An ideal gas having density `1.7 xx 10^(-3) g cm ^(-3) at a preesure` 1.5 xx 10^(5) ` pa is a filled Kundt tube. When the gas is resonnated at a frequency of 3.0 kHz, nodes an formed at a separation of 6.0 cm . Calculate the heat molar heat capacites `(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.

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.

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.

When 100J of heat is given to an ideal gas it expands from 200cm^(3) to 400cm^(3) at a constant pressure of 3 xx 10^(5) Pa . Calculate (a) the change in internal energy of the gas (b) the number of moles in the gas if the initial temperature is 400K , (c ) the molar heat capacity C_(p) at constant pressure and (d) the molar heat capacity C_(v) at constant volume. [R = (25)/(3)J//mol-K]

When 100J of heat is given to an ideal gas it expands from 200cm^(3) to 400cm^(3) at a constant pressure of 3 xx 10^(5) Pa . Calculate (a) the change in internal energy of the gas (b) the number of moles in the gas if the initial temperature is 400K , (c ) the molar heat capacity C_(p) at constant pressure and (d) the molar heat capacity C_(v) at constant volume. [R = (25)/(3)J//mol-K]

The density of an ideal gas is 1.25xx10^(-3)g cm^(-3) at STP. Calculate the molecular weight of the gas.

The density of an ideal gas is 1.25xx10^(-3)g cm^(-3) at STP. Calculate the molecular weight of the gas.

The density of an ideal gas is 1.25xx10^(-3)g cm^(-3) at STP. Calculate the molecular weight of the gas.

An ideal gas expands from 100 cm^(3) to 200 cm^(3) at a constant pressure of 2.0 xx 10^(5) when 50 J of heat is supplied to it. Calculate (a) the change in internal energy of the gas , (b) the number of moles in the gas if the initial temperature is 300K , (C ) the molar heat capacity C_P at constant pressure and (d) the molar heat capacity C_v at constant volume

An ideal gas expands from 100 cm^(3) to 200 cm^(3) at a constant pressure of 2.0 xx 10^(5) when 50 J of heat is supplied to it. Calculate (a) the change in internal energy of the gas , (b) the number of moles in the gas if the initial temperature is 300K , (C ) the molar heat capacity C_P at constant pressure and (d) the molar heat capacity C_v at constant volume