The laws of thermodynamics describe the essential role of energy and explain and predict the direction of changes in matter. The availability or disposition of energy plays a role in virtually all observed chemical processes. Thermodynamics provides tools for understanding this key role, particularly the conservation of energy, including energy transfer in the forms of heat and work. Chemical bonding is central to chemistry. A key concept to know is that the breaking of a chemical bond inherently requires an energy input, and because bond formation is the reverse process, it will release energy. In subsequent units, the application of thermodynamics will determine the favorability of a reaction occurring.
1.B Describe the components of and quantitative information from models and representations that illustrate both particulate-level and macroscopic level properties.
2.D Make observations or collect data from representations of laboratory setups or results, while attending to precision where appropriate.
3.A Represent chemical phenomena using appropriate graphing techniques, including correct scale and units.
5.A Identify quantities needed to solve a problem from given information (e.g., text, mathematical expressions, graphs, or tables).
5.F Calculate, estimate, or predict an unknown quantity from known quantities by selecting and following a logical computational pathway and attending to precision (e.g., performing dimensional analysis and attending to significant figures).
6.D Provide reasoning to justify a claim using chemical principles or laws, or using mathematical justification.
6.E Provide reasoning to justify a claim using connections between particulate and macroscopic scales or levels.
ENE-2: Explain the relationship between experimental observations and energy changes associated with a chemical or physical transformation.
Temperature changes in a system indicate energy changes.
Energy changes in a system can be described as endothermic and exothermic processes such as the heating or cooling of a substance, phase changes, or chemical transformations.
When a chemical reaction occurs, the energy of the system either decreases (exothermic reaction), increases (endothermic reaction), or remains the same. For exothermic reactions, the energy lost by the reacting species (system) is gained by the surroundings, as heat transfer from or work done by the system. Likewise, for endothermic reactions, the system gains energy from the surroundings by heat transfer to or work done on the system.
The formation of a solution may be an exothermic or endothermic process, depending on the relative strengths of intermolecular/interparticle interactions before and after the dissolution process.
ENE-2: Represent a chemical or physical transformation with an energy diagram.
A physical or chemical process can be described with an energy diagram that shows the endothermic or exothermic nature of that process.
ENE-2: Explain the relationship between the transfer of thermal energy and molecular collisions.
The particles in a warmer body have a greater average kinetic energy than those in a cooler body.
Collisions between particles in thermal contact can result in the transfer of energy. This process is called “heat transfer,” “heat exchange,” or “transfer of energy as heat.”
Eventually, thermal equilibrium is reached as the particles continue to collide. At thermal equilibrium, the average kinetic energy of both bodies is the same, and hence, their temperatures are the same.
ENE-2: Calculate the heat q absorbed or released by a system undergoing heating/ cooling based on the amount of the substance, the heat capacity, and the change in temperature.
The heating of a cool body by a warmer body is an important form of energy transfer between two systems. The amount of heat transferred between two bodies may be quantified by the heat transfer equation: EQN: q = mcΔT. Calorimetry experiments are used to measure the transfer of heat.
The first law of thermodynamics states that energy is conserved in chemical and physical processes.
The transfer of a given amount of thermal energy will not produce the same temperature change in equal masses of matter with differing specific heat capacities.
Heating a system increases the energy of the system, while cooling a system decreases the energy of the system.
The specific heat capacity of a substance and the molar heat capacity are both used in energy calculations.
Chemical systems change their energy through three main processes: heating/cooling, phase transitions, and chemical reactions.
ENE-2: Explain changes in the heat q absorbed or released by a system undergoing a phase transition based on the amount of the substance in moles and the molar enthalpy of the phase transition.
Energy must be transferred to a system to cause a substance to melt (or boil). The energy of the system therefore increases as the system undergoes a solid-to-liquid (or liquid-to-gas) phase transition. Likewise, a system releases energy when it freezes (or condenses). The energy of the system decreases as the system undergoes a liquid-to-solid (or gas-to-liquid) phase transition. The temperature of a pure substance remains constant during a phase change
The energy absorbed during a phase change is equal to the energy released during a complementary phase change in the opposite direction. For example, the molar heat of condensation of a substance is equal to the negative of its molar heat of vaporization.
ENE-2: Calculate the heat q absorbed or released by a system undergoing a chemical reaction in relationship to the amount of the reacting substance in moles and the molar enthalpy of reaction.
The enthalpy change of a reaction gives the amount of heat energy released (for negative values) or absorbed (for positive values) by a chemical reaction at constant pressure.
ENE-3: Calculate the enthalpy change of a reaction based on the average bond energies of bonds broken and formed in the reaction.
During a chemical reaction, bonds are broken and/or formed, and these events change the potential energy of the system.
The average energy required to break all of the bonds in the reactant molecules can be estimated by adding up the average bond energies of all the bonds in the reactant molecules. Likewise, the average energy released in forming the bonds in the product molecules can be estimated. If the energy released is greater than the energy required, the reaction is exothermic. If the energy required is greater than the energy released, the reaction is endothermic.
ENE-3: Calculate the enthalpy change for a chemical or physical process based on the standard enthalpies of formation.
Tables of standard enthalpies of formation can be used to calculate the standard enthalpies of reactions. EQN: ΔH°reaction = Σ∆Hf °products − ΣΔHf °reactants
ENE-3: Represent a chemical or physical process as a sequence of steps.
ENE-3: Explain the relationship between the enthalpy of a chemical or physical process and the sum of the enthalpies of the individual steps.
Although the concept of “state function” is not required for the course, two principles of Hess’s law should be understood. First, when a reaction is reversed, the enthalpy change stays constant in magnitude but becomes reversed in mathematical sign. Second, when two (or more) reactions are added to obtain an overall reaction, the individual enthalpy changes of each reaction are added to obtain the net enthalpy of the overall reaction.
When the products of a reaction are at a different temperature than their surroundings, they exchange energy with the surroundings to reach thermal equilibrium. Thermal energy is transferred to the surroundings from the products of an exothermic reaction. Thermal energy is transferred from the surroundings to the products of an endothermic reaction.