The graph of Charles's law shows that the volume of a gas is directly proportional to its kelvin temperature under constant pressure
Charles law
volume and temperature of a gas are directly proportional
The spring obeys Hooke's law for all displacements. Hooke recognized this, and his law applies only while the displacement stays within the "elastic limit" for the spring. Within that range the graph is a straight line through the origin.
Well, pressure has to be kept constant and so does the mass of the gas with Charles's Law. Charles's Law--V1/T1=V2/T2--can be derived from the Combined Gas Law--V1xP1/T1=V2xP2/T2--by keeping the pressure constant which in turn cancels out the pressure in the Combined Gas Law leaving you with Charles's Law.
gases
A graph of Charles Law shows the relationship between temperature and volume of gas.
The intercept of -273¤C on the Charles law graph represents the absolute minimum of temperature below which it is not possible to go -Chukwuma Akubueze
This graph of Charles Law would show the relationship of volume of a gas as a function of the temperature at constant pressure.
Volume increases at the same rate as temperature.
Volume increases at the same rate as temperature.
A graph of Charles' Law shows the relationship between Volume vs. Temperature. Volume is placed on the y axis and temperature on the x axis. The relationship is linear if temperature is in units of Kelvin.
The relationship between temperature and volume
The relationship between temperature and volume
The relationship between temperature and volume
Volume increases at the same rate as temperature.
Charles law
Charles's Law. (Chapter 3.4 Assessments for Physical Science)