12. THERMODYNAMICS II

Question 1

1. What are the three physical states that matter exists in?

Answer 1

• solid
• liquid
• vapor

Question 2

2. What can change about a material when it absorbs heat?

Answer 2

• its physical state

Question 3

3. What is Melting?

Give an example.

Answer 3

• it is when a solid changes from the solid state
• to the liquid state
• the process requires energy
• this is because the molecules of a solid are found in a rigid structure
• they are not free to move without added energy
• EG: melting an ice cube to form liquid water

Question 4

4. What is Freezing?

Answer 4

• it is when a liquid is frozen to form a solid
• it is the reverse of melting
• it requires energy to be removed from the liquid
• this is so that the molecule can settle into a rigid structure

Question 5

5. What is Vaporizing?

Give an example.

Answer 5

• it is changing a substance from its liquid state to its vapour (gas) state
• this process requires energy
• this is because the molecules must be freed from their clusters
• boiling liquid water
• this transforms it to water vapour (or steam)

Question 6

6. What is steam?

Answer 6

• it is the gas of individual water molecules

Question 7

7. What is Condensing?

Answer 7

• it is when a gas is condensed to form a liquid
• it is the reverse of vaporizing
• it requires energy to be removed from the gas
• this allows the molecules of the gas to cluster instead of flying away from one another

Question 8

8. What is a material’s heat of transformation?
   What is another word for the heat of the transformation?

Answer 8

• it is the amount of energy required per unit mass
• to change the state of a particular material
• it does NOT change the temperature
• the Latent Heat

Question 9

9. What is the symbol for heat of transformation?

Answer 9

• L

Question 10

10. What is the formula to work out the heat of the transformation?

Answer 10

Q= L x m

• Q= the measure of the heat energy (J/kg)
• L= constant
  = it is the latent heat dependent on the material
  = it is measured in joules
• m = mass (kg)

Question 11

11. What is the Heat of Vaporization (Lv)?

Answer 11

• it is the amount of energy per unit mass
• that must be added to vaporize a liquid
• OR that must be removed to condense a gas

Question 12

12. What is the Heat of Fusion (Lf)?

Answer 12

• it is the amount of energy per unit mass
• that must be added to melt a solid
• OR that must be removed to freeze a liquid

Question 13

13. Why is an effective mode of body heat loss important?

Answer 13

• all our metabolism goes into making heat
• very little of our metabolism goes into useful mechanical work
• our body temperature would rise very quickly if we did not have effective modes of heat loss

Question 14

14. What are the five modes of heat loss?

Answer 14

1. Radiation
2. Convection
3. Conduction
4. Evaporation of sweat
5. Evaporation of water through breathing

Question 15

15. What is radiation loss?

What percentage of heat is lost through this?

Answer 15

• it is the loss of heat by the emission of electromagnetic radiation
• 54%-60% heat loss

Question 16

16. What is convection?

What percentage of heat is lost through this?

Answer 16

• the loss of radiated heat
• it is removed by moving air
• around 25% of heat is lost

Question 17

17. What is conduction?

What percentage of heat is lost through this?

Answer 17

• it is the direct transfer of heat through contact
• around 25% of heat is lost

Question 18

18. What is the Evaporation of sweat?

What percentage of heat is lost through this?

Answer 18

• it is the loss of heat by the evaporation of water
• around 7% of heat is lost

Question 19

19. What is the Evaporation of water through breathing?

What percentage of heat is lost through this?

