What is the difference between molecularity of reaction and order of reaction?
We define order of reaction as the number of molecules of the reactant whose concentration changes during the chemical change. Molecularity is the number of ions or molecules that take part in the rate-determining step. It is meaningful only for simple reactions or individual steps of a complex reaction.
What is the difference between the rate of reaction and the rate constant?
2. Rate of reaction is defined as the rate of disappearance of reactant and the rate of appearance of the product while rate constant is proportionality constant between the rate of reaction and the concentration terms.
Why can’t molecularity be more than 3?
Molecularity cannot be greater than three because more than three molecules may not mutually collide with each other to have an effective collision.
What is the molecularity of a reaction Class 12?
The molecularity of a reaction is defined as the number of reacting molecules that collide simultaneously to bring about a chemical reaction. In other words, the molecularity of an elementary reaction is defined as the number of reactant molecules taking part in the reaction.
Are order and molecularity always the same for a reaction?
If the reaction is elementary reaction then order and molecularity have same value because elementary reaction proceeds in a single step.
Why can’t molecularity be zero?
Molecularity of the reaction is the number of molecules taking part in an elementary step. For this, we require at least a single molecule leading to the value of minimum molecularity of one. Hence, molecularity of any reaction can never be equal to zero.
How are order and molecularity different for complex reactions?
Molecularity is a theoretical quantity, which can be determined through reaction mechanisms. Order of reaction can be a whole number, zero, integer, or fraction. Molecularity of reaction is always in a whole number or integer, it can never be fraction or zero.
What is the difference between the rate law and the order of reaction?
The rate law is a mathematical relationship obtained by comparing reaction rates with reactant concentrations. The reaction order is the sum of the concentration term exponents in a rate law equation.
What is the relationship between the rate constant and the order of the reaction?
A rate law shows how the rate of a chemical reaction depends on reactant concentration. For a reaction such as aA → products, the rate law generally has the form rate = k[A]ⁿ, where k is a proportionality constant called the rate constant and n is the order of the reaction with respect to A.
Why the reactions of higher molecularity or order are rare?
Higher order(>3) reactions are very rare due to the Low probability of simultaneous collision of all the reacting species.
Why is molecularity above 3 rare?
The probability of more than three molecules colliding simultaneously is very small. Hence, the possibility of molecularity being more than three is very low.
Is molecularity 4 possible?
Also, there is very less probability that 4 molecules will collide simultaneously. Hence, molecularity can also not be 4.
What is the difference between order and molecularity?
Molecularity is the number of reacting species involved in simultaneous collisions in an elementary or simplest reaction. Order is an experimentally determined quantity. It may be equal to zero, positive, negative, whole number or fractional number. Molecularity is a theoretical concept, it is always in whole numbers.
Can molecularity be negative?
The value of molecularity cannot be zero, negative, fractional, infinite, and imaginary. So, it can only be a positive integer. The value of molecularity cannot be greater than 3 as more than three molecules may not mutually collide or come closer during the course of the chemical reaction.
Can the order of a reaction be fractional?
Order of Reaction It can be a whole number or a fraction. It can be noted that when the order of reaction is a fraction, the reaction is generally a chain reaction or follows some other complex mechanism. An example of a chemical reaction with a fractional reaction order is the pyrolysis of acetaldehyde.
Can the order of a reaction be zero?
The order of a reaction can be equal to zero. In such a reaction, the rate of the reaction is independent of the concentrations of the reactants. The order can be a negative integral value. In this case, the rate of the reaction is inversely affected by the concentrations of the reactants.
Can molecularity be a whole number?
Molecularity is defined as the number of molecules, atoms, or radicals that must collide simultaneously in order for the reaction to take place. It is always a whole number (except zero) and cannot be negative.
Is molecularity applicable only for elementary reactions?
Molecularity works only in the elementary reaction as it is a single reaction and the rate depends on the concentration of each molecule. And in the case of complex reactions there are many reactions involved and thus molecularity has no meaning.
Is molecularity always equal to order?
Order and molecularity may or may not be same as order of reaction is sum of power of reactant which can be determined experimentally. But molecularity is sum of stoichiometric coefficient of rate determining elementary step.
What is wrong about molecularity?
