2. 2.1 The Earth is closest to the Sun during the:
Northern Hemisphere winter
Northern Hemisphere summer
Southern Hemisphere spring
Southern Hemisphere fall
Southern Hemisphere winter

3. 2.1 The Earth is closest to the Sun during the:
Northern Hemisphere winter
Northern Hemisphere summer
Southern Hemisphere spring
Southern Hemisphere fall
Southern Hemisphere winter
Earth-Sun Relationships
Earth’s Motions
Revolution, refers to Earth’s movement in a slightly elliptical orbit around the Sun. The distance between Earth and Sun averages about 150 million kilometers (93 million miles). Because Earth’s orbit is not perfectly circular, however, the distance varies during the course of a year. Each year, on about January 3, our planet is about million kilometers (91.5 million miles) from the Sun, closer than at any other time—a position called perihelion. About six months later, on July 4, Earth is about million kilometers (94.5 million miles) from the Sun, farther away than at any other time—a position called aphelion.

4. 2.2 The motion that refers to Earth’s movement around the Sun is called
Rotation
Perihelion
Revolution
Aphelion
Ecliptic

5. 2.2 The motion that refers to Earth’s movement around the Sun is called
Rotation
Perihelion
Revolution
Aphelion
Ecliptic

6. 2.3 What is the name for the point in the Earth’s orbit where it is closest to the Sun?
Perihelion
Declination
Zenith
Sub-orbital
Aphelion

7. 2.3 What is the name for the point in the Earth’s orbit where it is closest to the Sun?
Perihelion
Declination
Zenith
Sub-orbital
Aphelion
Earth-Sun Relationships
Earth’s Motions
Revolution, refers to Earth’s movement in a slightly elliptical orbit around the Sun. The distance between Earth and Sun averages about 150 million kilometers (93 million miles). Because Earth’s orbit is not perfectly circular, however, the distance varies during the course of a year. Each year, on about January 3, our planet is about million kilometers (91.5 million miles) from the Sun, closer than at any other time—a position called perihelion. About six months later, on July 4, Earth is about million kilometers (94.5 million miles) from the Sun, farther away than at any other time—a position called aphelion.

8. 2.4 The primary reason for the seasons is:
Annual variations in the energy output of the Sun
The Earth’s orbital tilt relative to the plane of the ecliptic
The elliptical orbit of Earth
Changes in the daily weather
The distance of the Earth from the Sun

9. 2.4 The primary reason for the seasons is:
Annual variations in the energy output of the Sun
The Earth’s orbital tilt relative to the plane of the ecliptic
The elliptical orbit of Earth
Changes in the daily weather
The distance of the Earth from the Sun

10. 2.5 On the Northern Hemisphere winter solstice, the noon sun has an altitude of 90° above the horizon at the:
North pole
Equator
Tropic of Cancer
Tropic of Capricorn
The Arctic Circle

11. 2.5 On the Northern Hemisphere winter solstice, the noon sun has an altitude of 90° above the horizon at the:
North pole
Equator
Tropic of Cancer
Tropic of Capricorn
The Arctic Circle

12. 2.6 Which of the following dates is closest to the Southern Hemisphere summer solstice?
June 21
March 21
September 21
December 21
None of these are correct

13. 2.6 Which of the following dates is closest to the Southern Hemisphere summer solstice?
June 21
March 21
September 21
December 21
None of these are correct

14. 2.7 Which one of the following statements is true about the equinoxes?
They occur in June and December.
The Sun’s vertical rays are striking either the Tropic of Cancer or the Tropic of Capricorn.
Days and nights are equal in length everywhere.
The length of daylight at the Arctic and Antarctic Circles is 24 hours.
Both b and c are correct.

15. 2.7 Which one of the following statements is true about the equinoxes?
They occur in June and December.
The Sun’s vertical rays are striking either the Tropic of Cancer or the Tropic of Capricorn.
Days and nights are equal in length everywhere.
The length of daylight at the Arctic and Antarctic Circles is 24 hours.
Both b and c are correct.

16. 2.8 What is the energy associated with motion called?
Kinetic energy
Potential energy
Vibrational energy
Molecular motion energy
Friction

17. 2.8 What is the energy associated with motion called?
Kinetic energy
Potential energy
Vibrational energy
Molecular motion energy
Friction
Energy, Temperature, and Heat
Forms of Energy: Kinetic Energy
Energy can be defined simply as the capacity to do work. Work is done whenever matter moves. Energy associated with an object by virtue of its motion is described as kinetic energy. A simple example of kinetic energy is the motion of a hammer when driving a nail. Because of its motion, the hammer is able to move another object (do work). The faster the hammer is swung, the greater its kinetic energy (energy of motion). Similarly, a larger (more massive) hammer possesses more kinetic energy than a smaller one, provided that both are swung at the same velocity. Likewise, the winds associated with a hurricane possess much more kinetic energy than do light, localized breezes because they are both larger in scale (cover a larger area) and travel at higher velocities.

