1) [tex]293 ^{\circ}C[/tex]
2) [tex]859^{\circ}C[/tex]
Explanation:
1)
The average kinetic energy of the molecules of an ideal gas is directly related to the Kelvin temperature of the gas, by the formula
[tex]KE=\frac{3}{2}kT[/tex]
where
KE is the kinetic energy
k is the Boltzmann constant
T is the Kelvin temperature
We can say therefore that the average kinetic energy of the particles is directly proportional to the absolute temperature of the gas; so, we can write:
[tex]KE\propto T[/tex]
And therefore
[tex]\frac{KE_1}{KE_2}=\frac{T_1}{T_2}[/tex] (1)
In this problem, we have:
[tex]KE_1 = K_{10}[/tex] is the initial kinetic energy of the molecules when the temperature of the gas is
[tex]T_1=10^{\circ}+273=283 K[/tex]
Here we want to find the temperature [tex]T_2[/tex] at which the average kinetic energy of the particles is
[tex]KE_2=2K_{10}[/tex]
So, twice the initial value. Substituting into eq.(1) and solving for T2, we find:
[tex]T_2=\frac{T_1 KE_2}{KE_1}=\frac{(283)(2K_{10})}{K_{10}}=566 K[/tex]
Converting into Celsius degrees,
[tex]T_2=566-273=293 ^{\circ}C[/tex]
2)
The root-mean-square (rms) speed of the molecules in a gas is given by the equation
[tex]v=\sqrt{\frac{3kT}{m}}[/tex]
where
k is the Boltzmann constant
T is the Kelvin temperature of the gas
m is the mass of each molecule
Therefore, from the equation we can say that the rms speed is proportional to the square root of the temperature:
[tex]v\propto \sqrt{T}[/tex]
So we can write:
[tex]\frac{v_1}{v_2}=\frac{\sqrt{T_1}}{\sqrt{T_2}}[/tex] (2)
where in this problem:
[tex]v_1 = v_{rms}[/tex] is the rms speed of the molecules when the temperature is
[tex]T_1=10^{\circ}C+273=283 K[/tex]
[tex]v_2=2v_{rms}[/tex] is the final rms speed of the molecules
Solving eq.(2), we find the temperature at which the rms speed is twice the initial value:
[tex]T_2=T_1 (\frac{v_2}{v_1})^2=(283)(\frac{2v_{rms}}{v_{rms}})^2=1132 K[/tex]
Converting into Celsius degrees,
[tex]T_2=1132-273=859^{\circ}C[/tex]
