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[[Image:Incandescence.jpg|thumb|right|180px|The sparks generated by striking steel against a [[Ferrocerium|flint]] provide the '''activation energy''' to initiate combustion in this [[Bunsen burner]]. The blue flame will sustain itself after the sparks are extinguished because the continued combustion of the flame is now energetically favorable.]] | |||
In [[chemistry]], '''activation energy''' is a term introduced in 1889 by the Swedish scientist [[Svante Arrhenius]] that is defined as the minimum energy that must be input to a chemical system, containing potential reactants, in order for a [[chemical reaction]] to occur. Activation energy may also be defined as the minimum energy required to start a chemical reaction. The activation energy of a reaction is usually denoted by ''E<sub>a</sub>'' and given in units of [[joule per mole|kilojoules per mole]]. | |||
Activation energy can be thought of as the height of the [[potential barrier]] (sometimes called the energy barrier) separating two [[minima]] of [[potential energy]] (of the reactants and products of a reaction). For a chemical reaction to proceed at a reasonable rate, there should exist an appreciable number of molecules with energy equal to or greater than the activation energy. | |||
At a more advanced level, the Arrhenius Activation energy term from the [[Arrhenius equation]] is best regarded as an experimentally determined parameter that indicates the sensitivity of the reaction rate to temperature. There are two objections to associating this activation energy with the threshold barrier for an elementary reaction. First, it is often unclear as to whether or not reaction does proceed in one step; threshold barriers that are averaged out over all elementary steps have little theoretical value. Second, even if the reaction being studied is elementary, a spectrum of individual collisions contributes to rate constants obtained from bulk ('bulb') experiments involving billions of molecules, with many different reactant collision geometries and angles, different translational and (possibly) vibrational energies - all of which may lead to different microscopic reaction rates. | |||
== Negative activation energy == | |||
In some cases, rates of reaction ''decrease'' with increasing temperature. When following an approximately exponential relationship so the rate constant can still be fit to an Arrhenius expression, this results in a negative value of ''E<sub>a</sub>''. Elementary reactions exhibiting these negative activation energies are typically barrierless reactions, in which the reaction proceeding relies on the capture of the molecules in a potential well. Increasing the temperature leads to a reduced probability of the colliding molecules capturing one another (with more glancing collisions not leading to reaction as the higher momentum carries the colliding particles out of the potential well), expressed as a reaction [[cross section (physics)|cross section]] that decreases with increasing temperature. Such a situation no longer leads itself to direct interpretations as the height of a potential spot. | |||
== Temperature independence and the relation to the Arrhenius equation == | |||
The [[Arrhenius equation]] gives the quantitative basis of the relationship between the activation energy and the rate at which a reaction proceeds. From the Arrhenius equation, the activation energy can be expressed as | |||
:<math>k = A e^{{-E_a}/{RT}}</math> | |||
where ''A'' is the [[frequency factor (chemistry)|frequency factor]] for the reaction, ''R'' is the universal [[gas constant]], ''T'' is the temperature (in [[kelvin]]), and ''k'' is the [[Reaction rate constant|reaction rate coefficient]]. While this equation suggests that the activation energy is dependent on temperature, in regimes in which the Arrhenius equation is valid this is cancelled by the temperature dependence of ''k''. Thus, ''E<sub>a</sub>'' can be evaluated from the reaction rate coefficient at any temperature (within the validity of the Arrhenius equation). | |||
== Catalysis == | |||
{{Main|Catalysis}} | |||
[[Image:Activation energy.svg|right|thumb|360px|The relationship between activation energy (<math>E_a</math>) and [[Standard enthalpy of formation|enthalpy of formation]] (Δ''H'') with and without a catalyst, plotted against the [[reaction coordinate]]. The highest energy position (peak position) represents the transition state. With the catalyst, the energy required to enter transition state decreases, thereby decreasing the energy required to initiate the reaction.]] | |||
A substance that modifies the transition state to lower the activation energy is termed a [[catalyst]]; a [[biology|biological]] catalyst is termed an [[enzyme]]. It is important to note that a catalyst increases the rate of reaction without being consumed by it. In addition, while the catalyst lowers the activation energy, it does not change the energies of the original reactants or products. Rather, the reactant energy and the product energy remain the same and only the ''activation energy'' is altered (lowered). | |||
== Relationship with Gibbs free energy == | |||
