Category: Chemistry

No.	Topics.	No.	Topics.
1.	ALCOHOLS AND PHENOLS	2.	ALDEHYDES & KETONES
3.	ALKYL HALIDES	4.	ATONTIC STRUCTURE
5.	CARBOXYLIC ACIDS	6.	CHEMICAL BONDING
7.	CHEMISTRY OF HYDROCARBONS	8.	CHETVI ICAL EQUI LIBIRIUM
9.	ELECTROCHE]VIISTRY	10.	FUNDAMENTAL CONCEPTS OF CHEMISTRY
11.	FUNDAMENTAL PRICIPLES OF ORGANIC CHEMISTRY	12.	GASES
13.	INDUSTRIAL CHEMISTRY	14.	Limiting and Excess Reactants
15.	LIQUIDS	16.	Macro Mulecule
17.	Moles and Avogadro’s Numbers	18.	REACTION KINETICS
19.	S AND P BLOCK ELEMNETS	20.	SOLIDS
21.	THERMOCHEMISTRY & ENERGETICS OF CHEMICAL REACTIONS	22.	TRANSITION ELEMENTS
23.	Yield

The slowest step in a reaction mechanism is referred to as the:

Elementary step.
Overall step.
Rate-determining step.
Initiation step.

A plot of [A]1? versus time yields a straight line with a positive slope. This indicates the reaction is:

Zero-order.
First-order.
Second-order.
Third-order.

For a certain reaction, if the rate constant ‘k’ has units of s?1, the order of the reaction is:

Zero-order.
First-order.
Second-order.
Third-order.

The decomposition of hydrogen peroxide is often catalyzed by MnO2? (manganese dioxide). This represents a case of:

Homogeneous catalysis.
Enzyme catalysis.
Heterogeneous catalysis.
Autocatalysis.

When the temperature of a reaction is increased, the kinetic energy of reactant molecules:

Decreases, leading to fewer collisions.
Increases, leading to fewer collisions.
Increases, leading to a higher proportion of effective collisions.
Remains unchanged.

For a reaction with the rate law: Rate = k[A], if the concentration of A is reduced by half, the rate will:

Be reduced by half.
Be reduced by a quarter.
Remain unchanged.
Double.

A reaction has the rate law: Rate = k[A]2[B]0. The overall order of the reaction is:

Zero
First
Second
Third

In a homogeneous catalysis, the catalyst exists in:

A solid state.
A liquid state.
The same phase as the reactants.
A different phase from the reactants.

Enzymes, acting as biological catalysts, are distinct from inorganic catalysts primarily due to their:

High molecular weight.
Protein nature and high specificity.
Ability to lower activation energy.
Reusability in reactions.

A catalyst generally increases the rate of a chemical reaction by:

Increasing the kinetic energy of reacting molecules.
Shifting the equilibrium towards the products.
Providing an alternative reaction pathway with a lower activation energy.
Increasing the collision frequency between reactant molecules.

The Arrhenius equation relates the rate constant (k) to temperature. A higher activation energy implies that the reaction rate is:

Less sensitive to temperature changes.
More sensitive to temperature changes.
Independent of temperature changes.
Always faster at lower temperatures.

The half-life of a first-order reaction:

Increases with increasing initial concentration.
Decreases with increasing initial concentration.
Is independent of the initial concentration.
Is inversely proportional to the rate constant.

Collision theory states that for a reaction to occur, colliding molecules must possess a minimum amount of energy, known as:

Kinetic energy.
Potential energy.
Activation energy.
Bond energy.

If a reaction is first-order with respect to reactant A, doubling the initial concentration of A would:

Quadruple the reaction rate.
Halve the reaction rate.
Double the reaction rate.
Not affect the reaction rate.

For a zero-order reaction, a plot of reactant concentration versus time would yield:

A straight line with a positive slope.
A curved line.
A straight line with a negative slope.
A horizontal line.

The rate constant (k) for a chemical reaction:

Always remains constant with temperature change.
Changes with changes in reactant concentration.
Is independent of reactant concentration but changes with temperature.
Determines the initial rate only.

Increasing the concentration of a reactant generally enhances the reaction rate primarily because it leads to:

A decrease in activation energy.
A greater frequency of effective collisions.
A shift in the equilibrium position.
An increase in the temperature of the system.

A reaction takes place in a closed container. If the surface area of a solid reactant is doubled, the reaction rate will likely:

Remain unchanged.
Halve.
Increase, but not necessarily double.
Decrease.

For a reaction A?B, the instantaneous rate at a specific time is determined by:

The total change in concentration from start to end.
The slope of the tangent to the concentration vs. time curve at that point.
The initial concentration of reactant A.
The rate constant of the reaction.

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