Homework #3
Due in class on Tuesday, February 14th
Answer
the following questions on a separate sheet of paper. If you need to calculate an answer, you must show your work. You
will need to use the table of saturation mixing ratios below to help answer
questions 1-2. (The table below is in
Fahrenheit; you cannot use table 4.1 included in the in-class handout because
it is in Celsius). Use the heat index
and wind chill tables (provided in lecture notes) to help answer questions 3-4. Make
sure you read and answer all the parts to each question!
|
Temperature (ºF) |
Sat. Mixing Ratio (g/kg) |
|
Temperature (ºF) |
Sat. Mixing Ratio (g/kg) |
|
5 |
1.21 |
55 |
9.32 |
|
|
10 |
1.52 |
60 |
11.19 |
|
|
15 |
1.89 |
65 |
13.38 |
|
|
20 |
2.34 |
70 |
15.95 |
|
|
25 |
2.88 |
75 |
18.94 |
|
|
30 |
3.54 |
80 |
22.43 |
|
|
35 |
4.33 |
85 |
26.48 |
|
|
40 |
5.28 |
90 |
31.16 |
|
|
45 |
6.40 |
95 |
36.56 |
|
|
50 |
7.74 |
100 |
42.78 |
1.
Last
Thursday the following conditions were measured on the UA campus
n
At
8 AM: air temperature, T = 45° F; dew point temperature, Td = 25° F.
n
At
11 AM: air temperature, T = 60° F; dew point temperature, Td = 25° F.
n
At
2 PM: air temperature, T = 70° F; dew point temperature, Td
= 25° F.
(a)
Compute
the relative humidity for each of the times/conditions specified above.
(b)
Explain
why the relative humidity changed the way it did from 8 AM through 2 PM. How did the water vapor content in the air
change between 8 AM and 2 PM?
2.
Values
of air temperature and relative humidity are given below for Presque Isle,
Maine and Tucson, Arizona as observed on a day in spring 2004.
Air Temperature
|
35° F |
|
Relative Humidity |
100 % |
|
Weather Conditions |
Rain |
Air
Temperature
|
90° F |
|
Relative Humidity |
25 % |
|
Weather Conditions |
Sunny |
(a)
What
are the approximate dew point temperatures at the two locations?
(b)
Of
these two locations, which has the higher concentration of water vapor in the
air? How do you know? Explain how a desert location with a low
relative humidity can actually have a higher water vapor content than a
location where the relative humidity is 100% with rain falling?
3.
On
a day in summer 2004, the conditions in Tucson, Arizona and Charleston, South
Carolina are given
Tucson, Arizona
|
Air Temperature |
105° F |
|
Relative Humidity |
10 % |
Air
Temperature
|
95° F |
|
Relative Humidity |
50 % |
(a)
Using
the heat index chart provided with the course lecture notes, find the heat
index for the two cities. Which of the
two conditions is more stressful for people or are they the same?
(b)
Interpret
your answer to (a) by explaining how the human body is affected by the
respective weather conditions.
4.
On
a day last winter, conditions measured at Flagstaff, Arizona and West
Yellowstone, Montana are given
Air
Temperature
|
0° F |
|
Wind Speed |
20 MPH |
West Yellowstone, Montana
Air
Temperature
|
-10° F |
|
Wind Speed |
5 MPH |
(a)
Using
the wind chill chart provided with the course lecture notes, determine the wind
chill equivalent temperature for Flagstaff and West Yellowstone. Which of the two conditions is more
stressful for humans or are they the same?
(b)
Interpret
your answer to (a) by explaining how the human body is affected by the
respective weather conditions.
5.
Evaporative
cooling is one of the most ancient and one of the most energy-efficient methods
of cooling a home. It long has been regarded as environmentally
"safe," since the process uses no ozone-depleting chemicals, and
demands one-fourth as much energy as refrigeration during the peak cooling
months of the year. In dry climates such as Tucson, evaporative cooling can be
used to inexpensively cool large homes.
Locally, these devices are often referred to as “swamp coolers”.
The most common form of residential evaporative
cooling uses a vertical pad of absorbent cellulose fiber, a system for
delivering water to the pad to keep it soaked with water, and a fan to draw air
through the porous pad. As warm, dry outside air is drawn through the wet pad,
water evaporates into the air, and the air gives up its heat. In other words, energy is removed from the
air in order to evaporate water. Thus, air that has moved through the wet pad
is cooler than the outdoor air and contains more water vapor than the outside
air.
The drop in temperature depends on how much water
can be evaporated into the air. This is
obviously a function of relative humidity.
When the relative humidity is low, the temperature drop can be
large. However, when the relative
humidity is high, the temperature drop will be small (and the swamp cooler
doesn’t help much).
The wet bulb temperature is the lowest
temperature to which air can be cooled by evaporating water into it. This is the theoretical lower limit for the
temperature of the air that comes out of an evaporative cooler.
Explain the following statements:
(a)
When
the relative humidity is 100%, the air temperature, the dew point temperature,
and the wet bulb temperature are identical.
Explain.
(b)
When
the relative humidity is less than 100%, the dew point temperature and the wet
bulb temperature are both lower than the air temperature. Explain.
(c)
When
the relative humidity is less than 100%, the wet bulb temperature will always
be higher than the dew point temperature.
Explain. (Hint: What is happening to the water vapor content
and dew point temperature of the air as it is being evaporatively cooled? At what point does it become impossible to
further cool air by evaporation?)
6.
Suppose
you were going to walk from the ocean near Calcutta, India up to the top of
Mount Everest at 8846 meters above sea level.
We will round off the elevation to 9000 meters. We will look at how air temperature and air
pressure change on your way up, using the table below
|
Elevation (meters) |
Fraction of way up by
altitude |
Air Temperature |
Air Pressure |
Percentage of the
atmosphere below you by weight |
|
0 |
At bottom |
30° C |
1000 mb |
0 % |
|
3000 |
1/3 |
? |
700 mb |
? |
|
6000 |
2/3 |
? |
500 mb |
? |
|
9000 |
At top |
? |
330 mb |
? |
(a)
Estimate
the air temperature at 3000, 6000, and 9000 meters. The information you need to do this is contained on the lecture
page discussed in class on January 19th.
(b)
Compute
the percentage of the atmosphere below 3000, 6000, and 9000 meters (based on
weight).
(c)
Explain
why air pressure decreases as you move upward in altitude.
(d)
Explain
why the rate of decrease of air pressure is not constant, i.e., it drops by 300
mb in the first 3000 meters (from 0 m to 3000 m), 200 mb over the next 3000
meters (from 3000 m to 6000 m), and 170 mb over the next 3000 meters (from 6000
m to 9000 m).