Given below are observations on molar specific heats at room temperature of some common gases.
`{:("Gas","Molar specific heat "(C_(v))),(,("cal mol"^(1)K^(-1))),("Hydrogen",4.87),("Nitrogen",4.97),("Oxygen",5.02),("Nitric oxide",4.99),("Carbon monoxide",5.01),("Chlorine",6.17):}`
The measured molar specific heats of these gases are markedly different from those for monatomic gases. Typically, molar specific heat of a monatomie gas is` 2.52` cal/mol K. Explain this difference. What can you infer from the somewhat larger than the rest) value for chlorine ?

Given below are observations on molar specific heats at room temperature of some common gases. The measured molar specific heats of these gases are markedly different from those for monatomic gases. Typically, molar specific heat of a monatomic gas is 2.92 cal/mol K. Explain this difference. What can you infer from the somewhat larger (than the rest) value for chlorine ?

Calculate the molar specific heat at constant volume . Given : specific heat of hydrogen at constant pressure is 6.85 "cal" mol^(-1) K^(-1) and density of hydrogen = 0.0899 "g" cm^(-3) . One mole of gas = 2.016g, J=4.2xx10^(7) "erg" cal^(-1) and 1 atmosphere = 10^(6) "dyne" cm^(-2) .

Calculate the difference between the two principal specific heats of 1g of helium gas at S.T.P. Given atomic weight of helium = 4 and J = 4.186 J cal^(-1) and R = 8.31 J mol^(-1)K^(-1) .

Statement - 1 : A gas is taken from state A to state B through two different paths. Molar specific heat capacity in path (A) is more as compared to (B) Statement- 2 : Specific heat C =(Q)/(nDeltaT) & Q = DeltaU + W and W is equal to area under P-V diagram.

An ideal gas has a specific heat at constant pressure C_P=(5R)/2 . The gas is kept in a closed vessel of volume 0.0083m^3 , at a temperature of 300K and a pressure of 1.6xx10^6 N//m^2 . An amount of 2.49xx10^4 Joules of heat energy is supplied to the gas. Calculate the final temperature and pressure of the gas.

An ideal gas has a specific heat at constant pressure C_P=(5R)/2 . The gas is kept in a closed vessel of volume 0.0083m^3 , at a temperature of 300K and a pressure of 1.6xx10^6 N//m^2 . An amount of 2.49xx10^4 Joules of heat energy is supplied to the gas. Calculate the final temperature and pressure of the gas.

5 mole of oxygen are heated at constant volume from 10^(@)C "to" 20^(@)C . What will be the change in internal energy of the gas? Gram molar specific heat of gas at constant pressure =8cal. "Mole"^(-1).^(@)C^(-1) and R=8.36J "mole"^(-1).^(@)C^(-1) .

Surafce tension is exhibited by liquids due to force of attraction between the molecules of the liquid .The surface tension decreases with increases in temperature and vanishes at boiling point Given that the latent heat of vaporization for water L_(v)=540(kcal)/(kg) the mechanical equivalent of heat J=4.2(J)/(cal) density of water rho_(w)=10^(3)kgl^(-1) ,Avogadro'sno. N_(A)=6.0xx10^(26)k " mole"^(-1) . Molecular weight of water M_(A)=10kg , for 1k mole . (a) Estimate the energy required for one molecule of water to evaporated. (b) Show that the inter molecular distance for water is d=((M_(A))/(N_(A))xx(1)/(rho_(w)))^((1)/(3)) and find its value. (c ) 1 g of water in the vapour state at 1 atm occupies 1601cm^(3) , estimate the intermolecular distance at boiling point in the vapour state. (d) During vaporisation a molecule overcomes a force F, assumed constant to go from an inter molecular distance d to d .Estimate the value of F. (e ) Caculate (F)/(d) , which is a measure of the surface tension.

The pressure in monoatomic gas increases linearly from =4xx10^(5) Nm^(-2) to 8xx10^(+5) Nm^(-2) when its volume increases from 0.2m^(3) to 0.5m^(3) . Calculate . (i) Work done by the gas , (ii) Increase in the internal energy, (iii) Amount of heat supplied, (iv) Molar heat capacity of the gas R= 8.31J mol^(-1) K^(-1)

Comprehension-1 Two closed identical conducting containers are found in the laboratory of an old scientist. For the vertification of the gas some experiments are performed on the two boxes and the results are noted. Experimenet 1. When the two containers are weighed W_(A) = 225tg, W_(B) = 160 g and mass of evacuated container W_(C) = 100g . Experiment 2. When the two containers are given same amount of heat same temperature rise is recorded. The pressure changes found are DeltaP_(A) = 2.5 atm, Deltap_(B) = 1.5 atm . Required data for unknown gas: |(underset("molar mass")(Mono)",He,Ne,Ar,Kr,Xe,Rd),(,4g,20g,40g,84g,131g,222g),(underset(molar mass)(Dia),H_(2),F_(2),N_(2),O_(2),CI_(2),),(,2g,19g,28g,32g,71g,)| The initial internal energy of the gas in container 'A'. If the container were at room temperature initially