--- title: "Reaction Energy Profile AP Chemistry Review | Topic 5.6" description: "Review AP Chemistry Topic 5.6 with reaction energy profiles, activation energy, transition states, reaction coordinate diagrams, temperature, and Arrhenius concepts." canonical: "https://fiveable.me/ap-chem/unit-5/reaction-energy-profile/study-guide/RF1B5UBHtCp0qgt8ayp3" type: "study-guide" subject: "AP Chemistry" unit: "Unit 5 – Kinetics" lastUpdated: "2026-06-11" --- # Reaction Energy Profile AP Chemistry Review | Topic 5.6 ## Summary Review AP Chemistry Topic 5.6 with reaction energy profiles, activation energy, transition states, reaction coordinate diagrams, temperature, and Arrhenius concepts. ## Guide ## TLDR A reaction energy profile is a graph that tracks [potential energy](/ap-chem/key-terms/potential-energy "fv-autolink") as reactants turn into products along the reaction coordinate. It shows the activation energy (the climb from reactants up to the transition state) and the overall energy change (whether products end up lower or higher than reactants). For [AP Chemistry](/ap-chem "fv-autolink"), you need to read and draw these diagrams, label the key points, and connect activation energy to temperature and reaction rate. ## Reaction Energy Profile Summary In AP Chemistry Topic 5.6, a reaction energy profile shows how potential energy changes as an [elementary reaction](/ap-chem/unit-5/elementary-reactions/study-guide/SPsFzzECb4aCre0wFrGg "fv-autolink") moves from reactants, through a transition state, to products. The vertical gap from reactants to the transition state is the forward activation energy, and the vertical gap from reactants to products is the overall energy change. The AP exam expects you to interpret and label the diagram, not calculate with the Arrhenius equation. Know the concept: higher temperature means a larger fraction of collisions can reach the transition state, while lower activation energy means more collisions can successfully react. ## Why This Matters for the AP Chemistry Exam This topic builds your ability to represent a [chemical reaction](/ap-chem/unit-4/representations-reactions/study-guide/CzoUpQyKbK27GRGVfXFM "fv-autolink") with a model and read meaning from it. On the exam, you may be asked to draw or interpret an energy profile, identify the activation energy and overall energy change, and explain why temperature affects how fast a reaction goes. These diagrams also set up later topics like reaction mechanisms and catalysis, where you compare energy profiles to support claims about how a reaction proceeds. One thing to note up front: the Arrhenius equation explains the [temperature dependence](/ap-chem/key-terms/temperature-dependence "fv-autolink") of the rate, but you will not be asked to do calculations with it. Focus on the concept, not the math. ## Key Takeaways - A reaction energy profile plots potential energy (y-axis) against the reaction coordinate, which represents reaction progress (x-axis). - Activation energy is the energy difference between the reactants and the transition state. Lower activation energy generally means a faster reaction. - The transition state (activated complex) is the highest energy point, where bonds are partly broken and partly formed. It is unstable and cannot be isolated. - Compare [reactant](/ap-chem/unit-7/representations-equilibrium/study-guide/wLQChBkGSKiEP5xvlXB8 "fv-autolink") and product energies to classify the reaction: products lower than reactants is [exothermic](/ap-chem/key-terms/exothermic-reaction "fv-autolink"), products higher than reactants is endothermic. - Elementary reactions involve breaking some bonds and forming new ones, which is what the energy profile is tracking. - Higher temperature means more collisions have enough energy to reach the transition state, so the rate increases. ## Energy in Elementary Reactions An **elementary reaction** is a reaction that happens in a single step. Because it is a single step, an energy profile for it shows one climb up to a single transition state and then down to products. Every elementary reaction involves breaking some bonds and forming new ones. Breaking bonds takes energy and forming bonds releases energy. The energy profile is a way to track that energy balance as the reaction moves from reactants to products. ## Reading a Reaction Energy Profile A reaction energy profile (also called a potential energy diagram or reaction coordinate diagram) plots potential energy on the y-axis against the **reaction coordinate** on the x-axis. The reaction coordinate is the axis along which the motions of rearranging reactants into products are tracked, so moving left to right means moving forward through the reaction. There are three main features to find on the diagram: 1. **Reactants** sit at the far left, at their starting energy. 