and (b) ?

An ideal monatonic gas is confined in a cylinder by a spring-loaded piston of cross section 8.0xx10^(-3) m^(2). initially the gas is at 300K and occupies a volume of 2.4xx10^(-3)m^(-3) and the sprinng is in its relaxed state. The gas is heated by a small heater until the piston moves out slowly by 0.1m. Calculate the final tempreture of the gas. The force constant if the spring is 8000Nm^(-1) ,and the atmospheric pressure is 1.0xx10^(5)Nm^(-2) . the cylinder and the piston are thermally insulated. The piston and the spring are massless and there is no friction between the piston and the cylinder. Neglect any heat-loss through the lead wires of the heater. The heat capacity of the heater coil is negligible. assume the spring to be massless

The ratio of C_p / C_v = gamma for a gas. It's molecular weight is M. It's specific heat capacity at constant pressure is

Figure shows an aluminium wire of length 60 cm joined to a steel wire of length 80 cm and stretched between two fixed supports. The tension produced is 40 N . The cross-sectional area of the steel wire is 1.0 mm^(2) and that of the aluminimum wire is 3.0 mm^(2) The minimum frequency of a tuning fork which can produce standing waves in the system with the joint as a node is 10P (in Hz ) the find P . Given density of aluminimum is 2.6 g//cm^(3) and that of steel is 7.8 g//cm^(3) .

A barometer tube is 1 m long and 2cm^(2) in cross section. Mercury stands to a height of 75cm in the tube. When a small amount of oxygen is introduced in the space above the mercury level, the level falls by 5cm. Calculate the mass of the oxygen is introduced. Room temperature= 27^(@)C , g=10 m s_(-2) and density if mercury = 13600kg m^(-3) .