endergonic reaction

(noun)

A chemical reaction in which the standard change in free energy is positive, and energy is absorbed

Related Terms

  • Gibbs free energy
  • exergonic reaction

Examples of endergonic reaction in the following topics:

  • Free Energy

    • These chemical reactions are called endergonic reactions; they are non-spontaneous.
    • An endergonic reaction will not take place on its own without the addition of free energy.
    • Therefore, the chemical reactions involved in anabolic processes are endergonic reactions.
    • Exergonic and endergonic reactions result in changes in Gibbs free energy.
    • Exergonic reactions release energy; endergonic reactions require energy to proceed.
  • ATP: Adenosine Triphosphate

    • Cells couple the exergonic reaction of ATP hydrolysis with endergonic reactions to harness the energy within the bonds of ATP.
    • ATP provides the energy for both energy-consuming endergonic reactions and energy-releasing exergonic reactions, which require a small input of activation energy.
    • Cells couple the exergonic reaction of ATP hydrolysis with the endergonic reactions of cellular processes.
    • By donating free energy to the Na+/K+ pump, phosphorylation drives the endergonic reaction.
    • In this example, the exergonic reaction of ATP hydrolysis is coupled with the endergonic reaction of converting glucose for use in the metabolic pathway.
  • Activation Energy

    • Activation energy must be considered when analyzing both endergonic and exergonic reactions.
    • Cells will at times couple an exergonic reaction $(\Delta G<0)$ with endergonic reactions $(\Delta G>0)$, allowing them to proceed.
    • The free energy released from the exergonic reaction is absorbed by the endergonic reaction.
    • Although the image above discusses the concept of activation energy within the context of the exergonic forward reaction, the same principles apply to the reverse reaction, which must be endergonic.
    • In this endergonic reaction, activation energy is still required to transform the reactants A + B into the product C.
  • Spontaneous and Nonspontaneous Processes

    • There are two types of processes (or reactions): spontaneous and non-spontaneous.
    • Spontaneity does not imply that the reaction proceeds with great speed.
    • The rate of a reaction is independent of its spontaneity, and instead depends on the chemical kinetics of the reaction.
    • An endergonic reaction (also called a nonspontaneous reaction or an unfavorable reaction) is a chemical reaction in which the standard change in free energy is positive, and energy is absorbed.
    • Endergonic reactions can also be pushed by coupling them to another reaction, which is strongly exergonic, through a shared intermediate.Saul Steinberg from The New Yorker illustrates a nonspontaneous process here.
  • ATP in Metabolism

    • In this way, ATP is a direct link between the limited set of exergonic pathways of glucose catabolism and the multitude of endergonic pathways that power living cells.
    • The energy from ATP can also be used to drive chemical reactions by coupling ATP hydrolysis with another reaction process in an enzyme.
    • During an endergonic chemical reaction, ATP forms an intermediate complex with the substrate and enzyme in the reaction.
    • This is illustrated by the following generic reaction:
    • In phosphorylation reactions, the gamma phosphate of ATP is attached to a protein.
  • Solvent Effects

    • Reactions which involve the formation of charged atoms and molecules are usually extremely endothermic in the gas phase, but may become spontaneous in certain solvents.
    • These different entropy changes are incorporated in the free energy of solution, which is exergonic for NaCl, but endergonic for CaF2.
  • Reaction Quotients

    • The reaction quotient is a measure of the relative amounts of reactants and products during a chemical reaction at a given point in time.
    • The reaction quotient, Q, is a measure of the relative amounts of reactants and products during a chemical reaction at a given point in time.
    • By comparing the value of Q to the equilibrium constant, Keq, for the reaction, we can determine whether the forward reaction or reverse reaction will be favored.
    • As the reaction proceeds, assuming that there is no energy barrier, the species' concentrations, and hence the reaction quotient, change.
    • Calculate the reaction quotient, Q, and use it to predict whether a reaction will proceed in the forward or reverse direction
  • Changes in Temperature

    • Changes in temperature can affect the equilibrium state of a reversible chemical reaction.
    • Reactions can be classified by their enthalpies of reaction.
    • A diagram of the reaction coordinate for an exothermic reaction is shown in .
    • Exothermic reactions will be shifted toward the reactants.
    • Endothermic reactions, on the other hand, will be shifted towards product formation as heat is removed from the reaction's surrounding environment.
  • Ene Reactions

    • The reverse process is called a retro ene reaction.
    • This is the same bond bookkeeping change exhibited by electrocyclic reactions, but no rings are formed or broken in an ene reaction unless it is intramolecular.
    • The following examples illustrate some typical ene reactions, with equation 3 being an intramolecular ene reaction.
    • Reaction 4 is drawn as a retro ene reaction, although this has not been demonstrated to be general for all reactions of allylic alcohols with thionyl chloride.
    • A similar acid-catalyzed reaction of simple aldehydes with alkenes to give allylic alcohols, 1,3-diols or 1,3-dioxanes is known as the Prins reaction.
  • Energy Changes in Chemical Reactions

    • For example, combustion reactions are usually exothermic.
    • In exothermic reactions, the products have less enthalpy than the reactants, and as a result, an exothermic reaction is said to have a negative enthalpy of reaction.
    • For example, decomposition reactions are usually endothermic.
    • Thus, an endothermic reaction is said to have a positive enthalpy of reaction.
    • Significant heat energy is needed for this reaction to proceed, so the reaction is endothermic.
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