In the [[Arrhenius equation]], the term activation energy (E<sub>a</sub>) is used to describe the energy required to reach the [[reaction coordinate|transition state]]. Likewise, the [[Eyring equation]] is a similar equation which also describes the rate of a reaction. Instead of also using E<sub>a</sub>, however, the Eyring equation uses the concept of [[Gibbs free energy]] and the symbol *<math>\ \Delta G^\ddagger </math> to denote the energy of the [[transition state]]. | |||
== See also == | |||
* [[Arrhenius equation]] | |||
* [[Chemical kinetics]] | |||
* [[Mean kinetic temperature]] | |||
* [[Quantum tunnelling]] | |||
== External links == | |||
* [http://chemed.chem.purdue.edu/genchem/topicreview/bp/ch22/activate.html The Activation Energy of Chemical Reactions] | |||
[[Category:Chemical kinetics]] | |||
[[Category:Catalysis]] | |||
Revision as of 04:56, 26 January 2014
In chemistry, activation energy is a term introduced in 1889 by the Swedish scientist Svante Arrhenius that is defined as the minimum energy that must be input to a chemical system, containing potential reactants, in order for a chemical reaction to occur. Activation energy may also be defined as the minimum energy required to start a chemical reaction. The activation energy of a reaction is usually denoted by Ea and given in units of kilojoules per mole.
Activation energy can be thought of as the height of the potential barrier (sometimes called the energy barrier) separating two minima of potential energy (of the reactants and products of a reaction). For a chemical reaction to proceed at a reasonable rate, there should exist an appreciable number of molecules with energy equal to or greater than the activation energy.
At a more advanced level, the Arrhenius Activation energy term from the Arrhenius equation is best regarded as an experimentally determined parameter that indicates the sensitivity of the reaction rate to temperature. There are two objections to associating this activation energy with the threshold barrier for an elementary reaction. First, it is often unclear as to whether or not reaction does proceed in one step; threshold barriers that are averaged out over all elementary steps have little theoretical value. Second, even if the reaction being studied is elementary, a spectrum of individual collisions contributes to rate constants obtained from bulk ('bulb') experiments involving billions of molecules, with many different reactant collision geometries and angles, different translational and (possibly) vibrational energies - all of which may lead to different microscopic reaction rates.
Negative activation energy
In some cases, rates of reaction decrease with increasing temperature. When following an approximately exponential relationship so the rate constant can still be fit to an Arrhenius expression, this results in a negative value of Ea. Elementary reactions exhibiting these negative activation energies are typically barrierless reactions, in which the reaction proceeding relies on the capture of the molecules in a potential well. Increasing the temperature leads to a reduced probability of the colliding molecules capturing one another (with more glancing collisions not leading to reaction as the higher momentum carries the colliding particles out of the potential well), expressed as a reaction cross section that decreases with increasing temperature. Such a situation no longer leads itself to direct interpretations as the height of a potential spot.
Temperature independence and the relation to the Arrhenius equation
The Arrhenius equation gives the quantitative basis of the relationship between the activation energy and the rate at which a reaction proceeds. From the Arrhenius equation, the activation energy can be expressed as
where A is the frequency factor for the reaction, R is the universal gas constant, T is the temperature (in kelvin), and k is the reaction rate coefficient. While this equation suggests that the activation energy is dependent on temperature, in regimes in which the Arrhenius equation is valid this is cancelled by the temperature dependence of k. Thus, Ea can be evaluated from the reaction rate coefficient at any temperature (within the validity of the Arrhenius equation).
Catalysis
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A substance that modifies the transition state to lower the activation energy is termed a catalyst; a biological catalyst is termed an enzyme. It is important to note that a catalyst increases the rate of reaction without being consumed by it. In addition, while the catalyst lowers the activation energy, it does not change the energies of the original reactants or products. Rather, the reactant energy and the product energy remain the same and only the activation energy is altered (lowered).
Relationship with Gibbs free energy
In the Arrhenius equation, the term activation energy (Ea) is used to describe the energy required to reach the transition state. Likewise, the Eyring equation is a similar equation which also describes the rate of a reaction. Instead of also using Ea, however, the Eyring equation uses the concept of Gibbs free energy and the symbol * to denote the energy of the transition state.
