How Fast? The Rate of Chemical Change (DP IB Chemistry)

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  • Define rate of reaction.

    Rate of reaction is the speed at which a chemical reaction takes place, expressed as the change in concentration of a particular reactant or product per unit time.

  • What are the typical units for rate of reaction?

    Typical units for rate of reaction are mol dm-3 s-1.

  • True or False?

    The rate of reaction is always a negative value.

    False.

    The rate of reaction is always a positive value.

  • What is the equation for calculating rate of reaction?

    The equation for calculating rate of reaction is:

    Rate of reaction = change in concentration of reactants or products / time

  • True or False?

    The steeper the gradient on a rate of reaction graph, the slower the rate of reaction.

    False.

    The steeper the gradient on a rate of reaction graph, the quicker the rate of reaction.

  • How can you find the rate of reaction at a particular time on a graph?

    You can find the rate of reaction at a particular time by calculating the gradient of the tangent to the curve at that time.

  • What does the equation gradient = Δy / Δx represent in rate of reaction graphs?

    The equation gradient = Δy / Δx represents the calculation of the gradient of the tangent to the curve, which gives the rate of reaction at a specific time.

  • True or False?

    When drawing a tangent to a rate of reaction curve, you should make the triangle small to minimize errors.

    False.

    When drawing a tangent to a rate of reaction curve, you should make the triangle large to minimize errors of precision.

  • Using the tangent, determine the rate of reaction for:

    Graph giving the required information to calculate the rate of reaction at a specific time in a chemical reaction

    The rate of reaction is 40 / 22 = 1.82 cm3 s-1.

  • What are three commonly used techniques for measuring rates of reaction?

    Three commonly used techniques for measuring rates of reaction are:

    • Mass loss

    • Gas production

    • Colorimetry.

  • What is colorimetry?

    Colorimetry is a technique that measures the amount of light that passes through a solution to determine the concentration of a colored species.

  • What is the limitation of using colorimetry to monitor the formation of colored precipitates?

    Colorimetry cannot be used to monitor the formation of colored precipitates as the light will be scattered or blocked by the precipitate.

  • Why is hydrogen gas not suitable for measuring reaction rates using mass loss?

    Hydrogen gas is not suitable for measuring reaction rates using mass loss due to its low molecular mass, which means that the mass loss is negligible.

  • What is a gas syringe used for in measuring rates of reaction?

    A gas syringe is used to trap and measure the volume of gas produced over time in a reaction.

  • Define quenching in the context of measuring reaction rates.

    Quenching is the process of deliberately stopping a reaction and taking samples at regular intervals to allow the concentration to be determined by titration.

  • How can conductivity be used to measure the rate of a reaction?

    Conductivity can be used to measure the rate of a reaction by monitoring changes in the electrical conductivity of the reaction mixture over time, as the concentration of ions changes.

  • What is a clock reaction?

    A clock reaction is a non-continuous method for measuring reaction rates in which the time taken to reach a fixed point is measured.

  • Draw a graph to show how light intensity changes over time, as a coloured solution reacts to form a colourless solution.

    A graph to show how light intensity changes over time, as a coloured solution reacts to form a colourless solution is:

    A graph to show how light intensity changes over time, as a coloured solution reacts to form a colourless solution
  • True or False?

    Gas loss is an appropriate method to measure the rate of reaction for the reaction of a metal carbonate with acid.

    True.

    Gas loss is an appropriate method to measure the rate of reaction for the reaction of a metal carbonate with acid because the molecular mass of the carbon dioxide produced will give a significant / appropriate change of mass.

  • Draw a graph to show how the mass of the reaction mixture changes over time, as a metal carbonate reacts with an acid.

    A graph to show how the mass of the reaction mixture changes over time, as a metal carbonate reacts with acid is:

    A graph to show how mass changes changes over time, as a metal carbonate reacts with acid
  • True or False?

    The volume of gas produced is an appropriate method to measure the rate of reaction for the reaction of a metal with acid.

    True.

