What is the Transition State Theory?
Transition State Theory was developed by Henry Eyring in 1935 at the University of Manchester and is a very important factor in the chemical reaction that determines the rates of chemical reaction taking place in an elementary reaction. This theory functions on quasi-equilibrium, which is a chemical equilibrium that is established between the reactants when the reaction started and the complexes that had attained an activated transition state.
Though Transition State Theory cannot determine the absolute reaction rate of a chemical reaction as it will then require a very precise value of potential energy surfaces, it can efficiently calculate the Gibbs free energy or Gibb’s activation energy ( ߡG# or ߡ# GӨ ) and Entropy( Δ#SӨ ) and Enthalpy ( Δ#HӨ )of Activation of a particular reaction whose reaction rate constant is known.
Thus, transition theory provides a clear understanding of the rate of a chemical reaction and qualitative occurrence of a chemical reaction by assuming equilibrium between the reactants and the activated complex formed at the transition state.
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What is a Transition State?
A transition state of a chemical reaction is basically a configuration attended by reactants during complex formation along with the reaction coordinates where maximum potential energy is attained. Therefore, the meaning of transition state can be simply explained as when two reactants with a defined molecular arrangement undergo a chemical reaction, between the initial and final arrangements of the molecules or atoms an intermediate state of reaction is attained where maximum potential energy is observed. This particular intermediate configuration of atoms or molecules with the maximum value of potential energy is called activated complex and the state is defined as transition state.
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Now the diagram above shows the transition state of a chemical reaction taking place. It is basically a potential energy graph that shows the minimum energy required to convert reactants into products. From this curve, it is clear that that activation energy is a hurdle that the reactants need to overcome during the chemical reaction to get converted into their corresponding products. Therefore, numerically activation energy is the difference of the potential energy between the intermediate configuration of reaction coordinate and the initial reactants
Activation Energy = P.E. of intermediate configuration - P.E. of initial reactants
Activated Complex Theory Explained With Formula
Another term for Transition State Theory is Activated Complex Theory which is a qualitative analysis of a chemical reaction and other processes in which the relative positions of the atoms and the molecules of the reactants undergo continuous change resulting in a change of potential energy between the initial and final stage of the reaction.
The Activated Complex Theory is a primary element that helps in determining the value of reaction rate constant symbolized ‘k.'
Now, the reaction can be bimolecular or termolecular. Example,
A + B⟶AB
Thus, the activated intermediate complex will be in equilibrium with A and B.
A + B ⇌ AB# ⟶AB
Let kbe the rate constant for the reaction. Thus, the formula to determine the rate constant is
k = KBT/h * e-ΔG/RT
Here, KB is Boltzmann constant
H is Plank’s constant
T is temperature
ΔG is Gibbs free energy
ΔGо# = ΔHо# - TΔSо#
ΔHо# = Ea + (Δղ#g - 1) RT
Here, ΔHо# is Enthalpy
Ea is transition energy
Functioning of Active Complex
The two reactants X and Y can react with each other if their molecules collide with one another to form a product XY. Now the rate at which the reaction takes place is called its rate of reaction. The rate of reaction depends on many factors like temperature, the concentration of the reactants and the use of the catalyst. An increase in the rate of reaction indicates a more effective collision between molecules of reactants. Thus this collision increases with a rise in temperature, use of a catalyst to elevate the potential energy of reactants so that they can easily overcome the barrier of activation energy to form products, and also with the increase in the concentration of the reactants the collision of molecules increases. Therefore it is evident that the activated complex can be formed if the reactant molecules can attend the activation energy. Once the activated complex is formed, it cannot stay in that state as due to high potential energy as compared to the reactants or the products that it forms, it is very unstable in nature and temporary. So if enough activation energy is not present then the complex cannot form a product and eventually breaks back to reactants. If enough energy is present the complex form product.
Basic Concept of Collision Theory
Collision Theory states that the molecules of the reactants need to collide with each other in order for the ratio to take place. Now, if the collision of molecules initiates the reaction that the factors aggravating the collision of the molecules play a very important role in Collision theory. For instance, if high energy is given to the molecules they will collide with each other more effectively. If the temperature of the reaction increases the molecules will move faster and will collide more with each other.
