Chapter Two - Test One

Question 1

Solar radiation accounts for more than ___ of the energy that heats the earth and its atmosphere
- This energy is not distributed evenly, however, as it varies by:

Answer 1

99. 9%
    - latitude; time of day; time of year.
    - It is this uneven distribution of energy that creates most of what we consider to be weather.

Question 2

Rotation:

Answer 2

earth rotates on its axis once per 24 hours

Question 3

Revolution:

Answer 3

earth orbits around the sun once per 365.25 days per year

Question 4

The Seasons
Regulated by the amount of solar radiation received by the surface of the Earth; which is dictated by:

1) angle at which the radiation strikes the surface:
2) length of the “day” (# of daylight hours)

Answer 4

radiation striking the earth perpendicularly is:

• much more intense than that striking at an angle (Fig 2.3)
• traverses through less atmosphere (Fig 2.4)
• length of days allow for more radiation to reach the earth’s surface (Table 2.2)
  Equinox ~ 12 hours everywhere

Question 5

Earth’s Orientation

• These changes are due to the Earth being tilted by 23.5º from the plane of its elliptical orbit around the sun (Fig 2.5)
• The Earth’s axis (center of rotation) points in the same direction into space all year long; as a result:

Answer 5

The NH: is tilted toward the sun in summer (northern hemisphere) is tilted away from the sun in winter

Question 6

Solar Elevation Angle (Noontime)

Figure 2.6 and Box 2.2 (The Analemma) provide ways to calculate the solar elevation angle (β) at local noon for any latitude and time of year. This angle can also be calculated using the following equation:

Answer 6

β =90-Phi-(23.5ºxcos((360(N+10))/365))

where: Phi is the latitude
N is the Julian day of the year (N=1… 365)

Question 7

Solar Radiation Equation - provides an instantaneous measure of the intensity of the solar radiation (Watts) per square meter (ignoring effects of atmosphere):

Answer 7

J = 1367 Watts/Meters^2 x sin β

Question 8

Summer Solstice “Astronomical start of summer”

Sun is at its highest position in the sky, as a result, radiation shines down on the surface:

Answer 8

~June 21 : Julian Day 173

• more directly than at any other time of the year.
• Longest “day” of the year

Question 9

Summer Solstice “Astronomical start of summer”

Answer 9

each latitude (in NH) will have:

- more than 12 hours of sunlight

- the farther north you go, the greater the # of daylight hours  	   (Table 2.2) 
- from Arctic Circle (66.5o N) north, 24 hours of sunlight
- The noon sun is directly overhead at 23.5ºN, the: Tropic of Cancer

Question 10

Notice that the sun actually rises north of east and sets north of ____ during Summer Solstice

Answer 10

west

Question 11

Winter Solstice “Astronomical start of winter”

Sun is at its lowest position in the sky, as a result, radiation shines down on the surface:

Answer 11

~ December 21 : Julian Day 356

• less directly than any other time of the year
• Shortest “day” of the year
• each latitude (in NH) will have less than 12 hours of sunlight
• the farther north you go, the
  lesser the # of daylight hours
• from Arctic Circle (66.5ºN)
  north, 24 hours of darkness
• The noon sun is directly
  overhead at 23.5ºS, the: Tropic of Capricorn

Question 12

Notice that the sun actually rises ____ of east and sets south of west during Winter Solstice

Answer 12

south

Question 13

Autumnal Equinox “Astronomical start of autumn”

Answer 13

( ~ September 23 : Julian Day 266)

Question 14

Vernal Equinox “Astronomical start of spring”

Answer 14

( ~ March 20 : Julian Day 80)

Question 15

In an equinox, each latitude (NH and SH) will have:

Answer 15

Exactly 12 hours of sunlight and 12 hours night (hence the name equinox)
- The noon sun is directly overhead (90º from the horizon) at: 0.0º (Equator)

Question 16

Energy:

Answer 16

the capacity to do work

Question 17

Kinetic Energy (KE):

Answer 17

energy associated with an object by virtue of its motion; KE = ½ mv2

Question 18

Potential Energy (PE):

Answer 18

energy associated with an object by virtue of its position with respect to gravity
PE = mgh

Question 19

Temperature:

Answer 19

degree of hotness or coldness of an object

• is a form of Kinetic energy
• or a measure of the average speed of all of the atoms and molecules of that object
• As The Speed Increases, T Increases
• As the speed decreases, T decreases

Question 20

Heat:

Answer 20

is energy in the process of being transferred between substances (or within a substance):

- because of a difference in temperature (∆T)
- transfer is always hot to cold

Question 21

Mechanisms of Heat Transfer

Answer 21

Conduction, Convection/Advection, Radiation

Question 22

Conduction

Answer 22

Transfer of heat by molecular activity from one substance to another (or within a substance)

• transfer is always from hot to cold
• the larger the ∆T, the faster the transfer
• solids, especially metals are excellent conductors

Question 23

Air is a poor conductor, as a result:

Answer 23

conduction of heat within the atmosphere only occurs at the earth’s surface (lowest few inches) where the ∆Ts are very large

Question 24

Convection

Answer 24

Vertical transfer of heat by the mass movement or circulation of a fluid (water, air)

- thermals
- convective circulation

Question 25

Advection

Answer 25

Horizontal transfer of heat by the mass movement or circulation of a fluid (water, air)
- warm advection

