Consider the following condition and find out the direction of the reaction (1) Q < K (2) Q > K (3) Q = K Concept introduction: Equilibrium is the condition at which the concentration of the reactant and the product are equal and the reaction can in move either forward means towards product formation or backward reaction means towards reactant formation. Equilibrium constant K c is defined as the ratio of the concentrations of the products raised to the power of their stoichiometric coefficients and reactants raised to the power of their stoichiometric coefficients. Reaction quotient Q is defined as the ratio at any point of the reaction of the concentration of the product raised to the power of their stoichiometric coefficients and reactant raised to the power of their stoichiometric coefficients. aA + bB→cC + dD K c = [ C ] c [ D ] d [ A ] a [ B ] b , equilibrium Q = [ C ] c [ D ] d [ A ] a [ B ] b To find: The direction of reaction shift at different value of the reaction quotient and the equilibrium constant.
Consider the following condition and find out the direction of the reaction (1) Q < K (2) Q > K (3) Q = K Concept introduction: Equilibrium is the condition at which the concentration of the reactant and the product are equal and the reaction can in move either forward means towards product formation or backward reaction means towards reactant formation. Equilibrium constant K c is defined as the ratio of the concentrations of the products raised to the power of their stoichiometric coefficients and reactants raised to the power of their stoichiometric coefficients. Reaction quotient Q is defined as the ratio at any point of the reaction of the concentration of the product raised to the power of their stoichiometric coefficients and reactant raised to the power of their stoichiometric coefficients. aA + bB→cC + dD K c = [ C ] c [ D ] d [ A ] a [ B ] b , equilibrium Q = [ C ] c [ D ] d [ A ] a [ B ] b To find: The direction of reaction shift at different value of the reaction quotient and the equilibrium constant.
Solution Summary: The author explains the direction of reaction shift at different values of the reaction quotient and the equilibrium constant.
Definition Definition Number that is expressed before molecules, ions, and atoms such that it balances out the number of components present on either section of the equation in a chemical reaction. Stoichiometric coefficients can be a fraction or a whole number and are useful in determining the mole ratio among the reactants and products. In any equalized chemical equation, the number of components on either side of the equation will be the same.
Chapter 15, Problem 14E
Interpretation Introduction
Interpretation: Consider the following condition and find out the direction of the reaction
(1) Q < K
(2) Q > K
(3) Q = K
Concept introduction: Equilibrium is the condition at which the concentration of the reactant and the product are equal and the reaction can in move either forward means towards product formation or backward reaction means towards reactant formation.
Equilibrium constant Kc is defined as the ratio of the concentrations of the products raised to the power of their stoichiometric coefficients and reactants raised to the power of their stoichiometric coefficients.
Reaction quotient Q is defined as the ratio at any point of the reaction of the concentration of the product raised to the power of their stoichiometric coefficients and reactant raised to the power of their stoichiometric coefficients.
aA + bB→cC + dD
, equilibrium
To find: The direction of reaction shift at different value of the reaction quotient and the equilibrium constant.
nd engy Level above Ferm; Level if prebabl.tg
f enrgy levelis o03 and temportun
is 6ook
carbon dioxideand
Given the reaction:
CHu+2O2→ COe+2H20
* when IGa of methane
(CHu) and 3290FOKygen
Oz reacted +o pradoco
carbon dioxide and water,
g OF carbon dioxide was
produced.what ig the percent
yeild of carbon dioxide
and water
a.25%
b.5.0%
C.I0%
d 50%
Consider +his reaction
Hame
Tools
Document
Sign in
1L ontainec Contain o.4mul.ol Hz
Brg in
the reaction reached
state Ke for meel equal to 0.25 M.
Calculate the Concentration of Constitucnts?
A Ciute SDE
425 K temperature
the quilibrium
d-0.4 mmel.
when
4 Fila Sia
L Send or Sgrature
* Tand trck
Sture nd e len in te
nise Cletd