    The volume of gas produced is an appropriate method to measure the rate of reaction for the reaction of a metal with acid.

  • Draw a graph to show how the volume of gas produced changes over time, as a metal reacts with an acid.

    A graph to show how the volume of gas produced changes over time, as a metal reacts with an acid is:

    A graph to show how the volume of gas produced changes over time, as a metal reacts with an acid
  • What is collision theory?

    Collision theory explains how chemical reactions occur based on collisions between reactant particles.

  • According to collision theory, what are the four factors that influence the rate of a chemical reaction?

    According to collision theory, the four factors that influence the rate of a chemical reaction according to collision theory are:

    • Collision frequency,

    • Collision energy,

    • Activation energy,

    • Collision geometry.

  • Define collision frequency.

    Collision frequency is the number of collisions between particles per unit time in a system.

  • What is collision energy?

    Collision energy is the combined energy of two colliding particles.

  • True or False?

    All collisions between reactant particles result in a chemical reaction.

    False.

    Not all collisions between reactant particles result in a chemical reaction. Most collisions are unsuccessful.

  • What is an unsuccessful collision?

    An unsuccessful collision is when particles collide in the wrong orientation or when they don't have enough energy and bounce off each other without causing a chemical reaction.

  • What is a successful collision?

    A successful collision is where the particles collide in the correct orientation and with sufficient energy for a chemical reaction to occur.

  • True or False?

    Collision geometry is more important for small, simple molecules.

    False.

    Collision geometry becomes increasingly important in large complex biomolecules such as proteins and carbohydrates.

  • What determines the rate of reaction according to collision theory?

    The rate of reaction depends on the number of successful collisions that happen per unit time.

  • State three ways that the collision frequency of a given system can be changed.

    Three ways that the collision frequency of a given system can be changed include:

    • Changing the concentration of the reactants

    • Changing the total pressure

    • Changing the temperature

    • Changing the surface area of the reacting particles

  • How can the activation energy of a chemical reaction be changed?

    The activation energy of a chemical reaction can be changed by the addition of a catalyst.

  • True or False?

    Most collisions do not result in a reaction because they do not have correct collision geometry.

    False.

    Most collisions do not result in a reaction because they do not reach the activation energy / have energy greater than or equal to the activation energy.

  • True or False?

    Increasing concentration increases the number of collisions per second.

    True.

    Increasing the concentration of a solution will increase the number of reactant particles in a given volume, allowing more frequent and successful collisions per second.

  • How does increasing temperature increase the rate of reaction?

    Increasing temperature increases the kinetic energy of the particles, leading to more frequent and successful collisions with energy greater than the activation energy.

  • How does increasing surface area affect the rate of reaction?

    Increasing the surface area of a solid reactant increases the rate of reaction because more surface area is exposed to the other reactant, producing a higher number of collisions per second.

  • State the relationship between the number of collisions and the number of particles.

    The number of collisions is proportional to the number of particles present.

  • What are the five factors affecting the rate of reaction?

    The five factors affecting the rate of reaction are:

    • Concentration,

    • Pressure,

    • Temperature,

    • Surface area,

    • The use of catalysts.

  • True or False?

    An increase in pressure only affects reactions involving liquids.

    False.

    An increase in pressure affects reactions involving gases, having the same effect as an increased concentration of solutions.

  • Define catalyst in terms of its effect on reaction rate.

    A catalyst is a substance that provides the reactants with an alternative reaction pathway which is lower in activation energy than the uncatalyzed reaction, increasing the rate of reaction.

  • True or False?

    A catalyst is chemically changed at the end of a reaction.

    False.

    A catalyst does not undergo permanent chemical change and is chemically unchanged at the end of the reaction.

  • How can surface area be increased to affect reaction rate?

    Surface area can be increased by decreasing the size of the reactant, e.g. from large pieces to a fine powder.

  • What are two ways increasing temperature affects reaction rate?

    Increasing temperature affects reaction rate by:

    • Making particles move faster, leading to more frequent collisions,

    • Increasing the proportion of particles with activation energy or more.

