Integrated Course AIIMS-SYLLABUS Chemistry syllabus Molecularity of a reaction

Molecularity of a reaction

The molecularity of a reaction refers to the number of molecules or particles that participate as reactants in an elementary step of a chemical reaction. It is determined by the stoichiometry of that particular step. The concept of molecularity is closely related to the reaction mechanism and the rate equation of a reaction.

The molecularity of a reaction can be classified into three types:

  1. Unimolecular Reaction: A unimolecular reaction involves the decomposition or rearrangement of a single molecule. It has a molecularity of 1 because only one molecule is involved in the rate-determining step. For example, the decomposition of hydrogen peroxide (H2O2) into water and oxygen gas is a unimolecular reaction.
  2. Bimolecular Reaction: A bimolecular reaction involves the collision of two molecules in the rate-determining step. It has a molecularity of 2. Many reactions fall into this category, such as the reaction between hydrogen (H2) and iodine (I2) to form hydrogen iodide (HI).
  3. Termolecular Reaction: A termolecular reaction involves the simultaneous collision of three molecules in the rate-determining step. It has a molecularity of 3. Termolecular reactions are relatively rare due to the low probability of three molecules colliding simultaneously. An example of a termolecular reaction is the reaction between nitric oxide (NO) and ozone (O3) to form nitrogen dioxide (NO2) and oxygen gas (O2).

It’s important to note that molecularity is a concept that applies to elementary steps of a reaction mechanism, rather than the overall balanced equation of a reaction. The overall reaction can involve multiple elementary steps, each with its own molecularity.

Understanding the molecularity of a reaction helps in predicting the rate of reaction and provides insights into the reaction mechanism. It is an important concept in the field of chemical kinetics.

The concept of molecularity is primarily related to the rate of a chemical reaction. It refers to the number of molecules or particles that participate as reactants in a specific elementary step of a reaction. The molecularity of a reaction is determined by the stoichiometry of that particular step.

In general, reactions can be classified based on their molecularity as follows:

  1. Unimolecular Reactions: These reactions involve a single molecule in the rate-determining step. For example, a typical unimolecular reaction is a first-order decomposition reaction, where a single reactant decomposes into two or more products.
  2. Bimolecular Reactions: These reactions involve the collision of two molecules in the rate-determining step. Bimolecular reactions are frequently encountered in chemical kinetics. One common example is a second-order reaction where two reactant molecules combine to form a product.
  3. Termolecular Reactions: These reactions involve the simultaneous collision of three molecules in the rate-determining step. Termolecular reactions are relatively rare due to the low probability of three molecules colliding simultaneously. They are often observed under high-pressure conditions or in the presence of catalysts.

It’s important to note that molecularity is a concept related to the elementary steps of a reaction mechanism and not the overall balanced equation of a reaction. The overall reaction can involve multiple elementary steps, each with its own molecularity.

While the concept of molecularity is essential in chemical kinetics, it may not be explicitly mentioned in the syllabus for an integrated course like AIIMS. However, having a solid understanding of chemical kinetics and reaction mechanisms, including molecularity, can be beneficial in understanding and predicting reaction rates and mechanisms in the context of biochemistry and pharmacology.

What is Required AIIMS-SYLLABUS Chemistry syllabus Molecularity of a reaction

However, having a basic understanding of chemical kinetics, including the concept of molecularity, can be beneficial for a comprehensive understanding of chemistry. It can help in understanding reaction rates, reaction mechanisms, and other related concepts.

In addition to chemical kinetics, the AIIMS syllabus for chemistry generally includes topics such as:

  1. General and Physical Chemistry:
    • Atomic structure and chemical bonding
    • Thermodynamics and thermochemistry
    • Gaseous state
    • Chemical equilibrium
    • Solutions
    • Electrochemistry
    • Chemical kinetics (basic understanding)
    • Surface chemistry
  2. Organic Chemistry:
    • Basics of organic chemistry
    • Isomerism
    • Organic compounds and functional groups
    • Hydrocarbons
    • Alcohols, phenols, and ethers
    • Aldehydes and ketones
    • Carboxylic acids and their derivatives
    • Amines
    • Polymers
    • Biomolecules
    • Chemistry in everyday life

It’s important to refer to the official AIIMS syllabus or consult the specific course material provided by AIIMS for the most accurate and up-to-date information on the chemistry syllabus.

Case Study on AIIMS-SYLLABUS Chemistry syllabus Molecularity of a reaction

Determining the Molecularity of a Reaction

In a laboratory experiment, a researcher investigates the reaction between nitrogen dioxide (NO2) and carbon monoxide (CO) to form nitrogen monoxide (NO) and carbon dioxide (CO2). The researcher performs the experiment under carefully controlled conditions and measures the initial reaction rate.

To determine the molecularity of the reaction, the researcher varies the initial concentrations of NO2 and CO while keeping other factors constant. The reaction rate is observed to be directly proportional to the concentration of NO2 and CO, indicating that the reaction is second-order overall.

Based on this observation, the researcher concludes that the reaction between NO2 and CO proceeds via a bimolecular step in the rate-determining process. Therefore, the molecularity of the reaction is determined to be 2, indicating that two molecules (NO2 and CO) collide and react to form the products (NO and CO2) in the rate-determining step.

This case study illustrates how experimental observations, such as monitoring the reaction rate as a function of concentration, can provide insights into the molecularity of a reaction. However, it’s important to note that this specific case study is hypothetical and not based on any specific AIIMS syllabus or experiment.

If you require more information or specific examples related to the AIIMS syllabus for chemistry, I recommend referring to official AIIMS resources, textbooks, or consulting with your instructors for relevant case studies or practical applications.

White paper on AIIMS-SYLLABUS Chemistry syllabus Molecularity of a reaction

Molecularity refers to the number of molecules or particles that participate as reactants in an elementary step of a chemical reaction. It is determined by the stoichiometry of that particular step. Molecularity is an important concept in chemical kinetics as it helps in understanding the reaction rates and mechanisms.

The molecularity of a reaction can be classified into three main types:

  1. Unimolecular Reaction: A unimolecular reaction involves the decomposition or rearrangement of a single molecule. It has a molecularity of 1 because only one molecule is involved in the rate-determining step. For example, the decomposition of hydrogen peroxide (H2O2) into water and oxygen gas is a unimolecular reaction.
  2. Bimolecular Reaction: A bimolecular reaction involves the collision of two molecules in the rate-determining step. It has a molecularity of 2. Many reactions fall into this category, such as the reaction between hydrogen (H2) and iodine (I2) to form hydrogen iodide (HI).
  3. Termolecular Reaction: A termolecular reaction involves the simultaneous collision of three molecules in the rate-determining step. It has a molecularity of 3. Termolecular reactions are relatively rare due to the low probability of three molecules colliding simultaneously. An example of a termolecular reaction is the reaction between nitric oxide (NO) and ozone (O3) to form nitrogen dioxide (NO2) and oxygen gas (O2).

The concept of molecularity is closely related to reaction mechanisms, where a chemical reaction can occur through multiple elementary steps, each with its own molecularity. The overall reaction can have a different molecularity than the individual steps.

Understanding molecularity is essential for predicting the rate of a reaction and gaining insights into the reaction mechanism. It helps in analyzing the kinetics and stoichiometry of chemical reactions.

While I cannot provide a specific white paper on the topic, you may find research papers, textbooks, or academic articles related to chemical kinetics or reaction mechanisms that discuss the concept of molecularity in more detail. These resources can provide in-depth information and examples regarding molecularity and its applications in various chemical reactions.

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