What is the Difference Between First Order and Pseudo First Order Reaction?
🆚 Go to Comparative Table 🆚The main difference between a first-order reaction and a pseudo first-order reaction is that a first-order reaction has an inherent order of one, while a pseudo first-order reaction is a second-order reaction that has been altered to behave like a first-order reaction under certain conditions.
First-Order Reactions:
- The rate law for a first-order reaction is given by: $$rate = -k[A]$$
- The half-life (t1/2) of a first-order reaction is related to the rate constant (k) as follows: $$t1/2 = \frac{\ln{2}}{k}$$
- First-order reactions are characterized by a decrease in the concentration of a reactant by a constant percentage per unit time.
Pseudo First-Order Reactions:
- A pseudo first-order reaction is a second-order reaction that has been altered to appear as a first-order reaction under certain conditions.
- The rate law for a pseudo first-order reaction is given by: $$rate = -k[A]$$
- The half-life (t1/2) of a pseudo first-order reaction is related to the pseudo rate constant (k') as follows: $$t1/2 = \frac{\ln{2}}{k'}$$
- Pseudo first-order reactions simplify the quantification of reaction dynamics, making it easier to analyze second-order reactions.
In summary, the key difference between first-order and pseudo first-order reactions is that first-order reactions are genuine reactions with an inherent order of one, while pseudo first-order reactions are second-order reactions that have been altered to behave like first-order reactions under certain conditions.
Comparative Table: First Order vs Pseudo First Order Reaction
First-order reactions and pseudo first-order reactions are different types of chemical reactions. Here is a comparison between the two:
| First-order reactions | Pseudo first-order reactions |
|---|---|
| The reaction's order is one by nature. | The reaction is a second-order reaction made to behave like a first-order reaction. |
| Occur when the rate of the reaction depends on the concentration of only one reactant. | Occur when the rate of the reaction depends on the concentration of two reactants, but one of them is in great excess or constant concentration. |
| The rate law is given by: $$\frac{d[A]}{dt} = -k[A]$$. | The rate law is given by: $$\frac{d[A]}{dt} = -k[A]t$$ or $$\frac{d[A]}{dt} = -k^{'}[A]$$. |
| Used to simplify the analysis and quantification of reaction dynamics, especially when two reactants must be measured simultaneously. | Used to simplify the analysis and quantification of reaction dynamics, especially when two reactants must be measured simultaneously. |
In summary, first-order reactions have an order of one by nature, while pseudo first-order reactions are second-order reactions that are made to behave like first-order reactions. Both types of reactions can simplify the analysis and quantification of reaction dynamics, but the underlying mechanisms and rate laws differ.
- First vs Second Order Reactions
- First vs Second Order Phase Transition
- Elementary vs Complex Reaction
- Elementary vs Non Elementary Reaction
- Order of Reaction vs Molecularity
- Synthesis Reaction vs Substitution Reaction
- Reaction Rate vs Rate Constant
- Reaction Rate vs Specific Rate Constant
- SN1 vs SN2 Reactions
- Addition vs Substitution Reaction
- Equilibrium Constant vs Reaction Quotient
- E1 vs E2 Reactions
- Reaction Rate vs Reaction Time
- SN1 vs E1 Reactions
- Coupled vs Uncoupled Reaction
- Synthesis Reaction vs Dissociation Reaction
- Reactants vs Products
- Homogeneous vs Heterogeneous Reactions
- Composition vs Reaction Stoichiometry