  • How do catalysts reduce the environmental impact of industrial processes?

    Catalysts reduce the environmental impact of industrial processes by reducing energy requirements, reducing waste products, and increasing the selectivity of processes.

  • What is the symbol for activation energy?

    The symbol for activation energy is Ea.

  • How is activation energy shown on an energy profile diagram?

    Activation energy is the initial increase in energy, from the reactants to the peak of the curve.

  • Define activation energy.

    Activation energy (Ea) is the minimum amount of energy that reactant particles need to overcome for a reaction to take place.

  • In exothermic reactions, how does the energy of reactants compare to products?

    In exothermic reactions, the reactants are higher in energy than the products.

  • If a reversible reaction is exothermic in the forward direction, how can the activation energy of the reverse reaction be calculated?

    If a reversible reaction is exothermic in the forward direction, the activation energy of the reverse reaction is:

    Ea (reverse) = ∆H + Ea (forward)

  • True or False?

    The activation energy is always lower than the enthalpy change of the reaction.

    False.

    The activation energy can be higher or lower than the enthalpy change of the reaction, depending on whether the reaction is exothermic or endothermic.

  • If a reversible reaction is endothermic in the forward direction, how can the activation of the reverse reaction be calculated?

    If a reversible reaction is endothermic in the forward direction, the activation of the reverse reaction is:

    Ea (reverse) = Ea (forward) - ∆H

  • True or False?

    In endothermic reactions, the reactants are lower in energy than the products.

    True.

    In endothermic reactions, the reactants are lower in energy than the products.

  • What are energy profiles?

    Energy profiles are graphical representations of the relative energies of the reactants and products in chemical reactions.

  • How does an energy profile show that a reaction is exothermic?

    An energy profile shows that a reaction is exothermic because the energy of the products is lower than the energy of the reactants.

  • True or False?

    The difference in height between the energy of reactants and products on an energy profile represents the overall enthalpy change of a reaction.

    True.

    The difference in height between the energy of reactants and products on an energy profile represents the overall enthalpy change of a reaction.

  • How does an energy profile show that a reaction is endothermic?

    An energy profile shows that a reaction is endothermic because the the energy of the products is higher than the energy of the reactants.

  • What information is shown on the y-axis of an energy profile?

    The energy of the reactants and products is displayed on the y-axis of an energy profile.

  • What information is shown on the x-axis of an energy profile?

    The progress of the reaction is shown on the x-axis of an energy profile.

  • What does an downwards arrow on an energy profile indicate?

    A downwards arrow on an energy profile indicates an exothermic reaction.

  • What does an upwards arrow on an energy profile indicate?

    An upwards arrow on an energy level diagram indicates an endothermic reaction.

  • True or False?

    Catalysts are chemically altered by the end of the reaction.

    False.

    Catalysts remain chemically unaltered by the end of the reaction.

  • What are the two types of catalysts?

    The two types of catalysts are homogeneous catalysts and heterogeneous catalysts.

  • Define homogeneous catalyst.

    A homogeneous catalyst is a catalyst that is in the same phase as the reactants.

  • Define heterogeneous catalyst.

    A heterogeneous catalyst is a catalyst that is in a different phase to the reactants.

  • What are enzymes in the context of catalysis?

    Enzymes are biological catalysts that control many biochemical reactions within cells.

  • True or False?

    Transition metals are often used as catalysts due to their ability to form only one stable oxidation state.

    False.

    Transition metals are often used as catalysts due to their ability to form more than one stable oxidation state.

  • How do catalysts affect the activation energy of a reaction?

    Catalysts lower the activation energy of a reaction by providing an alternative reaction pathway.

  • Draw an energy profile diagram to show the effect of a catalyst on an exothermic chemical reaction, including:

    • Energy levels for reactants and products

    • Enthalpy change,

    • Activation energy for the catalysed and uncatalysed routes

    The energy profile diagram to show the effect of a catalyst on an exothermic chemical reaction is:

    Exothermic energy profile comparing catalyzed and uncatalyzed reactions.
  • True or False?