Answer 19

• it is the loss of heat by the evaporation of water
• around 14% of heat is lost

Question 20

20. What do the magnitude and importance of the four modes of heat loss depend on?

Answer 20

• clothing
• environment
• surroundings

Question 21

21. What is thermal radiation?

Answer 21

• it is the exchange of energy as heat between an object and its environment
• this is done via electromagnetic waves

Question 22

22. What happens when you stand near a fire?

Answer 22

• you are warmed
• you absorb the thermal radiation from the fire
• your thermal energy increases as the fire’s thermal energy decreases
• there is no medium required for the heat transfer via radiation

Question 23

23. Why is there no medium required for heat transfer that is accomplished through radiation?

Answer 23

• radiation can travel through a vacuum

Question 24

24. According to Planck’s Law, what do all objects at a temperature (T) emit?

Answer 24

• they emit Thermal radiation

Question 25

25. What is essential in Planck’s law?

Answer 25

• the presence of a black body

Question 26

26. What is a Black Body?
    List three characteristics.

Answer 26

1. It is a body that absorbs all the thermal radiation falling onto it
2. At thermal equilibrium, it emits as much energy as it absorbs
3. It is a good absorber of radiation
   and a good emitter of radiation

Question 27

27. What is Radiation incident?

Answer 27

• the unintended exposure of an individual to radiation

Question 28

28. What are the three types/components of Radiation Incident?

Answer 28

• reflection of the radiation by the object
• absorption of the radiation into the object
• transmission of radiation through the object

Question 29

29. What is Emissivity?

Answer 29

• it is the fraction of the energy incident on the object
  that is absorbed

Question 30

30. What can be said about the Emissivity of a shiny, metallic, reflective surface?

Answer 30

• it is very low
• less than 0.1

NB: emissivity exists on a scale from 0 to 1

Question 31

31. What can be said about the Emissivity of dull, black surfaces?

Answer 31

• they have the highest emissivity
• between 0.9 and 1

Question 32

32. What is the unit for Emissivity?

Answer 32

• ε

Question 33

33. What is the formula to calculate emissivity?

Answer 33

P = 𝑒. σ . A . T⁴

• P= the radiated power (Watts)
• 𝑒 = emissivity
  = it is a ratio
  = it has no units
• σ= the Stefan - Boltzman Constant
  = 5.67 x 10 ⎺⁸ (W/m².K⁴)
• A = the surface area (m²)
• T = the temperature (Kelvins)

Question 34

34. What does the Stefan Boltzman Law represent?

How can this be expressed in a formula?

Answer 34

• the energy per second (power) radiated by the surface
• ▵Q / ▵t

Question 35

35. Where does the body receive radiant energy from?

Answer 35

• the surrounding objects

Question 36

36. What unit of measurement can we find to calculate the approximate difference between the energy radiated by the body AND the energy absorbed from the radiation from the surroundings?

Answer 36

• we can look for Hr
• this is the rate of energy loss or gain
• it is another way of writing power
• it is measured in watts

Question 37

37. What is the formula for Hr?

Answer 37

• Hr = Power (watts)
• Kr = constant
  = it is a parameter
  = it is about 2.1 x 10⁴ (J/m²hr°C)
  = it can also be written as 5.0 kcal/m²hr°C
• Ar = the effective body surface area (m²)
  = it is what is emitting the radiation
• 𝑒 = surface emissivity
• (Ts - Tw) = difference in temperature
  = this can be in any unit
• Ts = the skin temperature (°C)
• Tw = the surrounding walls temperature (°C)

Question 38

38. When does Conduction occur?

Answer 38

• when the thermal energy moves through a material as a result of collisions
• these collisions happen between free electrons, ions, atoms and molecules of the material

Question 39

39. What can be said about the average kinetic energy of a hotter substance?

Answer 39

• it is higher

Question 40

40. What happens with regards to energy between materials in contact with one another?

Answer 40

• the higher energy atoms in the warmer substances transfer energy to the lower energy atoms in the cooler substances
• this is a result of atomic collisions between the two
• this allows heat to flow from hot to cold

Question 41

41. How would we calculate the temperature difference?

Answer 41

▵T = T1 - T 2

Question 42

42. What is the temperature gradient?

Answer 42

• the ▵T / ▵ x
• ▵T = the change in temperature
  = the unit is not important
• ▵x = the thickness of the body
• this is the rate of change of temperature with distance

Question 43

43. How would we work out the quantity of heat (▵Q) that is transmitted from Face 1 to Face 2 of the body for a given time (▵t)?

