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Lets start with a new symbol

Lets start with a new symbol. Q . Q is for “Heat” Measured in Joules. Heat is a form of energy. James Prescott Joule. Discovered that heat was form of energy. Found that when water is stirred, temperature increases. James Joule. Experimented with falling masses turning paddles in water.

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Lets start with a new symbol

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  1. Lets start with a new symbol • Q. Q is for “Heat” • Measured in Joules. • Heat is a form of energy.

  2. James Prescott Joule • Discovered that heat was form of energy. • Found that when water is stirred, temperature increases.

  3. James Joule • Experimented with falling masses turning paddles in water. • Figured out how much mechanical energy is needed to change temperature. • Got a unit named after him.

  4. Units of Heat • Joule is most common heat unit. • Also, there is the calorie. • Calorie: is the amount of energy necessary to raise the temperature of 1 g of water by 1° C . • Units to measure heat. • calorie: Energy needed to raise 1 g of water by 1C. • 1 cal = 4.186 Joules.

  5. Calories and calories. • Calories and calories are not the same thing. • If C is uppercase, it is a “dietary calorie” (on your food label.) • One Calorie = 1000 calories One Calorie = 1 kilocalorie One Calorie = 4186 Joules

  6. Units of Heat, cont. • Also – BTU • BTU stands for British Thermal Unit • A BTU is the amount of energy necessary to raise the temperature of 1 lb of water 1° F

  7. New Symbol • Specific heat = c • Amount of heat needed to raise 1 kg of a material 1 C. • Units J / kg °C • Depends on the substance. Look it up. • Specific heat questions are on the JCCC final.

  8. Specific Heat equation • Q = mcΔT • Heat = mass*specific heat*Temp. Change • If ΔT is positive, material gains heat. • If ΔT is negative, material gives up heat.

  9. Problem • The Specific Heat of water is 4186 J/kgC. • How much heat is needed to raise 6.2 kg of water from 10 to 85 Celsius? • Do in PP notes. • Specific heat questions like this are on the JCCC final.

  10. Problem • The Specific Heat of water is 4186 J/KgC. • How much heat is needed to raise 6.2 kg of water from 10 to 85 Celsius? • Q = mcΔT • Q = 6.2kg*4186 J/KgC*75C

  11. Calorimetry • Measurement of heat flow from a hot material to a cold material (usually Water). • Heat flow into water is calculated based upon the temp. change of the water. • Conservation of energy applies to the isolated system. Don’t let any heat escape so that all goes into the water. (Insulated system) • The energy that leaves the warmer substance equals the energy that enters the water. • ΔQhot = - ΔQcold • Know Q = mcΔT for final.

  12. Easy problem • Know for JCCC Final: • ΔQhot = - ΔQcold • mcΔThot = mcΔTcold

  13. Easy problem • 1 kg of water at 70 C is mixed with 1 kg of water at 60 C. What is the final temp?

  14. Easy problem • 1 kg of water at 70 C is mixed with 1 kg of water at 60 C. What is the final temp? • mcΔThot = mcΔTcold • 1 kg x 4186 J/kgK x (70C – Tf) • = 1 kg 4186 J/kgK x (Tf – 60C)

  15. Easy problem • 1 kg of water at 70 C is mixed with 1 kg of water at 60 C. What is the final temp? • 2 kg of water at 70 C is mixed with 1 kg of water at 60 C. What is the final temp?

  16. Problem • For breakfast you consume 320 dietary Calories. • You decide to work this off by lifting a 25 kg barbell .4 m. • How many times will you have to repeat this motion to burn off breakfast?

  17. Problem • For breakfast you consume 320 dietary Calories. • Instead, you (60 kg) decide to spring from rest to 5 m/s. • How many repetitions of this will you need to do?

  18. Still talking about breakfast • If instead of eating that food, you set it on fire, how much water could it bring from 0C to 100 C? • Q = mcΔT • m = Q /cΔT

  19. What else does heat do? • If heat is added to a substance, what else could happen besides ΔT?

  20. Phase Change • Temperature remains constant during phase change. • E.g. Ice will continue to absorb heat at 0 C without changing temp. The temp will not be 1 C until all of the ice has melted. • See graph next slide.