From this we can come to a conclusion the molecularity never be represented in numbers at first place and it cannot be fractional.
Can molecularity be more than 3?
The probability that three or more molecules collide to form products is very low. Hence, the molecularity of a reaction rarely exceeds 3. If BOD level of water in reservoir is less than 5 ppm it is not polluted.
Why can’t the molecularity of a reaction be zero?
Order of a reaction can be zero but molecularity of a reaction can never be equal to zero because no. of molecules colliding with each other in a reaction can never be zero.
Why molecularity has no meaning for complex reaction?
Molecularity of a reaction can be defined only for an elementary reaction because complex reaction does not take place in one single step and it is almost impossible for all the total molecules of the reactants to be in a state of encounter simultaneously.
Why are high molecularity reactions rare?
The reactions of higher order are rare because many body collisions have a very low probability. The chances of three or more molecules colliding at the same time to give product are very low.
What do you mean by zero-order reaction?
A zero-order reaction is defined as “a chemical reaction in which the rate of reaction does not change when the concentration of the reactants grows or decreases.” The rate of these reactions is always equal to the rate constant of the specific reactions since the rate is proportional to the 0th power of the …
How to find the molecularity of a reaction?
An elementary reaction is a reaction that occurs in a single step. The molecularity for an elementary reaction is calculated by adding the coefficients of the reactants, as determined by a balanced chemical equation. For example, in the reaction A + B → C, the molecularity is 2.
How to identify order of reaction?
Either the differential rate law or the integrated rate law can be used to determine the reaction order from experimental data. Often, the exponents in the rate law are the positive integers: 1 and 2 or even 0. Thus the reactions are zeroth, first, or second order in each reactant.
What is the order of reaction?
The Order of Reaction refers to the power dependence of the rate on the concentration of each reactant. Thus, for a first-order reaction, the rate is dependent on the concentration of a single species.
What is the value of molecularity and order of SN1 reaction?
What is the molecularity of Sn-1 reaction of alkyl halides? – Quora. As the name suggests, the molecularity is 1. It is a 1st-order reaction. The rate-determining step is the formation of the carbocation through the loss of the halide leaving group.
Is molecularity always a whole number?
Molecularity is defined as the number of molecules, atoms, or radicals that must collide simultaneously in order for the reaction to take place. It is always a whole number (except zero) and cannot be negative.
What is the order of reaction with respect to A and B?
The reaction between A and B is first order with respect to A and zero order with respect to B.
What is the difference between order and molecularity?
What is the molecularity of a reaction?
Are molecularity and Order of reaction identical?
Is kinetic order equal to molecularity?
Hey there, chemistry enthusiasts! So, you’ve stumbled upon the fascinating world of chemical kinetics and want to know the difference between molecularity and order of reaction. You’re in the right place! These two terms are crucial for understanding how chemical reactions proceed, and it’s easy to get them mixed up. Let’s dive in and clear up the confusion.
Molecularity
Imagine a chemical reaction as a dance. Molecularity tells us how many molecules are *actually* involved in the dance floor at the *exact moment* of the reaction. It’s a simple concept based on the elementary reaction, which is the smallest, indivisible step in a reaction mechanism.
In other words, molecularity is the number of reactant molecules that collide and transform into products in a single step of the reaction. Think of it as a specific move in the dance, where a set number of dancers are involved at that particular instant.
Here’s the catch: Molecularity can only be assigned to an elementary reaction, not a complex one. A complex reaction has multiple steps, and each step has its own molecularity.
Let’s break it down:
Unimolecular: Just one molecule participating in the dance step, like a solo performance. Think of the decomposition of nitrogen pentoxide (N2O5):
N2O5 → N2O4 + ½ O2
Bimolecular: Two molecules tangoing, like a couple’s dance. Consider the reaction between hydrogen and iodine:
H2 + I2 → 2HI
Termolecular: Three molecules getting together for a group dance. This is relatively rare, like a complicated three-person choreography. One example is the reaction between nitric oxide (NO) and oxygen:
2NO + O2 → 2NO2
Remember, molecularity is about the number of molecules colliding in a specific reaction step, not the total number of reactants or products.