Answer 43

▵Q / ▵t = kT x A x ▵T/▵x

kT= this is the thermal conductivity of the material
= this depends on the material of the body
= it has a unit of W/m.K

A= the cross sectional area (m²)

▵T = the change in temperature
= the unit is not important

▵x = thickness
= change in distance (m)

Question 44

44. What is another way of working out ▵Q / ▵t?

Answer 44

▵Q / ▵t = h x A x ▵T

• h = the coefficient of the conduction heat transfer
• A = the cross sectional area (m²)
• ▵T = change in temperature
  = the unit is not important

Question 45

45. How else can we calculate the coefficient of conduction heat transfer (h)?

Answer 45

h = kT / ▵x

• kT= the thermal conductivity
  = W/m.K.
• ▵x= thickness of the body
  = the distance (m)

Question 46

46. What is the flame of a candle classified as?

Answer 46

• it is convection
• it is this convection that is transporting the thermal energy upwards
• this energy transfer occurs when:
  • a fluid (air)
  • encounters an object (match)
  • with a higher temperature than that of the fluid

-the temperature of the part of the fluid that is in contact with the hot object increases

• the fluid expands
• it becomes less dense
• it is now lighter than the surrounding cooler fluid
• buoyant forces cause it to then rise

Question 47

47. How can the heat loss due to Convection/Conduction be worked out?

Answer 47

• we must find the heat loss due to convection (Hc)
• this is the rate of energy transfer
• it is another way of working out power
• it has a unit of Watts

Question 48

48. What is the formula for working out Hc?

Answer 48

Hc = Kc x Ac x (Ts - Ta)

• Hc = the heat loss due to convection
  = power (in watts)
• Kc = a parameter
  = it depends on the movement of the air

    = when the speed of the air is less than 0.2 m/s
    = it then has a value of 3.1 W/m²K

• Ac = the effective body surface area (m²)
• Ts = the skin temperature in Kelvins
• Ta = the air temperature in Kelvins

Question 49

49. When is the Convective heat loss greater?

Answer 49

• when the air is moving
• the Convective heat loss is much smaller when the air is still

Question 50

50. What is Convection within the body called?

Answer 50

• the flow of blood

Question 51

51. What does the flow of blood change?
    What does it not affect?

Answer 51

• it changes the distribution of the temperature within the body
• it does not affect the average temperature of the body

Question 52

52. What is the normal core body temperature?

Answer 52

• 36.5° - 37.5°

Question 53

53. How much does the core temperature generally change during the waking hours?

Answer 53

• it increases by 0.5 ° C

Question 54

54. What is an example of how well the body controls its temperature?

Answer 54

• the nude body can maintain its core temperature (between 36°C and 38°C) for several hours
• it can do this within environmental temperature changes that range from 21°C and 54°C in dry air

Question 55

55. What is the correlation between temperature deviation from the normal body temperature, and exposure time?

Answer 55

• the larger the temperature deviation from the normal body temperature
• the shorter the maximum possible exposure time until death

Question 56

56. What is the Convection Temperature for a naked adult man as compared to a naked baby?
    (if we have minimal air movement)

Answer 56

• naked adult man = 26°C
• naked baby = 35°C

Question 57

57. Where is the Thermoneutral Zone located?
    (the zone of minimal metabolism)

Answer 57

• it is between the Tc (Convection Temperature)
  AND
• the Th (Hypothermia Temperature)

Question 58

58. What happens below the Tc (convection temperature)?

Answer 58

• the heat loss increases
• this is due to convection and radiation

Question 59

59. What increases metabolism?

Answer 59

• increases in muscle tension
• shivering

Question 60

60. What increases muscle tension and shivering?

Answer 60

• increases in the difference between the body temperature and the environmental temperatures

