Please show all of your calculations!
1. Question 10.4 in your text. Marks: 1.What is the net radiation? Marks: 2.
5. Given a canopy with the following characteristics:
calculate, for both zenith angles:
A) The fraction of total beam radiation
transmitted
through the canopy. Marks: 2.
B) Repeat A) with double the leaf area index. Marks:
2.
C) Repeat A) with the leaves clumped together
(clumping
factor = 0.5). Marks: 2.
Assignment # 3: Biological Responses to Air Temperature
Due: October 7, 2004
Total Possible Marks: 30
Please show all your work to get full marks!
1. Text, Question 2.4. Marks: 6 for each part.
2. Calculate the effective temperature (Te) using the equation on the windchill handout for air temperatures between -50 and 0 oC (increments of 1 oC) at wind speeds of 6, 25, 50, and 75 km/h (equivalent to roughly 4, 15, 31, and 47 miles/h, respectively). Use a walking speed of 6 km/h. Plot your results and briefly (i.e. one paragraph), interpret your results. Marks: 8 for plot, 4 for interpretation.
3. Calculate the Humidex (H) using the equation on the Humidex handout for air temperatures between 0 and 30 oC (increments of 1 oC) at a relative humidity of 25, 50, 75 and 100%. Plot and briefly interpret your results. Hint: You may find equations 3.8 and 3.11 useful, and note that 1 kPa = 10 mbar. Marks: 8 for plot, 4 for interpretation.
Assignment # 4: The Human Energy Balance
Due: October 21, 2004
Total Possible Marks: 27
Introduction
The relationship between a person's mass and body surface area has
implicatons for how we acheive temperature regulation through
adjustments
in our energy balance. When energy inputs balance energy outputs, a
constant (steady-state) body temperature is acheived. The heat
generated
by
metabolism
(Hm), is balanced by convective (Hc),
radiative (Hr), evaporative (from sweating; Hs,
and from within the lungs; Hl) when body temperature
is constant. In this exercise, we'll explore the relationship between
human
mass and the energy balance. Use your answers and constants from
previous questions to answer the next.
Questions
1. What is the relationship between a person's total body area, and
mass? First, write down your hypothesis on what you think the
relationship
is, and why (2 marks). Then, for a 2-m tall person, calculate the total
body area as their mass varies from 0 to 100 kg in 2-kg increments.
Plot
the relationship (2 marks), and describe what the implications of your
graph in terms of a person's energy balance and temperature regulation
(2 marks). Hint: Equation 13.1 may be useful.
2. Based on your answer to #1, what do you think the relationship between mass, and the radiative and convective heat loss would be, and why (2 marks)? From an Ohm's Law analogy, we know that "flux = conductance x gradient". Therefore, we can write:
Hr (radiative heat
loss)
= DrA(Ts-Ta)
and
Hc (convective heat
loss)
= DcA(Ts-Ta)
where Dr and Dc are the heat and convective conductances, respectively (Dc = 7.1 and Dc = 6.5 W m-2 K-1), A is the total body surface area (m2), and Ts and Ta are the body surface and aire temperature, respectively (Ts = 37 and Ta = 25 oC, respectively). Plot the relationship between mass (for a 2-m tall person), and Hr and Hc (use one graph with two plots) (2 marks). How does a person's mass influence the convective and radiaive heat losses? (2 marks).
3. How does a person's mass influence their ability to cool by sweating? To answer this, assume a person generates heat at a rate of 500 W (e.g. moderate activity), and the rate of heat loss from the lungs is 10.5 W. First, write down the energy balance for our 2-m tall person with a constant temperature (1 mark). Then, calculate the heat loss from sweating as a function of mass, and plot this relationship (4 marks). What does this relationship show? (2 marks). Is your result a surprise (why or why not?) (2 marks).
4. At what mass does the evaporative sweating, convective, and radiative heat losses roughly balance? To determine this, on one graph, plot each of these terms against mass (2 marks).
5. The heat loss from sweating can be expressed as Hs = Dsr where Ds is the "evaporative sweating conductance" (674 W h kg-1), and r is the sweat required. Plot the sweat required to supply the sweat evaporation rate as a function of mass (2 marks). How many litres of water would a person at the mass you reported in question 4 need to drink per hour to supply this demand? (2 marks).
Assignment # 5: Water Pontential and Flow in Plants
Due: November 18, 2004
Total Possible Marks: 22
Please show all your work to get full marks!
In your text, questions (marks):
4.1 (1)
4.2 (1)
4.3 (3)
4.4 (7)
4.5 (1)
4.6 (2)
4.7 (1)
4.8 (6)
Assignment # 6: Organisims and Climate Variability
Due: December 2, 2004
Total Possible Marks: 20
We know that the Earth's climate is variable, even over relatively short time scales. It has changed in the past and will in the future. Organisms, to be successful, must then be capable of adapting to such climate variability.Or maybe not? (e.g. think of many reptiles, insects (coach roaches), or the plant Equisetum (horsetail))
Your assignment is to find at least one scientific paper (It must be
peer reviewed. Web documents, unless on-line peer reviewed journal
articles,
are not acceptable) that describes how an organism adapts (or doesn't
adapt)
to changes in its environment. For example, inspection of plants in
herbariums
compared to today's plants
shows that the stomata density has decreased
as carbon dioxide concentrations in the atmosphere have increased
(implying
that the plants have become more efficient). Write a 1-2 page summary
of
your paper's findings, including at least one key figure or graph (10
marks).
Then, on December 2, be prepared to orally present your paper to the
class,
using visual aids to assist you (10 marks). Your oral presentation
should
be 5-10 minutes.