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So the diagram illustrates that the molecules with higher kinetic energy are colliding faster than the blue sluggish molecules with very low kinetic energy thus the reaction rate will also decrease.
The rate at which the molecules collide with each other is the rate of collision and is also termed as collision rate and is mathematically expressed as Z = NA NBσAB√8кBT/ πμAB
Where NA and NB are the number of molecules of A and B reactants and are directly related to the concentration of the reactants.
√8кBT/ πμAB is the Maxwell-Boltzmann distribution of thermalized gases and determines the mean speed of molecules.
σAB represents the average sum of collision cross-sections of the molecules where the collision cross-section is defined as the collision region presented by one molecule to the other.
μAB is the reduced mass and is expressed as μAB = mAmB/ mA+mB
The reason that Transition State Theory is preferred over Collision Theory is that Collision Theory is only applicable for gaseous reactants whereas the former is applicable for the reactants in the solution.
FAQs on Transition State Theory
1. What is the Transition State Theory (TST)?
Transition State Theory, also known as Activated Complex Theory, is a model that explains the rates of chemical reactions. It proposes that between the state of reactants and the state of products, there exists an intermediate, high-energy state called the transition state. The rate of the reaction is then determined by the concentration of the species in this state and how quickly it converts to the final product.
2. What is a transition state in a chemical reaction?
A transition state is a specific, fleeting configuration of atoms at the peak of the energy barrier on a reaction coordinate diagram. It represents the point of maximum potential energy during a reaction's progress. This state is highly unstable, cannot be isolated, and exists for an extremely short time before decomposing into either reactants or products.
3. How is an activated complex formed according to Transition State Theory?
An activated complex is formed when reactant molecules collide with sufficient kinetic energy (equal to or greater than the activation energy) and the correct geometric orientation. During this moment, old chemical bonds are in the process of breaking while new ones are beginning to form, creating this temporary, high-energy molecular arrangement that corresponds to the transition state.
4. What is the main difference between a transition state and an activated complex?
While often used interchangeably, there's a subtle distinction. The activated complex is the actual, unstable arrangement of atoms at the energy peak. The transition state is the theoretical concept of that highest-energy configuration along the reaction path. In essence, the activated complex is the physical species that exists at the transition state.
5. Can you give an example of a transition state in a simple reaction?
A classic example is the SN2 reaction between a hydroxide ion (OH⁻) and chloromethane (CH₃Cl). The transition state is a trigonal bipyramidal structure where the carbon atom is partially bonded to both the incoming hydroxide group and the outgoing chlorine atom. This [HO···CH₃···Cl]⁻ complex represents the peak of the reaction's energy profile.
6. How does Transition State Theory provide a deeper insight than Collision Theory?
Collision Theory explains that reaction rates depend on the frequency and energy of collisions. However, Transition State Theory goes further by focusing on the nature of the collision itself. It examines the structural and energetic properties of the activated complex, allowing chemists to understand and predict how changes in molecular structure affect the activation energy and, consequently, the reaction rate.
7. Why is the concept of a transition state crucial for understanding catalysis?
The concept is fundamental to catalysis because a catalyst works by providing an alternative reaction pathway with a lower-energy transition state. By stabilising the activated complex, a catalyst effectively lowers the overall activation energy barrier, which dramatically increases the rate of the reaction without being consumed in the process.
8. What are the key assumptions of Transition State Theory?
The theory operates on a few key assumptions, including:
- Reactants are in a state of thermal equilibrium with the activated complex.
- The motion along the reaction coordinate at the transition state can be separated from other motions of the molecule.
- Once the activated complex crosses the energy barrier towards the products, it will always form products and not revert to reactants.
9. What is the significance of the Eyring equation in Transition State Theory?
The Eyring equation is the core mathematical formula of Transition State Theory. It provides a direct link between the rate constant of a reaction and the thermodynamic properties of the activated complex, specifically the Gibbs free energy of activation (ΔG‡). This allows for a more theoretical calculation of reaction rates compared to the empirical Arrhenius equation.
10. Does Transition State Theory have any limitations?
Yes, TST has limitations. It assumes that a system crossing the transition state barrier will proceed to products, which isn't always true as some may recross back to reactants. It also does not fully account for quantum mechanical effects like tunnelling, where particles can pass through an energy barrier instead of going over it, which is significant in certain reactions, especially at low temperatures.