Question 61

61. What happens to the core body temperature at low temperatures?

Answer 61

• it cannot be maintained
• there is cooling
• hypothermia develops

Question 62

62. How does heat loss happen above Th
    (Hypothermia Temperature)?

Answer 62

• it is dominated by evaporation

Question 63

63. Give the core temperature ranges for each of the following:

63.1: Mild Hypothermia
63.2: Moderate Hypothermia
63.3: Severe Hypothermia

Answer 63

63.1: 32°C- 35°C

63.2: 28°C - 32°C

63.3: less than 28°C

Question 64

64. Which temperature is usually lower than the Core
    temperature (37°C)?

Answer 64

• the temperature of the body skin (Tskin)
• this usually sits at 34°C

Question 65

65. What is Thermoregulation?

Answer 65

• it is the maintenance of a constant core body temperature in an organism
• both humans and other warm-blooded organisms thermoregulate

Question 66

66. What is the term given to warm-blooded organisms?

Answer 66

• homeotherms

Question 67

67. What aspects of the human body allow it to thermoregulate?

Answer 67

• the human body has temperature-sensitive receptors
• these are located in the skin, hypothalamus, midbrain, spinal cord and the abdominal cavity
• these thermoreceptors sense either hot and cold
• most areas of the human body have both kinds of thermoreceptors
• the sensors send information to the hypothalamus in the brain
• this controls the body’s response to the stimuli

Question 68

68. How do the blood vessels in the body react when the internal body temperature or the skin temperature gets too low?

Answer 68

• these blood vessels are found adjacent to the skin
• the blood vessel becomes smaller
• it constricts
• it reduces the blood flow from the core to the surface
• this process is called Vasoconstriction

Question 69

69. What are the effects of Vasoconstriction?

Answer 69

• it reduces the rate of heat loss from the skin surface
• it allows the skin to get colder

Question 70

70. What is Vasodilation and when is it used?

Answer 70

• it is when the blood vessel increases in size
• it expands
• this happens when there is a need to increase the rate of heat loss
• this happens when the body is too hot
• the blood supply to the skin is increased by Vasodilation
• this increases the blood flow in the skin
• this reduces the blood pressure

Question 71

71. What is Piloerection?

Answer 71

• it is when the fine body hairs stand on end
• this is an attempt to reduce convective heat loss from the skin
• the raising of the air is intended to create a stationary layer of air between the skin and the surroundings

Question 72

72. What is Shivering?

Answer 72

• it is a physiological response to cold temperatures
• cold signals are transmitted to the hypothalamus
• they trigger the reflex
• the body muscles begin to make small movements to use up some metabolic energy
• this generates thermal energy

Question 73

73. What is Perspiration/ Sweating?

Answer 73

• it is a very effective cooling mechanism
• this is because the Latent Heat (L) of evaporation of water is high
• heat loss that is caused by the evaporation of the liquid from the skin is the only way we can lose heat when the air is above 37°C
• the human body has sweat glands in the skin
• these excrete fluid
• it is mainly water
• it has some dissolved salts in it

Question 74

74. Read through this summary.
    Does everything make sense?

Answer 74

• yes

Question 75

75. Read through this summary.
    Does everything make sense?

Answer 75

• yes

Question 76

76. Read through this summary.
    Does everything make sense?

Answer 76

• yes

Question 77

77. Read through this summary.
    Does everything make sense?

Answer 77

• yes

Question 78

78. Read through this summary.
    Does everything make sense?

Answer 78

• yes

Question 79

79. Read through this summary?
    Does everything make sense?

Answer 79

• yes

Question 80

80. Read through this summary.
    Does everything make sense?

Answer 80

• yes

Question 81

81. Read through this summary.
    Does everything make sense?

Answer 81

• yes

Question 82

82. Read through this summary.
    Does everything make sense?

Answer 82

• yes

Question 83

83. Read through this summary.
    Does everything make sense?

Answer 83

• yes

Question 84

84. Read through this summary.
    Does everything make sense?

Answer 84

• yes