1. Science 10 – Hydrologic Cycle and Heat Capacity

2. Objectives
Define specific heat capacity and use it to calculate thermal energy
Describe the hydrological cycle
Distinguish between different phases of the hydrological cycle
Calculate heat of fusion and heat of vaporization

3. Planet Water 70% of Earth’s surface is covered with water
Water plays a major role in the absorption and distribution of thermal energy, influencing both weather and climate: the great
moderator

4. Hydrological Cycle Water is constantly moving through the biosphere
Changing phases from solid to liquid to gas and back again
Uses evaporation, condensation, transpiration, and precipitation
Add or release thermal energy for phase changes

6. How Oceans Effect Distribution of Heat
Large Reservoirs of Heat
Water has high specific heat capacity
Water has low albedo, high absorption (90% of incoming solar radiation is absorbed

7. Large Reservoirs of Heat
3. High heats of fusion and vaporization
• 4. Water is a fluid and heat can be distributed

8. Areas around large bodies of water (Great Lakes, oceans) do not experience extreme weather changes like areas that don’t have large bodies of water i.e continent interiors (think Saskatchewan and Alberta), and deserts.

9. Large bodies of water MODERATE temperature and climate.
It takes a lot of solar radiation to heat water, so water is a heat sink.
It absorbs a great deal of solar radiation, keeping the region cooler during the day, and it slowly reradiates the heat at night

10. Ocean Currents Large effect on weather in coastal communities
Influence worldwide climate

11. Gulf Stream
Surface current: starts in Caribbean and flows up the Eastern coastline of US and Canada up to British Isles. Also called North Atlantic Drift.

12. Huge air and ocean currents distribute heat in amazing patterns around the earth, greatly affecting the climate and weather of many regions.

13. Phase Changes and Global Energy Transfer
Phase changes in the hydrologic cycle play a role in global transfer of thermal energy
The transfer of energy warms the air, which rises
This can cause thunderstorms or hurricanes

14. How does all this affect weather and climate?
Different specific heat capacities (we will get to this in a minute) of the Earth’s different surfaces (sand, water, forests, etc) affect how much they heat up the air and water around them.

15. How does this affect our weather and climate?
The Earth’s water absorbs a lot of heat from the surroundings when condensing, and it releases a lot of heat when it is evaporating.

16. If you think of all the water that is condensing or evaporating all over the lakes, ponds, streams, oceans and clouds that’s a lot of heating and cooling!

17. Energy Transfer Types Heat of fusion Heat of Solidification
Energy absorbed when 1 mol of a substance changes from solid to liquid
Heat of Solidification
Energy released when 1 mol of a substance changes from liquid to solid
Heat of Vaporization
Energy absorbed when 1 mol of a substance changes from liquid to vapor

18. Energy Transfer Types cont…
Heat of Condensation
Energy released when 1 mol of a substance changes from vapor to liquid
Which ones are endothermic? Exothermic?

19. Specific Heat Capacity
Symbolized as “c”
Amount of energy needed to raise temp of 1 g of a substance by 1 degree Celsius
Water c= 4.19 J/g degree Celsius
This is high
What effect might this have on the climate of Vancouver compared to Calgary?

20. Specific heat capacity is a constant and is represented by “c”
SUBSTANCE
c (J /g oC)
Pure water
4.19
Steam
2.02
Ice
2.00
Sea water
3.89
Moist air
1.15
Dry air
1.00
Pg. 375

21. Formula Q = mcΔT c = specific heat capacity J/goC
ΔT = change in temperature oC
m = mass g
Q = amount of heat J
If data are given in initial (T1) and final (T2) temperatures instead of change in temperature, calculate ΔT using ΔT = T2 – T1

22. THE EFFECTS OF SPECIFIC HEAT CAPACITY ON THE EARTH’S WEATHER AND CLIMATE
a) The Earth’s land or water surface heats up as it absorbs solar radiation.
b) This thermal energy is transferred by conduction to surrounding cooler air or water causing convection currents in air and water

23. Convection (transfer of thermal energy in fluids – liquids or gases)
Convection currents – air circulates and distributes heat (remember warm air is less dense, rises, cooler air descends and takes its place close to the ground, it heats up…etc.

24. Practice
A 50.0 g mass of water at 25.0 °C is heated to 50.0°C on a hot plate. Given that the theoretical specific heat capacity of water is J/g°C, determine the value for Q
Answer: 5.24 J

25. Practice
How much thermal energy must be released to decrease the temperature of 1.00 kg of water by 10.0 °C, given that the theoretical specific heat capacity of water is 4.19 J/g°C?
Answer: 41.9 kJ

26. Practice
When 21.6 J of thermal energy is added to a 2.0 g mass of iron, the temperature of the iron increases by 24.0°C. What is the experimental specific heat capacity of iron?
0.45 J/g°C

27. Heat of Fusion, Heat of Vaporization: Phase Changes of Water
Why is the ice and water absorbing energy with no change in temperature?

28. Calculations Q amount of heat energy J (joules)
Energy required for melting Energy required for vaporizing
Q = nHfus Q = nHvap
Q amount of heat energy J (joules)
n number of moles (no units)
Hfus heat of fusion J/mol
Hvap heat of vaporization J/mol

29. Energy Transfer Graph
Where on the graph would we label heat of fusion? Heat of vaporization?

30. Calculating Heat of Fusion
Hfus = _Q_ n
Hfus = heat of fusion (kJ/mol)
Q = quantity of thermal energy (kJ)
n = amount of the substance (mol)

31. Practice
When kJ of thermal energy is added to mol of ice at 0.0°C, the ice melts completely. What is the experimental heat of fusion of water?
Answer: 6.01 kJ/mol

32. Practice
When 5.00 g of ice melts, 1.67 kJ of thermal energy is absorbed. Calculate the experimental heat of fusion of ice. The molar mass, M, of ice is g/mol.
Answer: 6.0 kJ/mol

33. Practice
When kJ of thermal energy is added to mol of ice at 0.0°C, the ice changes phase. Calculate the experimental heat of fusion of ice.

34. Calculating Heat of Vaporization
Hvap = _Q_ n
Hvap = heat of vaporization (kJ/mol)
Q = quantity of thermal energy (kJ/mol)
n = amount of the substance (mol)

35. Practice
When 150 g of water changes from liquid to vapor phase, 339 kJ of energy is absorbed. Determine the experimental heat of vaporization of water, given that the molar mass, M, of water is g/mol
Answer: 40.7 kJ/mol

36. Practice
When 8.70 kJ of thermal energy is added to mol of liquid methanol, all the methanol enters the vapor phase. Determine the experimental heat of vaporization of methanol.

37. Assignment Specific Heat Practice problems # 1-8 pg. 379
Pg 386/387, try practice problems