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Unit 2 Matter & Energy Chapters 3 & 10.

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Presentation on theme: "Unit 2 Matter & Energy Chapters 3 & 10."— Presentation transcript:

1 Unit 2 Matter & Energy Chapters 3 & 10

2 Energy Recall that Energy is the capacity to do work.
Energy can be given off or absorbed. Different terms are used to describe processes that give off or absorb energy.

3 Exothermic Describes a process which releases energy into the environment. It gives off heat and/or light. That energy can be used to do work.

4 Endothermic Describes a process which absorbs energy from the environment. It absorbs heat and/or light. The absorbed energy is used to do work.

5 Law of Conservation of Energy
Energy can neither be created nor destroyed, but changed from one form to another. We can change Heat into Light and Light into Heat. We cannot permanently remove light or heat from the universe.

6 Heat Energy that is transferred between objects.
Heat always travels from hotter objects to cooler objects. Energy will be transferred until the objects are at equal temperatures.

7 The 3 Methods of Energy Transfer
Radiation Transfer via light emission. Conduction Transfer from one material to another by direct contact. Convection Transfer via circulating molecules.

8 The Usual Manner Most of the time, at least two methods of energy transfer occur at the same time. For example, when you light a match, energy is emitted in the form of light. The molecules closest to the flame gain energy via conduction. And the room is warmed via convection.

9 Types of Energy There are two basic types of energy that matter can have: Kinetic Energy (KE) is the energy of an object due to its motion. Can be calculated using KE = ½ mv2 KE increases linearly with mass. KE increases exponentially with velocity (speed).

10 Potential Energy Energy of an object due to its location or construction. How far can it fall? How much energy is stored in its bonds? Since there is always more PE, we always talk about a change in PE.

11 There are 3 Modes of KE Translational KE is motion through space.
Vibrational KE is how strongly bonds vibrate. Rotational KE is how molecules rotate in space and the rotation of Atoms within a molecule. The faster Translation, Vibration, or Rotation, the more KE.

12 Temperature A measure of the average kinetic energy of the particles in an object or system. Higher Temp = higher KE This means more motion (translational, vibrational, rotational). Lower Temp = lower KE This means less motion.

13 Kinetic Theory of Matter
All matter is constantly moving (except at Absolute Zero, 0 K) The greater the temperature, the more motion there is!

14 Evaporative Cooling Since Temp is an average, when molecules w/ higher KE evaporate, the remaining group has less overall KE. The temperature drops. This is why we sweat: As sweat evaporates, avg KE decreases.

15 Sweating it Out When our body temperature rises, our sweat glands secrete a salty mixture that is mostly water. Our capillaries near our skin flush and heat is transferred from our blood to the sweat. Water molecules gain enough KE to evaporate, cooling our bodies.

16 Pot-In-Pot Refrigerator
Needs no electricity or fuel – just water from time to time! Why would that be useful? Invented in 1995 by Mohammed Bah Abba Won Rolex Laureate award in 2000 Two clay pots nestled with a layer of sand Sand is soaked in water Evaporation cools interior.

17 Temperature Conversions
ºC = 5/9 (º F – 32) ºF = 9/5 ºC + 32 K = ºC + 273 ºC = K – 273 The coldest possible temperature is 0 Kelvin Absolute Zero – where no motion occurs

18 Space Background Temperature
Complete the Table: # Temperature Fahrenheit Celsius Kelvin 1. Water Freezes 32°F 2. Water Boils 373 K 3. Room Temp 20°C 4. Warm Day 86°F 5. Medium Oven K 6. Iron Melts 1,809 K 7. Liquid Nitrogen °F 8. Common Temp 233 K 9. Space Background Temperature -451.3ºF

19 Delta T T = change in temperature T = Tf – Ti
All T must be in Kelvin Since Kelvin and Celsius are actually the same scale (but with a different zero point), T in K = T in ºC Don’t use ºF!!! It doesn’t matter if you use Kelvin or Celsius, as long as both Tf and Ti are in the same unit!

20 Units of Energy SI Unit: Joule (J) = kg·m2/s2
Common Unit: calorie (cal) = the amount of energy (heat) required to raise 1.00 grams of H2O by 1oC (or 1 K) Food Unit: Calorie = 1 kcal (1,000 calories) 1 calorie (cal) = Joules (J) 1 Calorie (Cal) = kiloJoules (kJ)

21 Convert the following:
60.1 cal to J 450 J to cal 190 Cal (in a yogurt cup) to J 60.1 cal * J = 1 cal 251 J 450 J * 1 cal = 4.184 J 110 cal 190 Cal * 1000 cal * J = 794,960 1 Cal cal 790,000 J

22 Turn off dah lights! A Watt light bulb gives off J per second. If the bulb is on for 1.00 hours, how many Calories of energy are used? 1.00 hr * 3600 s * J = 360,000 J 1 hr s 86 Cal 360,000 J * 1 cal * 1 Cal J = 4.184 J cal

23 Eat Your Wheaties… One small bag of trail mix contains 1880 kJ of energy. What is the Calorie value listed on the bag? 449 Cal

24 All that and… 62,000 J/serving 372 kJ/bag
A bag of chips has 260 Calories per serving. How many joules are in 1 serving? If the bag contains 6 servings, how many kilojoules in the entire bag? 62,000 J/serving 372 kJ/bag


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