  21. Graph of Ice to Steam

  22. Phase Change • 3 Basic types of Phase Change: • Melting/Freezing – Liquid/Solid • Boiling/Condensing – Gas/Liquid • Sublimation/Deposition – Gas/Solid

  23. New Symbol • l – “l” is for latent heat. • Amount of heat absorbed, per kilogram, for a change from one phase to another. • Heat absorbed during a phase change does not change temperature, so it is “latent.” • Units: J/kg

  24. Latent Heat, cont. • Depends on both substance and phase change. Just something to look up. • Latent heat of fusion, Lf, is used for melting or freezing • Latent heat of vaporization, Lv, is used for boiling or condensing • Latent heat of sublimation, Ls, is used for sublimation or deposition.

  25. Equation • Q = m l

  26. Problem • A gram of H20 is at -30 C. How much heat total is needed to raise it to H20 at 120 C?

  27. Multistep processes. • A lot of problems will involve both a temperature change and a phase change. Evaluate the Q for each step separately, and then add them together.

  28. Problem • How many steps?

  29. Graph of Ice to Steam • How many steps? 5 • 1- Ice to 0 C • 2- Melting • 3- Water to 100 C • 4- Boiling • 5- Steam to 120 C • Qtotal = Q1 + Q2 + Q3 + Q4 + Q5

  30. End here in 2012

  31. Problem • How many steps? • 5 • 1- Ice to 0 C • 2- Melting • 3- Water to 100 C • 4- Boiling • 5- Steam to 120 C • Qtotal = Q1 + Q2 + Q3 + Q4 + Q5

  32. Useful Information • For H20: • cice = 2090 J/kgº C • lf = 3.33 X 105 J/kg • cwater = 4186 J/kgº C • lv = 2.26 x 106 J/kg • csteam = 2010 J/kgº C

  33. Warm the Ice • Qtotal = Q1 + Q2 + Q3 + Q4 + Q5 • Q1 -> Ice from -30 to 0 • Temp. change, so use specific heat. • Q1 =mice*cice*ΔTice • = .001kg* 2090 J/kgº C * (0 - -30)

  34. Melt the Ice • Qtotal = 63 J + Q2 + Q3 + Q4 + Q5 • Q2 -> Ice from 0 to water @ 0 • Phase change, so use latent heat. • Q2 =mice*lfice • = .001kg* 3.33 X 105 J/kg

  35. Warm the Water • Qtotal = 63 J + 333 J + Q3 + Q4 + Q5 • Q3 -> Water from 0 to 100 • Temp. change, so use specific heat. • Q3 =mwater*cwater*ΔTwater • = .001kg* 4186 J/kgº C * (100 - 0)

  36. Boil the water • Qtotal = 63 J + 333 J + 419 J + Q4 + Q5 • Q4 -> Ice from 0 to water @ 0 • Phase change, so use latent heat. • Q4 =mwater*lfwater • = .001kg* 2.26 x 106 J/kg

  37. Warm the Steam • Qtotal = 63 J + 333 J + 419 J + 2260 J + Q5 • Q5 -> Steam from 100 to 120 • Temp. change, so use specific heat. • Q5 =msteam*csteam*ΔTsteam • = .001kg* 2010 J/kgº C * (120 - 100)

  38. Warm the Steam • Qtotal = 63 J + 333 J + 419 J + 2260 J + 40 J Qtotal = 3115 J

  39. Graph of Ice to Steam

  40. Problem • The latent heat of lead is 24500 J/kg, and the melting point is 327.5 C. How much heat is needed to bring 17 kg of solid lead at 327.5 C to 17 kg of liquid lead at 327.5 C?

  41. Problem • Back in October, we learned that the most powerful person in the class was about 1050 Watts. • If we gave him an electrical generator bike, how long would it take him to boil a kg of water from room temp?

  42. Problem • 400 g of Copper (c = 386 J/kgC) at 95 C is placed into a kilogram of water at 5 C. What will the final temperature of the mixture be?

  43. Another problem. • 10 kilograms of Aluminum (c = 900 J/kgC) are at 130 C. A 50 g Ice cube at -5 C is dropped onto the aluminum and melts, then boils away. What is the final temperature of the Al?

  44. More than 2 things • ΣΔQ = 0 • Or • ΔQ1 + ΔQ2 + ΔQ3 … = 0

  45. Problem • 400 ml of water at 40 C is poured into a .3 kg glass beaker (cglass = 837 J/C) and a .5 kg block of Al at 37 C (cAl 900 J/C) is dropped in. • What will the equilibrium temp be?

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