All concentrations would change.
The "amounts" of reactants and products DO change in a reversible reaction. What doesn't change is the concentration of these reactants and products AT EQUILIBRIUM. And also what does not change is the total mass of the system.
In a chemical system, there are forward and reverse reactions occurring constantly. As the forward reactions progress, the increased amount of products allows for more and more reverse reactions. Once the rate of the forward and reverse reactions are equal, the system is at equilibrium. The forward and reverse reactions continue at equal but opposite rates; however, there are no further changes in the concentration of the products and reactants.
Heterogeneous Equilibrium
the water level is higher in side A than in side B
Hydrogen (i) Oxide
If the added substance is a reactant, the equilibrium shifts toward products. If it is a product, it moves towards reactants.
If the added substance is a reactant, the equilibrium shifts toward products. If it is a product, it moves towards reactants.
All concentrations would change (apex)
All concentrations would change (apex)
All concentrations would change (apex)
The two kinds of equilibrium are the folowing:Physical, which is an open system, and the rate of substances in, equals the rate of substances out.The other equilibrium is chemical equilibrium, which is a closed system, and the rate of the forward reaction equals the rate of the reverse reaction.
The concentrations of reactants and products are modified.
the equilibrium constant would change
the equilibrium constant would change
If the system is in equilibrium then the temperature is also.
The reaction quotient is the ratio of products to reactants not at equilibrium. If the system is at equilibrium then Q becomes Keq the equilibrium constant. Q = products/reactants If Q < Keq then there are more reactants then products so the system must shift toward the products to achieve equilibrium. If Q > Keq then there are more products than reactants and the system must shift toward the reactants to reach equilibrium.
Equilibrium is pushed to the reactant side