    Catalysts change the overall enthalpy change of a reaction.

    False.

    Catalysts do not change the overall enthalpy change of a reaction; they only lower the activation energy.

  • Draw an energy profile diagram to show the effect of a catalyst on an endothermic chemical reaction, including:

    • Energy levels for reactants and products

    • Enthalpy change,

    • Activation energy for the catalysed and uncatalysed routes

    The energy profile diagram to show the effect of a catalyst on an endothermic chemical reaction is:

    Endothermic energy profile comparing catalyzed and uncatalyzed reactions.
  • What is a Maxwell-Boltzmann distribution curve?

    A Maxwell-Boltzmann distribution curve is a graph that shows the distribution of energies of particles in a sample at a certain temperature.

  • What does the peak of a Maxwell-Boltzmann distribution curve represent?

    The peak of a Maxwell-Boltzmann distribution curve represents the most probable energy of a particle, sometimes written as EMP or EMP.

  • How does increasing temperature affect a Maxwell-Boltzmann distribution curve?

    Increasing temperature causes the Maxwell-Boltzmann distribution curve to flatten and the peak to shift to the right.

  • True or False?

    An increase in temperature results in a higher proportion of particles with energy greater than the activation energy.

    True.

    An increase in temperature results in a higher proportion of particles with energy greater than the activation energy.

  • How does a catalyst affect the Maxwell-Boltzmann distribution curve?

    A Maxwell-Boltzmann curve with the area under the curve to the right of Ea shaded

    A catalyst does not change the Maxwell-Boltzmann distribution curve.

    It lowers the activation energy, resulting in a greater proportion of molecules having sufficient energy for a successful collision.

  • What does the shaded area under the Maxwell-Boltzmann distribution curve represent?

    A Maxwell-Boltzmann curve with the area under the curve to the right of Ea shaded

    The shaded area represents the number of particles with energy greater than the activation energy.

    A Maxwell-Boltzmann curve with the area under the curve to the right of Ea shaded
  • True or False?

    The Maxwell-Boltzmann distribution curve starts at a point above the origin and never touches the x-axis.

    False.

    The Maxwell-Boltzmann distribution curve must start at the origin and it approaches, but never touches the x-axis.

  • How does an increase in temperature affect the rate of reaction according to the Maxwell-Boltzmann distribution?

    An increase in temperature increases the rate of reaction by:

    1. Causing more effective collisions as particles have more kinetic energy

    2. Increasing the proportion of molecules with (kinetic) energy greater than the activation energy.

  • Draw a Maxwell-Boltzmann distribution for a chemical reaction, including:

    • Labelled axes,

    • Most probable energy, Emp,

    • Activation energy, Ea.

    A Maxwell-Boltzmann distribution for a chemical reaction, including labelled axes, most probable energy, Emp, and activation energy, Ea, is:

    A Maxwell-Boltzmann distribution curve with labelled axes and the most probable energy and activation energy labelled
  • In this Maxwell-Boltzmann distribution curve with a catalyst, what does the shaded area represent?

    A Maxwell-Boltzmann distribution curve with a highlighted section between Ea(catalysed) and Ea(uncatalysed)

    In the Maxwell-Boltzmann distribution curve with a catalyst, the shaded area represents the extra particles which have enough energy to react when a catalyst is present compared to without a catalyst.

  • What is the rate equation?

    The rate equation is an expression that shows how the rate of a reaction depends on the concentration of reactants and a rate constant.

  • Define the term rate constant.

    The rate constant (k) is a proportionality constant that links the rate of reaction to reactant concentrations.

  • True or False?

    The rate equation can be determined from the balanced chemical equation.

    False.

    The rate equation can only be determined experimentally, not from the balanced chemical equation.

  • What does the overall order of a reaction mean?

    The overall order of a reaction is the sum of the powers of the reactant concentrations in the rate equation.

  • Define zero order.

