Ch. 15: Energy and Chemical Change 15.2 Heat
Objectives Describe how a calorimeter is used to measure energy absorbed or released. Explain the meaning of enthalpy and enthalpy change in chemical reactions and processes.
Measuring Heat Heat changes that occur during chemical and physical processes can be measured accurately and precisely using a calorimeter. A calorimeter is an insulated device used for measuring the amount of heat absorbed or released during a chemical or physical process.
Calorimetry A known mass of water is placed in the insulated chamber. The amount of energy that this water absorbs or releases can be calculated from the change in temperature that occurs. A known mass of water is placed in an insulated chamber in the calorimeter to absorb the energy released from the reacting system or to provide the energy absorbed by the system.
Example qw = mCwT q = (50.0 g)(4.184 J/g 0C)(6.8 0C) = 1,400 J sample of lead heated in a beaker, water insulated, lead dropped into water qw = mCwT q = (50.0 g)(4.184 J/g 0C)(6.8 0C) = 1,400 J
Practice Problems A sample of metal is heated and put into a calorimeter containing 125 g of water at 25.6 0C. The final temperature of the water is 29.3 0C. How much heat in J is absorbed by the water? If 335 g of water at 65.5 0C lost 9750 J of heat, what was the final temperature of the water? The temperature of a sample of water increases from 20 0C to 46.6 0C as it absorbs 5650 J of heat. What is the mass of the sample?
Determining Specific Heat Remember: we calculated the water absorbs 1,400 J. How much energy does the lead release?
Determining Specific Heat The lead releases 1, 420!! qPb = -1,420 J. If we know the mass of lead (150 g) and the change in temperature of the lead (28.8 0C - 100 0C = -71.2 C0), we can calculate the specific heat of lead. qPb = mCPbT CPb = q/mT C = -1,400 J/(150 g)(-71.2 0C) C = 0.13 J/g 0C
Specific Heat Practice Problems To solve: Use Q = mwCwΔTw to determine the amount of heat the water absorbs. This is the same amount of heat the metal releases. (Just change the sign!) Use the heat, mass of metal (mm), and temperature change of metal (ΔTm) to find the specific heat of the metal (Cm). Determine the identity of the metal through its specific heat.
Chemical Energy and the Universe Every chemical reaction and change of physical state either releases heat (is exothermic) or absorbs heat (is endothermic). Endothermic: energy is absorbed Exothermic: Energy is released
Chemical Energy and the Universe Thermochemistry is the study of heat changes that accompany chemical reactions and phase changes. The system is the specific part of the universe that contains the reaction or process you wish to study. Everything else in the universe is considered the surroundings. The universe = system + surroundings
Chemical Energy and the Universe Consider heat flow in exothermic and endothermic reactions or processes In summary, When you break open the heat pack, oxygen from the air enters the pack. The oxygen reacts with iron in the pack in an exothermic reaction described by the following equation. Energy is a product of the reaction, which means that heat is released. (EXOTHERMIC) (ENDOTHERMIC)
Enthalpy and Enthalpy Changes The total amount of energy a substance contains is impossible to measure. But, for many reactions, the amount of energy lost or gained (CHANGE in energy) can be measured conveniently in a calorimeter. Reactions in a calorimeter or any lab take place at a constant atmospheric pressure.
Enthalpy and Enthalpy Changes Chemists use the term enthalpy (H) to represent the heat content of a system at constant pressure. Therefore, the change in enthalpy (H) is the heat absorbed or released in a chemical reaction at constant atmospheric pressure. Hrxn is the difference between the enthalpy of the substances present at the end of a reaction and the enthalpy of the substances present at the beginning.
Enthalpy and Enthalpy Changes In other words, the difference between the heat contained in the products and the heat contained in the reactants is the enthalpy (heat) of reaction. Hrxn = Hproducts - Hreactants In an endothermic reaction, heat is absorbed, which would create a positive enthalpy. In an exothermic reaction, heat is given off, which means the reaction would have a negative enthalpy. Give me an example! Have you ever made ice? Then you have lowered the enthalpy of water! Have you ever melted ice? Then you have raised the enthalpy of water!
Note Recall q was defined as the heat lost or gained in a chemical reaction or process. If the reaction takes place at constant pressure, q = Hrxn. (Therefore, Hrxn = mCT)
Enthalpy and Enthalpy Changes 4Fe(s) + 3O2(g) 2Fe2O3(s) + 1625 kJ According to the equation, the reaction is exothermic - energy is written as a product. Therefore, Hreactants has to be greater than Hproduct and Hrxn has to have a negative sign. The enthalpy change for this reaction can then be indicated by the notation: Hrxn = -1625 kJ Hot pack equation. According to the equation, the reactants in this exothermic reaction lose heat, therefore H(rxn) is a negative. Enthalpy changes for exothermic reactions are always negative.
Enthalpy and Enthalpy Changes Exothermic Delta H negative
Enthalpy and Enthalpy Changes NH4NO3 + 27 kJ NH4+ (aq) + NO3- (aq) This reaction is endothermic since energy is a reactant. Therefore, Hproducts has to be greater than Hreactant and Hrxn has to have a positive sign. Hrxn = 27 kJ
Endothermic Enthalpy Change