Temperature and Ideal Gases Flashcards
What is temperature
It is the measure of the average kinetic energy of molecules in a body
What is thermal equilibrium
2 bodies in thermal contact are said to be in thermal equilibrium when there is no net flow of heat from one body to another. It also implies that the 2 bodies are at the same temperature
What is a thermometric property
It is a physical property that increases or decreases continuously with temperature
What is a fixed point
A fixed point is a temperature that is easily and precisely reproducible where all thermometers show the same reading under the same conditions
What is a numerical scale
By taking the value of the thermometric property at the fixed points and dividing the range of values into a number of equal units between the 2 points, we can set up a empirical scale of temperature for that thermometer
What is the Thermodynamic Temperature Scale
It is the scale that is theoretical and independent of the property of any particular substance
What are the fixed points on the Thermodynamic Temperature Scale
- Absolute zero (0k)
- all substances have minimum internal energy
- pressure of an ideal gas becomes 0
- Triple point of water (273.16k)
- the temperature at which the 3 phases of water coexist in dynamic equilibrium
What are the reasons for using triple point of water
- Unique invariant and occurs at only one temperature and presure
- The conditions can be easily reproduced using a triple point cell
What is the definition of kelvin
1 kelvin is defined to be 1/273.16 of the thermodynamic temperature of the triple point of water
What is celsius
θ/C = T/K - 273.15
What is the ideal gas equation
pV = nRT
What is an ideal gas
An ideal gas is one that obeys the equation pV = nRT at all pressure, volumes and temperatures
What is the Boltzmann constant, k
k = R/(Avogadro constant) = 1.38 x 10^-23 JK^-1
pV = NkT
What are the assumptions of the kinetic theory for ideal gas
- A gas consists of a very large number of molecules
- The gas molecules are in constant random motion and obey the laws of classical mechanics
- The molecules of the gas make perfect elastic collisions with one another and with the walls of the container
- The intermolecular forces are negligible except during the time of condition which is compared to the time between collisions
- Volume of the molecules is negligible compared to the volume of the gas
Derivation of the equation p = 1/3(Nm/V)
- Resolve the motion of molecules along the x-y-z directions
- c^2 = u^2 + v^2 + w^2
- Find the change of momentum upon collision with a wall
- Consider velocity, u, along x axis
- momentum before collision with wall, p=mu
- The molecule collides elastically with the wall and rebounds with velocity of -u
- momentum of collision p=-mu
- change in momentum, Δp=-2mu
- Consider velocity, u, along x axis
- Find the force on the wall due to the bombardments of molecules on the wall
- Time between collisions, Δt = 2l/U
- Rate of change of momentum = -mu^2/l
- Force exerted by wall on molecule = -mu^2/l
- By N3L, force on wall by molecule = mu^2/l
- Consider <u> = mean square velocity in x-direction
</u>- total force on wall = (Nm<u>)/l</u>
- Find pressure on the wall
- p = (Nm<u>)/V</u>
- Express in terms of mean-squared speed c
- 1/3 () = <u> = =</u>
- p = 1/3 (Nm/v) ()
- p = 1/3 (ρ)()</u></u></u></u>
