| 1. | This is a typical example of the law of mass action.
|
| 2. | Equipotentiality is subject to the other term Lashley coined, the law of mass action.
|
| 3. | Ostwald noted that the law of mass action can be applied to such systems as dissociating electrolytes.
|
| 4. | However, equipotentiality and the law of mass action don� t mean that there is no localization.
|
| 5. | Application of law of mass action to microbial populations results in the linear rate-limiting enzyme reaction.
|
| 6. | The first step in the derivation applies the law of mass action, which is reliant on free diffusion.
|
| 7. | However, the law of mass action is not universally valid because rate expressions do not universally follow stoichiometry.
|
| 8. | Dynamical properties of reaction networks were studied in chemistry and physics after invention of the law of mass action.
|
| 9. | The dominant species is therefore, by the law of mass action, determined by the pH of the solution.
|
| 10. | Hence, law of mass action in its simple form cannot be strictly applied in the case of strong electrolytes.
|