    Zero order means that the rate of reaction is independent of the concentration of a particular reactant. So, changing the concentration will have no effect on the rate of reaction.

  • What is a first order?

    First order is where the rate of reaction is directly proportional to the concentration of a single reactant. So, doubling the concentration will have double the rate of reaction.

  • Define second order.

    Second order is where the rate of reaction is directly proportional to the square of the concentration of a single reactant. So, doubling the concentration will have increase the rate of reaction by a factor of 4.

  • How is the rate of reaction typically measured?

    The rate of reaction is typically measured by:

    • Decrease in the concentration of a reactant over time

    • Increase in the concentration of a product over time.

  • What are the units for the rate of reaction?

    The units for the rate of reaction are mol dm⁻³ s⁻¹.

  • Write the rate equation for a reaction that is first order with respect to [A] and zero order with respect to [B].

    The rate equation for a reaction that is first order with respect to [A] and zero order with respect to [B] is:

    Rate = k [A]

  • True or False?

    The rate equation includes all reactants from the balanced chemical equation.

    False.

    The rate equation only includes reactants that affect the rate of reaction, which may not be all reactants from the balanced chemical equation.

  • When the concentration of A changes from 0.15 mol dm-3 to 0.30 mol dm-3, the rate of reaction changes from 1.2 x 10-2 mol dm-3 s-1 to 4.8 x 10-2 mol dm-3 s-1.

    What is the order with respect to A?

    Concentration change from 0.15 mol dm-3 to 0.30 mol dm-3

    • Concentration doubles

    Rate of reaction change from 1.2 x 10-2 mol dm-3 s-1 to 4.8 x 10-2 mol dm-3 s-1

    • Rate of reaction increases by a factor of 4

    Therefore, A is second order.

  • The rate equation for a chemical reaction is:

    Rate = k [A]2 [B]

    What is the overall order of the reaction?

    The overall order of reaction is 2 + 1 = 3.

  • The rate equation for a chemical reaction is:

    Rate = k [A]2 [B]

    If the concentration of both chemicals is doubled, what is the effect on the rate of reaction?

    Rate = k [A]2 [B]

    If the concentration of both chemicals is doubled, the rate of reaction increases by a factor of 8.

  • True or False?

    3A + 2B → C + 2D

    The rate equation for the reaction is k [A]3 [B]2.

    False.

    3A + 2B → C + 2D

    The rate equation cannot be taken directly from the balanced equation.

  • Write the rate equation for a reaction that is zero order with respect to [A] and second order with respect to [B].

    The rate equation for a reaction that is zero order with respect to [A] and second order with respect to [B] is:

    Rate = k [B]2

  • True or False?

    Products and catalysts do not feature in rate equations.

    False.

    Products and catalysts may feature in rate equations.

    Intermediates do not feature in rate equations.

  • The rate equation for a chemical reaction is:

    Rate = k [A] [B]

    If the concentration of both chemicals is halved, what is the effect on the rate of reaction?

    Rate = k [A] [B]

    If the concentration of both chemicals is halved, the rate of reaction decreases by a factor of 4.

  • When [B] changes from 1.2 x 10-2 mol dm-3 to 4.8 x 10-2 mol dm-3, the rate of reaction does not change.

    What is the order with respect to B?

    A change in [B] that does not result in an increase/decrease in the rate of reaction means that the B is zero order.

  • What is the order of reaction with respect to a reactant?

    The order of reaction with respect to a reactant is the power to which the concentration of that reactant is raised in the rate equation.

  • What is a concentration-time graph?

    A concentration-time graph is a graph showing how the concentration of a reactant or product changes over time during a reaction.

  • What does a horizontal line on a rate-concentration graph indicate?

    A horizontal line on a rate-concentration graph indicates a zero-order reaction with respect to that reactant.

  • True or False?

    A first-order reaction shows a straight diagonal line on a rate-concentration graph.

    True.

    A first-order reaction shows a straight diagonal line on a rate-concentration graph.

  • What shape does a second-order reaction show on a rate-concentration graph?