Question 26

Radiation

Answer 26

Transfer of heat through the propagation of electromagnetic waves (Fig 2.11), which only release heat when they strike an object
- The units of these wave lengths (λ) are called: microns or micrometers (µ)
1 µ = 1 x 10^-6

Question 27

Solar Radiation

Answer 27

• transfer occurs at the speed of light (3x10^8 m/s)
• transfer does not need a medium (molecules), therefore it can occur in the vacuum of space

As the wavelength (λ) of the radiation decreases, the amount of energy it carries increases; Gamma least safe

Question 28

uv – C:

Answer 28

0.20 – 0.29 µ - most harmful (absorbed by Ozone)

Question 29

uv – B:

Answer 29

0.29 – 0.32 µ - produces sun burning, skin cancer

Question 30

uv – A:

Answer 30

0.32 – 0.40 µ - produces sun burning

Question 31

The NWS and EPA have established a:

Use sunscreen with a high SPF (Sun Protection Factor) number, which indicates:

Answer 31

UV Index (Box 2.3, Table 2.B) to bring attention to the dangers of over exposure to the sun; 
the Index ranges from:	0-2 	(Minimal)  to 10-15 (Very High) 

Percentage of UV – B that is blocked

Question 32

Laws of Radiation

Answer 32

1) All objects emit radiant energy over a range of λ’s
2) Hotter objects emit more radiant energy than colder objects (per area)
3) The hotter the radiating object, the shorter is the λ of maximum emission
4) Objects that are good absorbers of radiation at a particular λ are also good emitters at that same λ

Question 33

Stefan - Boltzmann Law

Answer 33

E = σ T^4

(Hotter objects emit more radiant energy than colder objects)

E : is the energy emitted by the body Watts m^-2
σ: is the Stefan Boltzmann constant:
(5.67 x 10^-8 Watts m^-2 K^-4)
T : is the temperature of the body (K)
-Notice that since T is raised to the fourth power, even a small increase in T will result in a large increase in emitted energy.

Question 34

Wien’s Displacement Law

Answer 34

λmax = C / T

(The hotter the radiating object, the shorter is the λ of maximum emission)

λmax : wavelength (µ) of maximum radiation emitted
T : is the temperature of the object (K)
C: is Wien’s constant 2898 µ K

Question 35

Earth’s (Terrestrial) Radiation as:

Answer 35

Longwave Radiation

Question 36

Sun’s (Solar) Radiation as:

Answer 36

Shortwave Radiation

Question 37

Although the sun emits at a maximum rate around 0.5 µ, it also emits radiation at other wavelengths as seen in the:

Answer 37

Solar Electromagnetic Spectrum

Question 38

Human’s eyes are sensitive to radiation at wavelengths between 0.4 and 0.7 µ, this is called the:

Answer 38

Visible Range (43% of total)

Question 39

Below the visual range are:

Answer 39

Ultraviolet Wavelengths (7%)

Question 40

Above the visual range are:

Answer 40

Infrared Wavelengths (49%)

Question 41

Kirchhoff’s Law

Some objects, called Blackbodies are unique in that they are both:

Answer 41

• perfect emitters: emit 100% of the radiation possible (for a given T)
• perfect absorbers: absorb 100% of the radiation incident upon them across all possible λ

Question 42

Both the Earth and the Sun approach being ____ in that they absorb and emit with nearly 100% efficiency

Answer 42

Blackbodies

Question 43

The atmosphere does not act like a ____!

Rather, all of the molecules of gases (N2, O2, etc) that comprise the atmosphere each act like:

Answer 43

Black Body;

Selective Absorbers/Emitters, they absorbs/emit very well at some λ , but absorb/emit very poorly at other λ.

Question 44

Most gases, except O3 and O2:

Answer 44

Do not absorb short λ emitted by the sun
- most of the absorption of short λ by O3 occurs in the stratosphere and is responsible for the warm temperatures observed there

Question 45

Most gases, especially H20 and CO2:

Answer 45

Do absorb some of the long λ emitted by the earth
- the most notable exception being the:
“Atmospheric Window” that exists at λ between 8 and 12 µ that allows the earth to cool at night through: Radiational Cooling

Question 46

Clouds are present, which act to “ ____ the Atmospheric Window”, keeping cloudy nights warmer than clear nights.

Answer 46

close

Question 47

Because the atmosphere is largely transparent to short λ solar radiation, but more absorptive of the long λ:

Answer 47

The atmosphere is heated from the ground up.

This is why, on average, the temperature decreases 6.5ºC for every 1000 meter increase in hgt., which as seen earlier is the: Normal Lapse Rate

Question 48

As H20, CO2 and the other Greenhouse gases absorb the longwave radiation, they gain Kinetic Energy, causing them to warm and in turn re-radiate some energy back to the earth
(Figs. 2.19. 2.20), as a result:

Answer 48

The earth’s lower atmosphere is 33ºC (59ºF) warmer than it would be w/o the gases that comprise it !

This phenomenon is called the “Greenhouse Effect”

Because, like the glass in a greenhouse, the gases in the atmosphere allow solar radiation to penetrate, but absorb or trap the terrestrial radiation.

Question 49

The concentration of several of these Greenhouse Gases (CO2, CH4, N2O) have been:

Answer 49

increasing due to anthropogenic emissions, which, as we saw Chapter 1, have contributed to an increase in global temperatures.