Dissolution Definition in Chemistry

Dissolution Definition in ChemistryA dissolution definition in chemistry is an equation, that when applied, will give the function of the dissolution. There are two processes involved in a dissolution. The first process is the chemical dissociation, where a substance undergoes the process where the molecule is separated from the body. For example, when you melt down gasoline, it will leave a residue on the ground, after the chemical reaction.The second process is crystallization or chemical refraction, where the substance is pulled up and forms a crystal. In the process of chemical refraction, the body of the substance will not be physically broken up but only refracted into a fluid form. In the case of petroleum, the water molecule is pulled up and precipitates into a crystalline form, making the substance almost liquid at room temperature.However, in both of these processes, some of the chemical laws of the molecules remain. For example, if a molecule is pulled up, and then breaks in a liquid form, and the chemical laws remain, the molecule is bound to a solid rock, and this will leave a residue.Thus, what is left is a residue of the dissolved water molecule, which is bound in a solid rock. The other common example of this chemical is what happens in the weather when a water molecule is evaporated, leaving a solid layer in the air. In this case, however, the chemical laws do not apply, since there is no physical process occurring.It is important for a chemist to understand all the chemical equations involved in this process. A number of the chemical equations have direct applications to physical chemistry, and these are used by physicists. Understanding these equations can make a big difference to a student who is taking chemistry.Dissolution in chemistry will require the combination of chemistry equations with physics to form a very useful chemical formula. This is because even if the physical chemist is right, he or she may be wrong about the dissolution pr ocess.These equations will involve such things as molecular weight, molecular structure, equilibrium constant, surface tension, molecular diffusion, work, electric charge, water content, charge in crystals, etc. If a chemist can understand these equations, then he or she can use them to form a good, useful chemical formula for dissolving a substance in water.