    A second-order reaction shows a curved line on a rate-concentration graph.

  • What is a rate-concentration graph?

    A rate-concentration graph is a graph showing how the rate of a reaction changes with the concentration of a reactant.

  • What does the shape of a concentration-time graph indicate about the reaction order?

    The shape of a concentration-time graph indicates the order of the reaction:

    • A straight line for zero-order

    • A shallow curve for first-order

    • A steep curve for second-order.

  • What information can be derived from the gradient of a rate-concentration graph?

    The gradient of a rate-concentration graph can provide information about the order of the reaction with respect to the reactant being studied.

  • How can reaction orders be determined experimentally?

    Reaction orders can be determined experimentally by measuring initial rates at different reactant concentrations and analysing the relationship between rate and concentration.

  • Draw the expected graph for a first order rate-concentration graph.

    A first order rate-concentration graph is:

    A first order rate-concentration graph
  • Draw the expected graph for a second order concentration-time graph.

    A second order concentration-time graph is:

    A second order concentration-time graph
  • Draw the expected graph for a zero order concentration-time graph.

    A zero order concentration-time graph is:

    A zero order concentration-time graph
  • What is the rate constant, k?

    The rate constant, k, is a proportionality constant in the rate equation that relates the rate of reaction to reactant concentrations.

  • True or False?

    The rate constant remains constant if only the concentration of reactants is changed.

    True.

    The rate constant remains constant if only the concentration of reactants is changed.

  • What factors can change the value of the rate constant?

    The value of the rate constant can be changed by altering the temperature or using a catalyst.

  • How does increasing temperature affect the rate constant?

    Increasing temperature increases the value of the rate constant.

  • What is the relationship between the rate constant and the rate of reaction?

    The rate constant is directly proportional to the rate of reaction.

  • Define activation energy in relation to the rate constant.

    Activation energy is the minimum energy required for a reaction to occur, and it affects the value of the rate constant.

  • True or False?

    The units of the rate constant depend on the overall order of the reaction.

    True.

    The units of the rate constant depend on the overall order of the reaction.

  • What are the units of the rate constant for a zero-order reaction?

    The units of the rate constant for a zero-order reaction are mol dm⁻³ s⁻¹.

  • What are the units of the rate constant for a first-order reaction?

    The units of the rate constant for a first-order reaction are s⁻¹.

  • What are the units of the rate constant for a second-order reaction?

    The units of the rate constant for a second-order reaction are mol⁻¹ dm³ s⁻¹.

  • What is a reaction mechanism?

    A reaction mechanism is the sequence of elementary steps that describe how a chemical reaction occurs at the molecular level.

  • Define elementary step.

    An elementary step is a single, simple step in a reaction mechanism that involves a small number of particles.

  • What is an intermediate in a reaction mechanism?

    An intermediate is a species produced in one elementary step and consumed in a subsequent step of a reaction mechanism.

  • True or False?

    The sum of elementary steps must equal the overall reaction equation.

    True.

    The sum of elementary steps must equal the overall reaction equation.

  • What is the rate-determining step in a reaction mechanism?

    The rate-determining step is the slowest step in a reaction mechanism, which controls the overall rate of the reaction.

  • How does the rate-determining step relate to the rate equation?

    The rate-determining step determines which reactants appear in the rate equation and their respective orders.

  • True or False?

    Chemical kinetics can prove a proposed reaction mechanism.

    False.

    Chemical kinetics can suggest or disprove a reaction mechanism, but it cannot prove one.

  • What information is needed to predict a possible reaction mechanism?

    To predict a possible reaction mechanism, you need:

    • The overall reaction equation

    • The experimentally determined rate equation.

  • What is the overall reaction equation, using the following proposed elementary steps?

    Step 1:   NO2 + NO2 → NO3 + NO

    Step 2:   NO3 + CO → NO2 + CO2 

    Step 1:   NO2 + NO2 → NO3 + NO

    Step 2:   NO3 + CO → NO2 + CO2 

    The overall reaction equation, using the proposed elementary steps, is:

    NO2 + CO → NO + CO2

  • True or False?

