For example, if you want to calculate the volume of 40 moles of a gas under a pressure of 1013 hPa and at a temperature of 250 K, the result will be equal to: V = nRT/p = 40 * 8.3144598 * 250 / 101300 = 0.82 m³.
To find any of these values, simply enter the other ones into the ideal gas law calculator. For example, if you want to calculate the volume of 40 moles of a gas under a pressure of 1013 hPa and at a temperature of 250 K, the result will be equal to: V = nRT/p = 40 * 8.3144598 * 250 / 101300 = 0.82 m³.
An ideal gas is a special case of any gas that fulfills the following conditions: The gas consists of a large amount of molecules that move around randomly. All molecules are point particles (they don't take up any space). The molecules don't interact except for colliding.
The value of this constant is 8.3144598 J/(mol * K). The gas constant is often defined as the product of Boltzmann's constant k (it relates the kinetic energy and temperature of a gas) and Avogadro number (number of atoms in a mole of substance):
An ideal gas is a special case of any gas that fulfills the following conditions: The gas consists of a large number of molecules that move around randomly. All molecules are point particles (they don't take up any space). The molecules don't interact except for colliding.
It is used in many fundamental equations, such as the ideal gas law. The value of this constant is 8.3144626 J/ (mol·K).
An ideal gas is a special case of any gas that fulfills the following conditions: 1 The gas consists of a large number of molecules that move around randomly. 2 All molecules are point particles (they don't take up any space). 3 The molecules don't interact except for colliding. 4 All collisions between the particles of the gas are perfectly elastic. 5 The particles obey Newton's laws of motion.