2. The **transition state** (also called the **activated complex**) is the peak of the curve. It is the highest energy point and the least stable, because bonds are partway between broken and formed. You cannot isolate it. 3. **Products** sit at the far right, at their final energy. ## Endothermic vs. Exothermic Profiles You can classify a reaction by comparing where the reactants and products sit on the y-axis. - In an **endothermic reaction**, the products have higher potential energy than the reactants. Energy is absorbed overall. Think of it as Reactants + Energy → Products. - In an **exothermic reaction**, the products have lower potential energy than the reactants. Energy is released overall, often as [heat](/ap-chem/unit-6/heat-capacity-calorimetry/study-guide/jShImkrhZMnPWxlEjdwN "fv-autolink"). Think of it as Reactants → Products + Energy. The overall energy change is the difference between the reactant energy and the product energy. The activation energy is a separate measurement: the difference between the reactants and the transition state peak. ## Activation Energy **Activation energy** is the energy difference between the reactants and the transition state. It is the minimum energy needed to push reactants up to the peak so they can become products. You can picture it as an energy barrier that has to be cleared before the reaction can finish. On the diagram, activation energy is shown by the distance from the reactant energy level up to the top of the peak. The forward activation energy and the reverse activation energy are different distances: the forward value is measured from reactants to the peak, and the reverse value is measured from products to the peak. Activation energy connects directly to rate. A lower activation energy means a larger fraction of collisions have enough energy to react, so the reaction tends to go faster. A higher activation energy means fewer collisions clear the barrier, so the reaction tends to be slower. ## Temperature and the Arrhenius Equation The rate of an elementary reaction depends on temperature because temperature controls how many collisions are energetic enough to reach the transition state. At higher temperatures, a larger fraction of particles have enough energy to clear the activation energy barrier, so the rate goes up. The **Arrhenius equation** describes this temperature dependence by relating the [rate constant](/ap-chem/key-terms/rate-constant "fv-autolink") to the activation energy. You should understand what it tells you conceptually: as temperature rises or as activation energy falls, the rate constant gets larger. You will not have to do calculations with the Arrhenius equation on the AP exam, so focus on the relationships rather than plugging in numbers. ## How to Use This on the AP Chemistry Exam ### Free Response If you are asked to draw an energy profile, label both axes (potential energy vs. reaction coordinate), mark reactants and products at their correct relative heights, and show the transition state as the peak. Use an arrow or bracket to indicate the activation energy from the reactant level to the peak, and show the overall energy change between reactants and products. ### Problem Solving To classify a reaction from a given diagram, compare the height of the products to the height of the reactants. Products lower than reactants means exothermic. Products higher than reactants means endothermic. To find activation energy, measure from the reactant level up to the peak, not from the bottom of the y-axis. ### Common Trap Do not confuse the activation energy with the overall energy change. Activation energy is reactants to the peak. The overall energy change is reactants to products. They answer different questions, and a question can ask for either one. ## Common Misconceptions - **Activation energy is the same as the overall energy change.** They are different. Activation energy goes from reactants to the transition state; the overall energy change goes from reactants to products. - **The transition state is a stable [intermediate](/ap-chem/key-terms/intermediate "fv-autolink") you can collect.** It is the highest energy, least stable point and cannot be isolated. An intermediate (formed in one step and used in a later step) is a different idea that shows up in multistep mechanisms, not single elementary reactions. - **Exothermic reactions have no activation energy.