The Chemistry Rate Constant

The Chemistry Rate ConstantA number of theories are put forward about the relationship between changes in the chemical state and chemical rate constant. While there are many differences between the various theories, the major factor is the fact that all agree that there is a chemical rate constant that is constant regardless of what the chemical is doing. This constant rate constant is referred to as the gas phase rate constant.The gas-phase rate constant was first used in 1924 by Rutherford to determine the chemical rate constant for water vapor. This constant rate constant is measured in parts per second and is measured as the ratio of the molecular velocity to the molecular rotation frequency.When it comes to atomic physics the constant rate constant is known as c p. The cap is defined as the change in the enthalpy of state per second. It is measured as the effect on a molecule of changing its enthalpy.The cap varies as the value of the gas phase rate constant changes. This means that if the cop was ever to change the actual rate constant would change too. However, the atom theory states that the c p does not change with time.Atomic theory states that the rate constant is also determined by the molecular density. In other words, the density can be described as the product of the atom size and the molecular weight.This gives a relationship between the frequency and the c p. The frequency is the rate at which the molecular rotation occurs per second and the cup is the frequency at which the molecular rotation occurs per second.The c p can be quantified to determine the actual concentration. The strength of the relationship between the c p and the frequency is that the frequency will depend on the amount of oxygen present and that the frequency will also be related to the size of the molecule.While this equation is quite complex and can be written off as 'quintic' it is not completely unworkable. It has been calculated using modern molecular physics and mathema tical calculations. The question is therefore whether or not we will ever really have a physical example of this relationship.