For the reaction of nitrogen monoxide to form and ammonia ΔS rxn o has to be calculated and the sign of ΔS o has to be identified whether it matches with the expected one. Concept Introduction: Entropy change: The sign of ΔS o for a reaction is determined by using the following rules: When a molecule is broken down and gives two or more smaller molecules. When the moles of gas is increases (by the breaking of molecules) Solid changes to liquid or gas state or liquid state changes to gas state. Entropy ( S ) : it is used to describe the disorder. It is the amount of arrangements possible in a system at a particular state. If the disorder increases in a system, then Δ S > 0 positive If the disorder decreases in a system, then Δ S < 0 negative If the disorder equal in a system, then Δ S = 0 . Entropy is the measure of randomness in the system. Standard entropy change in a reaction is the difference in entropy of the products and reactants. (ΔS ° rxn ) can be calculated by the following equation. ΔS ° rxn = S ° Products - S ° reactants Where, S ° reactants is the standard entropy of the reactants S ° Products is the standard entropy of the products
For the reaction of nitrogen monoxide to form and ammonia ΔS rxn o has to be calculated and the sign of ΔS o has to be identified whether it matches with the expected one. Concept Introduction: Entropy change: The sign of ΔS o for a reaction is determined by using the following rules: When a molecule is broken down and gives two or more smaller molecules. When the moles of gas is increases (by the breaking of molecules) Solid changes to liquid or gas state or liquid state changes to gas state. Entropy ( S ) : it is used to describe the disorder. It is the amount of arrangements possible in a system at a particular state. If the disorder increases in a system, then Δ S > 0 positive If the disorder decreases in a system, then Δ S < 0 negative If the disorder equal in a system, then Δ S = 0 . Entropy is the measure of randomness in the system. Standard entropy change in a reaction is the difference in entropy of the products and reactants. (ΔS ° rxn ) can be calculated by the following equation. ΔS ° rxn = S ° Products - S ° reactants Where, S ° reactants is the standard entropy of the reactants S ° Products is the standard entropy of the products
Definition Definition Substance that constitutes everything in the universe. Matter consists of atoms, which are composed of electrons, protons, and neutrons. Different atoms combine together to give rise to molecules that act as a foundation for all kinds of substances. There are five states of matter based on their energies of attraction: solid, liquid, gases, plasma, and BEC (Bose-Einstein condensates).
Chapter 20, Problem 20.37P
Interpretation Introduction
Interpretation:
For the reaction of nitrogen monoxide to form and ammonia ΔSrxno has to be calculated and the sign of ΔSo has to be identified whether it matches with the expected one.
Concept Introduction:
Entropy change: The sign of ΔSo for a reaction is determined by using the following rules:
When a molecule is broken down and gives two or more smaller molecules.
When the moles of gas is increases (by the breaking of molecules)
Solid changes to liquid or gas state or liquid state changes to gas state.
Entropy(S): it is used to describe the disorder. It is the amount of arrangements possible in a system at a particular state.
If the disorder increases in a system, then ΔS>0 positive
If the disorder decreases in a system, then ΔS<0 negative
If the disorder equal in a system, then ΔS=0.
Entropy is the measure of randomness in the system. Standard entropy change in a reaction is the difference in entropy of the products and reactants. (ΔS°rxn) can be calculated by the following equation.
ΔS°rxn = S°Products- S°reactants
Where,
S°reactants is the standard entropy of the reactants
S°Products is the standard entropy of the products
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The Laws of Thermodynamics, Entropy, and Gibbs Free Energy; Author: Professor Dave Explains;https://www.youtube.com/watch?v=8N1BxHgsoOw;License: Standard YouTube License, CC-BY