** Even reactions that release energy overall still have a peak to climb. Releasing energy overall does not remove the barrier. - **Forward and reverse activation energies are equal.** They are usually different, since one is measured from reactants to the peak and the other from products to the peak. - **Raising temperature lowers the activation energy.** Temperature does not change the activation energy. It increases the fraction of collisions with enough energy to clear the existing barrier. - **You need to calculate with the Arrhenius equation.** You only need the conceptual relationship between temperature, activation energy, and rate. Calculations with it are not assessed. ## Related AP Chemistry Guides - [Unit 5 Overview: Kinetics](/ap-chem/unit-5/review/study-guide/vaoVU5dw76konF7C16Ib) - [5.1 Reaction Rates](/ap-chem/unit-5/reaction-rates/study-guide/4V94d3BwjoPaOOyQtDKQ) - [5.2 Introduction to Rate Law](/ap-chem/unit-5/intro-rate-law/study-guide/oq5mJS35IadrTLHLjdqZ) - [5.3 Concentration Changes Over Time](/ap-chem/unit-5/concentration-changes-over-time/study-guide/Owtcz3zbxFZXsPI7YfwJ) - [5.4 Elementary Reactions](/ap-chem/unit-5/elementary-reactions/study-guide/SPsFzzECb4aCre0wFrGg) - [5.5 Collision Model](/ap-chem/unit-5/collision-model/study-guide/rvpVG6AlhGU9AfTvkCdv) ## Vocabulary - **Arrhenius equation**: A mathematical relationship that describes how the rate of an elementary reaction depends on temperature and activation energy. - **activation energy**: The minimum energy required for reactants to overcome the energy barrier and proceed to products in a chemical reaction. - **bond-breaking**: The process of breaking chemical bonds in reactant molecules during a collision. - **bond-making**: The process of forming new chemical bonds to create product molecules during a collision. - **elementary reaction**: A single-step reaction that represents one molecular event in a reaction mechanism, with a specific rate law determined by its molecularity. - **overall energy change**: The difference in total energy between reactants and products in a chemical reaction; also known as the enthalpy change (ΔH). - **reaction coordinate**: A diagram or pathway showing the energy changes that occur as reactants are converted to products during a reaction. - **reaction energy profile**: A diagram that plots energy versus reaction progress, showing the activation energy and energy changes for each step in a multistep reaction. - **transition state**: The highest energy point on a reaction energy profile, representing the arrangement of atoms at the peak of the activation energy barrier. ## FAQs ### What is a reaction energy profile in AP Chemistry? A reaction energy profile is a graph of potential energy along the reaction coordinate. It shows reactants, products, the transition state, activation energy, and overall energy change. ### What is activation energy on a reaction energy profile? Activation energy is the energy difference between the reactants and the transition state for the forward reaction. On the diagram, it is the vertical distance from reactants to the peak. ### What is the transition state? The transition state is the highest-energy point on the reaction energy profile. Bonds are partly broken and partly formed, and the structure is unstable and cannot be isolated. ### How do you tell if a reaction is endothermic or exothermic from an energy profile? Compare product energy to reactant energy. Products lower than reactants indicate an exothermic reaction; products higher than reactants indicate an endothermic reaction. ### Do you need to calculate with the Arrhenius equation on the AP Chemistry exam? No. Calculations involving the Arrhenius equation are excluded. You should know conceptually that temperature and activation energy affect the fraction of collisions that reach the transition state. ### What is a common mistake with reaction energy profiles? A common mistake is confusing activation energy with overall energy change. Activation energy is reactants to transition state; overall energy change is reactants to products. ## Structured Data ```json {"@context":"https://schema.org","@type":"FAQPage","inLanguage":"en","mainEntity":[{"@type":"Question","@id":"https://fiveable.me/ap-chem/unit-5/reaction-energy-profile/study-guide/RF1B5UBHtCp0qgt8ayp3#what-is-a-reaction-energy-profile-in-ap-chemistry","name":"What is a reaction energy profile in AP Chemistry?","acceptedAnswer":{"@type":"Answer","text":"A reaction energy profile is a graph of potential energy along the reaction coordinate. 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