    The proposed elementary step for a one-step reaction mechanism is the same as the overall reaction equation.

    True.

    The proposed elementary step for a one-step reaction mechanism is the same as the overall reaction equation.

  • True or False?

    2NO2 + F2 → 2NO2F Rate = k [NO2] [F2]

    A possible mechanism for the above reaction could include the following elementary steps:

    NO2 + F2 → NO2F + F

    NO2 + F → NO2F

    True.

    2NO2 + F2 → 2NO2F Rate = k [NO2] [F2]

    A possible mechanism for the above reaction could include the following elementary steps:

    NO2 + F2 → NO2F + F

    NO2 + F → NO2F

    The elementary steps combine, losing F on both sides, to give the overall equation.

  • 2N2O5 + O2 → 4NO2 + O2 Rate = k [N2O5]

    Explain which of the following elementary steps is the rate-determining step.

    Step 1: N2O5 → 2NO2 + O

    Step 2: N2O5 + O → 2NO2 + O2

    2N2O5 + O2 → 4NO2 + O2 Rate = k [N2O5]

    Step 1: N2O5 → 2NO2 + O

    Step 2: N2O5 + O → 2NO2 + O2

    Step 1 is the rate-determining step because it is the elementary step containing the species and stoichiometry that match the rate equation.

  • What is a transition state in a chemical reaction?

    A transition state is an unstable, high-energy state formed temporarily when reacting molecules collide, corresponding to the activation energy.

  • True or False?

    The transition state always has lower energy than both reactants and products.

    False.

    The transition state always has higher energy than both reactants and products.

  • How is the rate-determining step represented on an energy profile diagram?

    The rate-determining step is represented by the highest activation energy barrier on an energy profile diagram for a multi-step reaction.

  • True or False?

    In a multi-step reaction, the first elementary step always has the highest activation energy.

    False.

    In a multi-step reaction, the first elementary step does not always have the highest activation energy.

    The rate-determining step has the highest activation energy.

  • What information can be derived from the overall shape of an energy profile diagram?

    The overall shape of an energy profile diagram can indicate whether a reaction is exothermic or endothermic.

  • True or False?

    The activation energy is always positive on an energy profile diagram.

    True.

    The activation energy is always positive on an energy profile diagram, representing the energy barrier that must be overcome for the reaction to proceed.

  • Define molecularity.

    Molecularity is the number of reacting particles taking part in an elementary step of a reaction.

  • In terms of molecularity, state the three classes of chemical reaction.

    In terms of molecularity, the three classes of chemical reaction are:

    • Unimolecular

    • Bimolecular

    • Termolecular.

  • What is the difference between a unimolecular and a bimolecular reaction?

    A unimolecular reaction involves one reactant particle in an elementary step, while a bimolecular reaction involves two reactant particles.

  • How many reactants are involved in a termolecular elementary step?

    Three reactants are involved in a termolecular elementary step.

  • 2N2O5 + O2 → 4NO2 + O2 Rate = k [N2O5]

    Step 1: N2O5 → 2NO2 + O

    Step 2: N2O5 + O → 2NO2 + O2

    State the molecularity of elementary step 1.

    2N2O5 + O2 → 4NO2 + O2 Rate = k [N2O5]

    Step 1: N2O5 → 2NO2 + O

    Step 2: N2O5 + O → 2NO2 + O2

    Step 1 is unimolecular.

  • 2N2O5 + O2 → 4NO2 + O2 Rate = k [N2O5]

    Step 1: N2O5 → 2NO2 + O

    Step 2: N2O5 + O → 2NO2 + O2

    Explain the molecularity of elementary step 2.

    2N2O5 + O2 → 4NO2 + O2 Rate = k [N2O5]

    Step 1: N2O5 → 2NO2 + O

    Step 2: N2O5 + O → 2NO2 + O2

    Step 2 is bimolecular, because there are two reactants in elementary step 2.

  • Explain why termolecular elementary steps are not common in reaction mechanisms.