Order of Reaction
Now, picture the order of reaction as the dance floor’s capacity. It tells us how the rate of the reaction changes depending on the concentration of each reactant. It’s a more practical concept, based on how the reaction *actually* happens, not just the theoretical steps.
The order of reaction is determined experimentally by measuring the rate of the reaction at different reactant concentrations. It’s not directly related to the stoichiometry of the reaction (the number of molecules in the balanced equation).
Here’s the deal:
Zero Order: The reaction rate is independent of the concentration of the reactants. It’s like having a dance floor with a fixed number of dancers, regardless of how many people are waiting outside.
First Order: The reaction rate is directly proportional to the concentration of one reactant. Imagine a dance floor where the number of dancers increases with the number of people waiting outside.
Second Order: The reaction rate depends on the concentration of two reactants or the square of one reactant. Think of a dance floor where the number of couples increases with the number of people waiting outside.
It’s important to note:
* The order of reaction can be fractional or even negative if the reaction mechanism is complex.
* The order of reaction is not necessarily equal to the molecularity of the reaction.
For example, the decomposition of ozone (O3) has an overall second-order reaction, even though the elementary step is unimolecular:
2O3 → 3O2
The decomposition of ozone is a complex reaction with multiple steps. The first step is unimolecular, but the overall reaction is second order.
Key Differences
Now, let’s summarize the key differences between molecularity and order of reaction:
| Feature | Molecularity | Order of Reaction |
| —————– | —————————————————————————– | ———————————————————————————- |
| Definition | The number of molecules participating in a single elementary reaction step | How the rate of a reaction changes with the concentration of the reactants |
| Focus | Elementary reaction steps | Overall reaction |
| Determination | Theoretical, based on the reaction mechanism | Experimental, based on the rate of the reaction at different concentrations |
| Applicability | Only to elementary reactions | Applies to both elementary and complex reactions |
| Value | Always a whole number, typically 1, 2, or 3 | Can be any number, including fractions and negative values |
In a Nutshell
Molecularity describes the choreography of a single dance move, while the order of reaction reflects the dance floor’s capacity. They are two different perspectives on the same chemical reaction, and understanding both is crucial for a complete picture.
FAQs
Q: Can the order of reaction be greater than the molecularity?
A: Yes, it’s possible. Consider a complex reaction with multiple steps. If the overall rate is determined by a slow step with a higher molecularity than the other steps, the overall reaction order might be greater than the molecularity of that step.
Q: Is the molecularity always a whole number?
A: Yes, molecularity is always a whole number because it represents the number of molecules involved in a single step of a reaction.
Q: How do I determine the order of reaction?
A: You can determine the order of reaction experimentally by measuring the rate of the reaction at different concentrations of the reactants. You can then analyze the data using different methods, such as the initial rate method or the integrated rate law method.
Q: What is the difference between a rate constant and a rate law?
A: The rate constant (k) is a proportionality constant that relates the rate of a reaction to the concentrations of the reactants. It’s a specific value for a given reaction at a given temperature.
The rate law, on the other hand, is an equation that expresses the rate of a reaction as a function of the concentrations of the reactants. It includes the rate constant and the orders of the reaction with respect to each reactant.
Q: What are some examples of reactions with different orders?
A:
Zero order: Decomposition of nitrogen dioxide (NO2) on a hot platinum surface.
First order: Decomposition of hydrogen peroxide (H2O2).
Second order: Reaction between hydrogen and iodine (H2 + I2 → 2HI).
Third order: Reaction between nitric oxide (NO) and oxygen (2NO + O2 → 2NO2).
Q: What are some real-life applications of molecularity and order of reaction?
A: Molecularity and order of reaction are essential for understanding various chemical processes, including:
Catalysis: Understanding how catalysts affect the rate of reactions by influencing the molecularity of individual steps.
Enzyme kinetics: Determining the reaction mechanisms of enzymes and their rates of activity.
Environmental chemistry: Predicting the rates of atmospheric reactions, such as ozone depletion.
Industrial processes: Optimizing chemical production processes by controlling the rates of reactions.
I hope this explanation has cleared up any confusion between molecularity and order of reaction. Keep exploring the fascinating world of chemical kinetics, and remember, understanding these concepts is key to unlocking the secrets of how reactions happen!
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