Chapter 10 Energy

1. Chemistry 101 Chapter 10 Energy

2. Energy Universe Matter Energy Empty space Energy: ability to do work or produce heat.

3. Energy Kinetic energy (KE): energy of motion KE = ½ mV2V: velocity Potential energy (PE): stored energy (Position & Composition) Law of conservation of energy

4. T of hill increases Frictional heating(heat is a form of energy). Kinetic and Potential Energy Kinetic energy Potential energy A B B A Work: change the position of ball B Change in potential energy for ball A (change in level) Heat: friction between surface & ball

5. Heat and Temperature Temperature:measure of random motions of the components of substance. move faster Kinetic energy ↑ T ↑

6. T final Cold Water Hot Water Heat and Temperature Energy is transferred from high T to low T. Heat: Flow of energy due to a T difference. Thotinitial + Tcoldinitial Tfinal = T final 2

7. Heat units of heat: calorie (cal) English system joule (J) SI system Joule:Energy (heat) required to raise T of one gram of water by 1C. 1 cal = 4.184 J Food energy is measured in Calories (note the capital C). 1 Cal = 1 kcal = 1000 cal

8. Amount of heat = specific heat × mass × change in temperature Amount of heat = SH × m × (T2 – T1) T2 = final temperature T1 = initial temperature SH = Specific heat capacity (cal/g °C) m = mass (g) Heat

9. Heat • Specific heat capacity is the energy required to change the temperature of a mass of one gram of a substance by one Celsius degree. Note: ALEKS uses “c” instead of “SH” to stand for specific heat capacity.

10. Heat Practice 1: • Calculate the amount of heat energy (in joules) needed to raise the temperature of 6.25 g of water from 21.0°C to 39.0°C. • We are told the mass of water and the temperature increase. We look up the specific heat capacity of water, 4.184 J/g°C. Q = SH x m x T Q = (4.184 J/g°C) x (6.25 g) x (39.0°C – 21.0°C) Q = 471 J

11. Heat Practice 2: • A silver-gray metal weighing 15.0 g requires 133.5 J to raise the temperature by 10.°C. Find the heat capacity. Q = SH x m x T (133.5 J) = SH x (15.0 g) x (10.°C) SH = 0.89 J/g°C Can you determine the identity of the metal using Table 10.1? Al

12. Heat of reaction 2HgO(s) + heat (energy)  2Hg(l) + O2(g) Endothermic reaction C3H8(s) + 5O2(g)  3CO2(g)+ 4H2O(l) + heat (energy) Exothermic reaction All combustion reactions are exothermic.

13. Surroundings Surroundings Energy Energy System System Exothermic Endothermic Exothermic (burning) Surrounding Reactant (PE) Energy released to the surroundings as heat Product Heat of reaction Exothermic = exit!

14. Heat of reaction Practice: • Classify each process as exothermic or endothermic. Explain why. (The system is underlined.) • Your hand gets cold when you touch ice. • The ice gets warmer when you touch it. • Water boils in a stove-top kettle. • Water becomes ice in the freezer. • Water vapor condenses on a cold pipe. • Ice cream melts. Exo Endo Endo Exo Exo Endo

15. Thermodynamics Thermodynamics: study of energy The first law of thermodynamics: Law of conservation of energy:energy of the universe is constant. Internal energy (E):sum of the kinetic and potential energies. E = q + w  “delta”: change Work Heat

16. Thermodynamics E = q + w Energy flows into system via heat (endothermic): q = +x Energy flows out of system via heat (exothermic): q = -x Surroundings Surroundings Energy Energy System System System does work on surroundings: w = -x Surroundings do work on the system: w = +x E  0 E  0 Endothermic Exothermic

17. Enthalpy Enthalpy (Thermochemistry): heat of chemical reactions. For a reaction in constant pressure, the change of enthalpy is equal to energy that flows as heat. Hp = heat Constant pressure “-” heat or Hp: exothermic: heat flows out of the system. “+” heat or Hp: endothermic: heat flows into the system.

18. Calorimetry Calorimeter: A device to measure the heat energy released or absorbed by a reaction. T  H

19. Enthalpy Practice: S(s) + O2(g)  SO2(g) ΔH = –296 kJ • Calculate the quantity of heat released when 2.10 g of sulfur is burned in oxygen at constant pressure. – 296 kJ 1 mol S 2.10 g S x x = 0.0655 mol S 32.26 g S 1 mol S 0.0655 mol S = – 19.4 kJ Use the H value like a conversion factor.

20. Hess’s Law State function:a property of system that changes independently of its pathways. Enthalpy is a state function. In a chemical reaction, change of enthalpy is the same whether the reaction takes place in one step or in a series of steps. N2(g) + 2O2(g)  2NO2(g) H1 = 68 kJ 1 Step N2(g) + O2(g)  2NO(g) H2 = 180 kJ 2 Steps 2NO(g) + O2(g)  2NO2(g) H3 = -112 kJ N2(g) + 2O2(g)  2NO2(g) H2 + H3 = 68 kJ

21. Two rules about enthalpy 1. If a reaction is reversed, the sign of H is also reversed. N2(g) + 2O2(g)  2NO2(g) H1 = 68 kJ 2NO2(g)  N2(g) + 2O2(g) H1 = -68 kJ 2. If the coefficients in a balanced reaction are multiplied by an integer, the value of H is also multiplied by the same integer. N2(g) + 2O2(g)  2NO2(g) H1 = 68 kJ 2N2(g) + 4O2(g)  4NO2(g) H1 = 2  68 kJ = 136 kJ  2

22. Gasoline + O2 CO2 + H2O + energy Spread in universe Concentrated energy Spread energy Use of energy to do work Heat death Quality Quantity Quality-Quantity of Energy Law of conservation of energy Why are we concerned about energy?

23. Energy and Our World Woody plants Source of energy Photosynthesis Coal Sun Natural gas Petroleum Photosynthesis 6CO2 + 6H2O + energy of sun C6H12O6 + 6O2 glucose

24. (C1-C4) (C5-C10) (C10-C18) (C15-C25) (C25) Energy and Our World Fossil Fuels: formed from the decomposition of marine plants and animals. 1. Natural gas • 90 to 95 percent methane. • 5 to 10 percent ethane, and a mixture of other low-boiling alkanes. 2. Petroleum • A thick liquid mixture of thousands of compounds, most of them hydrocarbons.

25. Energy and Our World 3. Coal • Was formed from the remains of plants that were buried (under high P and T). • 20% of our energy. • Expensive, dangerous, and produces pollution (CO & SO2).

26. Greenhouse Effect

27. Driving forces Energy spread: concentrated energy is dispersed widely. (Exothermic process) heat Matter spread: molecules of a substance are spread out and occupy a larger volume. Dissolving is endothermic process, but because of matter spread, it occurs.

28. The second law of thermodynamics: The entropy (S) of the universe is always increasing. We run towards a disorder (heat death of universe). A Spontaneous process is one that happens in nature on its own. (because of increasing entropy) Dissolving Entropy (S) A measure of disorder or randomness. Energy spread Faster random motions of the molecules in surroundings. Matter spread Components of matter are dispersed (occupy a larger volume).

29. Midterm 2 • Bring a 2B pencil. • One 30423 Scantron form (available in Runner Bookstore). • A calculator (scientific, not graphing).