    Termolecular elementary steps are not common in reaction mechanisms because it is unlikely that three different reactants will collide in the correct orientations and with sufficient energies to react.

  • The Arrhenius equation is k = Ae(-Ea/RT)

    What do the terms k, A, Ea, R and T represent in the Arrhenius equation?

    In the Arrhenius equation, the terms k, A, Ea, R and T represent:

    • k is the rate constant

    • A is the Arrhenius factor

    • Ea is the activation energy

    • R is the gas constant

    • T is the temperature in Kelvin.

  • What does the Arrhenius factor, A, represent?

    The Arrhenius factor, A, represents the frequency of collisions with proper orientations for a reaction to occur.

  • True or False?

    The activation energy, Ea, in the Arrhenius equation is always constant for a given reaction.

    True.

    The activation energy, Ea, in the Arrhenius equation is always constant for a given reaction.

  • How does increasing temperature affect the rate constant according to the Arrhenius equation?

    According to the Arrhenius equation, increasing temperature increases the rate constant.

  • What is the effect of increasing activation energy on the rate constant?

    Increasing the activation energy decreases the rate constant, according to the Arrhenius equation.

  • True or False?

    The natural logarithm form of the Arrhenius equation, ln(k) = ln(A) - (Ea/RT), is used to simplify calculations and for analysing graphs.

    True.

    The natural logarithm form of the Arrhenius equation, ln(k) = ln(A) - (Ea/RT), is used to simplify calculations and for analysing graphs.

  • How does the natural logarithm form of the Arrhenius equation, ln(k) = ln(A) - (Ea/RT), compare to the equation of a straight line, y = mx + c?

    When comparing ln(k) = ln(A) - (Ea/RT) to y = mx + c:

    • ln(k) = y

    • -Ea/R = m

    • 1/T = x

    • ln(A) = c

  • What information is needed to calculate the activation energy using the Arrhenius equation?

    To calculate the activation energy using the Arrhenius equation, you need the rate constants at different temperatures.

  • How can the Arrhenius factor, A, be determined experimentally?

    The Arrhenius factor, A, can be determined experimentally by plotting ln(k) against 1/T and finding the y-intercept, which equals ln(A).

  • What type of graph is used to determine activation energy using the Arrhenius equation?

    A graph of ln(k) against 1/T is used to determine activation energy using the Arrhenius equation.

  • True or False?

    The slope of the Arrhenius plot, ln(k) vs 1/T, is equal to the activation energy.

    False.

    The slope of the Arrhenius plot, ln(k) vs 1/T, is equal to -Ea/R, where Ea is the activation energy and R is the gas constant.

  • How is the activation energy calculated from the Arrhenius plot?

    The activation energy is calculated by multiplying the negative of the gradient of the Arrhenius plot by the gas constant R.

  • What does the y-intercept of the Arrhenius plot represent?

    The y-intercept of the Arrhenius plot represents ln(A), where A is the Arrhenius factor.

  • What is an Arrhenius plot?

    An Arrhenius plot is a graph of ln(k) against 1/T that is used to determine the activation energy and Arrhenius factor of a reaction.

  • True or False?

    A linear Arrhenius plot indicates that the reaction follows Arrhenius behavior.

    True.

    A linear Arrhenius plot indicates that the reaction follows Arrhenius behavior.

  • What units should be used for temperature when constructing an Arrhenius plot?

    Temperature should be in Kelvin (K) when constructing an Arrhenius plot.

  • How can the Arrhenius factor, A, be calculated from the Arrhenius plot?

    The Arrhenius factor, A, can be calculated by taking the exponential of the y-intercept of the Arrhenius plot.

  • True or False?

    The activation energy calculated from an Arrhenius plot is typically expressed in kJ/mol.

    True.

    The activation energy calculated from an Arrhenius plot is typically expressed in kJ/mol.

  • What experimental data is needed to construct an Arrhenius plot?

    To construct an Arrhenius plot, you need rate constant values measured at different temperatures.