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Question: If there is no loss of energy. Two monatomic ideal gases at temperature \({T_1}\) and \({T_2}\) are ...

If there is no loss of energy. Two monatomic ideal gases at temperature T1{T_1} and T2{T_2} are mixed. If the masses of molecules of two gases are m1{m_1} and m2{m_2} number of their molecules are n1{n_1} and n2{n_2}.then the temperature of mixture will be:
(A) T1+T2n1+n2\dfrac{{{T_1} + {T_2}}}{{{n_1} + {n_2}}}
(B) T1n1\dfrac{T_1}{n_1} + T1n2\dfrac{T_1}{n_2}
(C) n2T1+n1T2n1+n2\dfrac{{{n_2}{T_1} + {n_1}{T_2}}}{{{n_1} + {n_2}}}
(D) n1T1+n2T2n1+n2\dfrac{{{n_1}{T_1} + {n_2}{T_2}}}{{{n_1} + {n_2}}}

Explanation

Solution

Hint An ideal gas is a theoretical gas composed of many randomly moving point particles that are not subject to interparticle interactions. The ideal gas concept is useful because it obeys the ideal gas law, a simplified equation of state, and is amenable to analysis under statistical mechanics. The average molecular kinetic energy is proportional to the ideal gas law's absolute temperature.

Complete Step by Step Solution
1. The average kinetic energy per molecule of a perfect gas = 32RT\dfrac{3}{2}RT
2. Average kinetic energy of the molecules of the first gas = 32n1RT1\dfrac{3}{2}{n_1}R{T_1}
Average kinetic energy of the molecules of the second gas = 32n2RT2\dfrac{3}{2}{n_2}R{T_2}
Therefore, the total kinetic energy of the two molecules of gas before they are mixed is Ki=32n1RT1+32n2RT2=32(n1T1+n2T2)R.......(1){K_i} = \dfrac{3}{2}{n_1}R{T_1} + \dfrac{3}{2}{n_2}R{T_2} = \dfrac{3}{2}\left( {{n_1}{T_1} + {n_2}{T_2}} \right)R.......(1)
If T is the temperature of the mixture, then the kinetic energies of the molecules after mixing is Kf=32(n1+n2)RT.............(2){K_f} = \dfrac{3}{2}\left( {{n_1} + {n_2}} \right)RT.............(2)
Since there is no loss of energy
∴ Sum of change of internal energies must be zero
Equating (1) and (2) we get,
Ki=Kf 32(n1T1+n2T2)R=32(n1+n2)RT T=(n1T1+n2T2)(n1+n2)  {K_i} = {K_f} \\\ \dfrac{3}{2}\left( {{n_1}{T_1} + {n_2}{T_2}} \right)R = \dfrac{3}{2}\left( {{n_1} + {n_2}} \right)RT \\\ T = \dfrac{{\left( {{n_1}{T_1} + {n_2}{T_2}} \right)}}{{\left( {{n_1} + {n_2}} \right)}} \\\

Hence, the option (d) is the correct answer.​

Note In the kinetic model of gases, the pressure is equal to the force exerted by the atoms hitting and rebounding from a unit area of the gas container surface. The product of pressure and volume per mole is proportional to the average (translational) molecular kinetic energy.