"Quantitative effect of temperature on Equilibrium Constant by using Van't Hoff Equation"

"Quantitative effect of temperature on Equilibrium Constant by using Van't Hoff Equation"

Use the following equation to draw the relationship between temperature and equilibrium constant;

Relationship between Homogeneous Equilibrium and the Law of Mass Action (Part C)

 Relationship between Homogeneous Equilibrium and the Law of Mass Action (Part C)::

Case C- In gaseous reaction when no of moles decreases:

To understand this case, suppose the formation of ammonia by Haber Process

Relationship between Homogeneous Equilibrium and the Law of Mass Action (Part B)

 

"Relationship between Homogeneous Equilibrium and the Law of Mass Action (Part B)"

Case B- In gaseous reaction when no of moles increases:

Suppose the decomposition of PCl₅

"Relationship between Homogeneous Equilibrium and the Law of Mass Action (Part A)"

 

"Relationship between Homogeneous Equilibrium and the Law of Mass Action (Part A)"

The Law of Mass Action is a fundamental principle that governs the equilibrium of a chemical reaction. It states that the rate of a chemical reaction is directly proportional to the product of the concentrations (or activities) of the reactants, each raised to the power of their respective coefficients in the balanced chemical equation. This law applies to both homogeneous and heterogeneous equilibria.

“Exploring Homogeneous and Heterogeneous Equilibrium in Chemical Reactions”

 

“Exploring Homogeneous and Heterogeneous Equilibrium in Chemical Reactions”

Introduction:

Chemical equilibrium is a pivotal concept in the realm of chemistry, describing the balance between reactants and products in a reaction. This equilibrium can be further classified into two main types:

• Homogeneous equilibrium
• Heterogeneous equilibrium

"Deriving the Units of chemical equilibrium"

"Deriving the Units of chemical equilibrium"

Introduction

Equilibrium constants play a crucial role in chemical reactions, providing insights into the balance between reactants and products at a given point in a reaction. These constants are indispensable in the field of chemistry, aiding researchers and scientists in predicting reaction outcomes and understanding the dynamics of chemical systems.

"The Relationship Between Different Equilibrium Constants: Kp, Kc, Kx, and Kn"

 

"The Relationship Between Different Equilibrium Constants: Kp, Kc, Kx, and Kn"

Introduction:

Chemical equilibrium is a fascinating topic in the world of chemistry, where the balance between reactants and products in a chemical reaction is carefully maintained. To understand and quantify this balance, chemists rely on various equilibrium constants, such as Kp, Kc, Kx, and Kn. In this article,