Charles's Law Calculator
Charles's Law Calculator
Solve for volume or temperature of a gas at constant pressure using V₁/T₁ = V₂/T₂.
Initial State
Final State
Important!
Charles's Law Formula: V₁/T₁ = V₂/T₂
The Expansion of Gases: A Guide to Charles's Law
Charles's Law, another of the fundamental gas laws, describes the relationship between the volume and the temperature of a gas. Formulated by the French scientist Jacques Charles in the 1780s, the law states that for a fixed amount of a gas at a constant pressure, the volume of the gas is directly proportional to its absolute temperature. This means that as you heat a gas, its volume will increase, and as you cool it, its volume will decrease. This is a linear relationship—if you double the absolute temperature of a gas, you will double its volume, provided the pressure does not change.
A simple, everyday example of this is a balloon. If you take an inflated balloon from a warm room into the cold outdoors, you will notice it shrink slightly. The gas inside the balloon has cooled, its molecules move less vigorously, and it occupies less volume. If you bring it back inside, it will expand back to its original size. Charles's Law is a cornerstone of thermodynamics and is essential for understanding how engines work, how hot air balloons fly, and why it's important to check your car's tire pressure in different seasons. This calculator makes it easy to solve for any of the variables in the Charles's Law equation, providing a simple way to explore this direct relationship between volume and temperature.
The Charles's Law Formula
The direct relationship between volume (V) and absolute temperature (T) can be expressed mathematically. Since their ratio is a constant (k), we can write:
V / T = k
This leads to the more commonly used form of the law, which compares the initial and final states of a gas:
V₁/T₁ = V₂/T₂
Where:
- V₁ is the initial volume of the gas.
- T₁ is the initial absolute temperature of the gas.
- V₂ is the final volume of the gas.
- T₂ is the final absolute temperature of the gas.
Crucially, the temperature must be expressed in an absolute scale, such as Kelvin (K) or Rankine (°R), for this law to work. The calculation will not be correct if you use Celsius or Fahrenheit directly, as these scales have arbitrary zero points.
Absolute Zero and the Kelvin Scale
Charles's Law played a key role in the discovery of the concept of absolute zero. If you plot the volume of a gas versus its temperature, you get a straight line. If you extrapolate this line backwards, you find that the volume of the gas would theoretically reach zero at a temperature of -273.15°C. This temperature was recognized as the absolute coldest possible temperature, where all molecular motion ceases. This led to the development of the Kelvin scale, where 0 K is set at this absolute zero. Therefore, to use Charles's Law, you must convert any Celsius temperatures to Kelvin by adding 273.15 (K = °C + 273.15).
Charles's Law and the Ideal Gas Law
Like Boyle's Law, Charles's Law is a specific case of the more general Ideal Gas Law, PV = nRT. Charles's Law applies when the amount of gas (n) and the pressure (P) are held constant. In this scenario, the volume V becomes directly proportional to the temperature T.