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Yes, the concentrations are constant but not necessarily static. The 'forward' reaction rate matches the 'reverse' reaction rate.
all the changes to a system cancel out APEX
Redox is what is needed to reverse a biochemical reaction. The redox is used in science.
At equilibrium, the reaction rate of the forward reaction and the reverse reaction are equal to one another. This means that the products of the forward reaction are being made at the same speed as the products of the reverse reaction.
A rate constant
when forward and reverse reaction rates are equal
it's when it changes to one thing then changes to the original state
Yes, the concentrations are constant but not necessarily static. The 'forward' reaction rate matches the 'reverse' reaction rate.
Equal to one another. K= k1/k-1 where k1 is the forward reaction, k-1 is the backwards reaction and K is the equilibrium constant.
Law of equilibrium - The principle that (at chemical equilibrium) in a reversible reaction the ratio of the rate of the forward reaction to the rate of the reverse reaction is a constant for that reaction.
all the changes to a system cancel out APEX
Kc is the equilibrium constant of a chemical reaction; Kp is the equilibrium constant of a chemical reaction at constant pressure.
The product and reactants reach a final, unchanging level.
reversible reaction
the rate of te forward reaction and the rate of the reverse reaction
Redox is what is needed to reverse a biochemical reaction. The redox is used in science.
At equilibrium, the reaction rate of the forward reaction and the reverse reaction are equal to one another. This means that the products of the forward reaction are being made at the same speed as the products of the reverse reaction.