16.1.1 Order of Reaction

Cards (48)

What is the order of reaction with respect to a reactant defined as?
Power in rate equation
The overall order of a reaction is the sum of the orders with respect to each reactant
The overall order of a reaction is calculated by multiplying the individual orders of reactants.
False
If $\text{Rate} =$ $k[A]^{2}[B]^{0}$ , what is the overall order of the reaction? 
2
Match the order of reaction with its effect on reaction rate when concentration doubles:
Zero Order ↔️ No change in rate
First Order ↔️ Rate doubles
Second Order ↔️ Rate quadruples
A zero-order reaction proceeds at a constant rate, regardless of reactant concentration
The rate of a first-order reaction is halved when the reactant concentration is halved.
What is the rate equation for a zero-order reaction?
$\text{Rate} =$ $k$
The decomposition of ammonia on a platinum surface is an example of a zero-order reaction
The order of reaction indicates how the reaction rate changes with changes in the volume of reactants.
False
How is the overall order of a reaction calculated?
Sum of individual orders
Match the term with its definition:
Order of Reaction ↔️ Power in rate equation
Rate Equation ↔️ Relates rate to concentrations
Overall Order ↔️ Sum of individual orders
In a zero-order reaction, the rate doubles when the reactant concentration doubles.
False
The rate of a first-order reaction is directly proportional to the concentration of the reactant
What does the order of reaction determine?
How reaction rate changes
In a first-order reaction, the rate doubles when the concentration doubles.
What is the characteristic of a zero-order reaction regarding reactant concentration?
Independent of concentration
What type of reaction has a rate directly proportional to the concentration of the reactant?
First-order reaction
What happens to the rate of a second-order reaction if the reactant concentration is doubled?
It quadruples
Zero-order reactions occur at a constant rate regardless of reactant concentration.
Match the order of reaction with its characteristic:
Zero Order ↔️ Constant rate
First Order ↔️ Rate proportional to [A]
Second Order ↔️ Rate proportional to [A]^{2}
Give an example of a zero-order reaction.
Decomposition of ammonia on platinum
What is the rate equation for a first-order reaction?
$\text{Rate} =$ $k[A]$
In a first-order reaction, the rate doubles when the reactant concentration doubles.
Give an example of a first-order reaction.
Radioactive decay of polonium-210
In a second-order reaction, the rate quadruples when the concentration doubles.
What is an example of a second-order reaction?
Reaction between NO and ozone
Steps to determine the order of reaction experimentally using the method of initial rates:
1️⃣ Vary reactant concentrations
2️⃣ Measure initial rates
3️⃣ Compare rate changes with concentration changes
4️⃣ Solve rate equation for the exponent
First-order reactions yield straight lines when $\ln[A]$ is plotted against time.
If doubling the concentration of a reactant quadruples the reaction rate, what is the order of the reaction with respect to that reactant?
Second order
What three variables are plotted against time to determine the order of a reaction using the graphical method?
$[A]$ , $\ln[A]$ , $\frac{1}{[A]}$
A reaction is second order with respect to reactant A
The order of reaction indicates how the reaction rate changes with changes in reactant concentration.
What is the overall order of a reaction if $m =$ $2$ and $n =$ $1$ ? 
3
There are three primary types of reaction orders: zero order, first order, and second order.
Match the order of reaction with its effect on the rate of reaction.
Zero Order ↔️ Rate is independent of concentration.
First Order ↔️ Rate doubles when concentration doubles.
Second Order ↔️ Rate quadruples when concentration doubles.
Zero-order reactions proceed at a constant rate regardless of reactant concentration.
What is an example of a zero-order reaction?
Decomposition of ammonia on platinum
The rate equation for a first-order reaction is $\text{Rate} =$ $k[A]$ , where $[A]$ is the concentration of the reactant.
The half-life of a first-order reaction is constant and depends only on the rate constant.