18. 2.9 A measure of the kinetic energy of molecules in a substance is called
Melting
Latent heat
Heat
Temperature
Conduction

19. 2.9 A measure of the kinetic energy of molecules in a substance is called
Melting
Latent heat
Heat
Temperature
Conduction

20. 2.10 The Earth receives energy from the Sun by:
Convection
Radiation
Conduction
Scattering
Emissivity

21. 2.10 The Earth receives energy from the Sun by:
Convection
Radiation
Conduction
Scattering
Emissivity

22. 2.11 Infrared radiation has a ________ wavelength than visible light.
Longer
Shorter
Equal
It is not possible to determine the wavelengths of energy.

23. 2.11 Infrared radiation has a ________ wavelength than visible light.
Longer
Shorter
Equal
It is not possible to determine the wavelengths of energy.

24. 2.12 The correct listing of radiation from shortest to longest wavelength is:
Radio, visible, infrared, ultraviolet
Infrared, visible, ultraviolet, radio
Ultraviolet, visible, infrared, radio
Visible, radio, ultraviolet, infrared
Ultraviolet, infrared, radio, visible

25. 2.12 The correct listing of radiation from shortest to longest wavelength is:
Radio, visible, infrared, ultraviolet
Infrared, visible, ultraviolet, radio
Ultraviolet, visible, infrared, radio
Visible, radio, ultraviolet, infrared
Ultraviolet, infrared, radio, visible

26. 2.13 The Stefan–Boltzmann Law gives the relationship between:
Energy and the wavelength
Emissivity and the wavelength
Energy and the temperature of an object
Temperature and longwave radiation
Temperature and the wavelength

27. 2.13 The Stefan–Boltzmann Law gives the relationship between:
Energy and the wavelength
Emissivity and the wavelength
Energy and the temperature of an object
Temperature and longwave radiation
Temperature and the wavelength
Mechanisms of Heat Transfer
Laws of Radiation
Hotter objects radiate more total energy per unit area than do colder objects. The Sun, which has a surface temperature of 6000 K (10,000°F), emits about 160,000 times more energy per unit area than does Earth, which has an average surface temperature of 288 K (59°F). This concept is called the Stefan–Boltzmann law.

28. 2.14 What type of electromagnetic radiation is emitted by the Earth’s surface?
Visible
Microwaves
Gamma rays
Infrared
Ultraviolet

29. 2.14 What type of electromagnetic radiation is emitted by the Earth’s surface?
Visible
Microwaves
Gamma rays
Infrared
Ultraviolet
Mechanisms of Heat Transfer
Laws of Radiation
Hotter objects radiate more energy in the form of short-wavelength radiation than do cooler objects. We can visualize this law by imagining a piece of metal that, when heated sufficiently (as occurs in a blacksmith’s shop), produces a white glow. As it cools, the metal emits more of its energy in longer wavelengths and glows a reddish color. Eventually, no light is given off, but if you place your hand near the metal, the still longer infrared radiation will be detectable as heat. The Sun radiates maximum energy at 0.5 micrometer, which is in the visible range (Figure 2-14). The maximum radiation emitted from Earth occurs at a wavelength of 10 micrometers, well within the infrared (heat) range. Because the maximum Earth radiation is roughly 20 times longer than the maximum solar radiation, it is often referred to as longwave radiation, whereas solar radiation is called shortwave radiation.

30. 2.15 The process by which energy passes through the atmosphere without interacting with atmospheric gases or other particles is called
Reflectivity
Transmission
Absorption
Radiation
Albedo

31. 2.15 The process by which energy passes through the atmosphere without interacting with atmospheric gases or other particles is called
Reflectivity
Transmission
Absorption
Radiation
Albedo

32. 2.16 Which one of the following is true about reflection?
Light bounces back from an object at the same angle it hits the object.
It causes radiation to disperse forward and backward.
It causes diffused light.
It can only occur because light does not travel in a straight line.

33. 2.16 Which one of the following is true about reflection?
Light bounces back from an object at the same angle it hits the object.
It causes radiation to disperse forward and backward.
It causes diffused light.
It can only occur because light does not travel in a straight line.

34. 2.17 On average, what percentage of solar radiation is absorbed by the Earth’s surface?

35. 2.17 On average, what percentage of solar radiation is absorbed by the Earth’s surface?
What Happens to Incoming Solar Radiation?
When solar radiation strikes an object, three different things may occur: some energy may be absorbed; some energy may “bounce off” the object; and some energy may be transmitted – it is allowed to pass through without being absorbed. Figure 2-15 shows the fate of incoming solar radiation averaged for the entire globe. On average, about 50 percent of incoming solar energy is absorbed at Earth’s surface.

36. 2.18 What is the percentage of radiation reflected by an object called?
Albedo
Bowen ratio
Latent
Scattering
Emissivity

37. 2.18 What is the percentage of radiation reflected by an object called?
Albedo
Bowen ratio
Latent
Scattering
Emissivity
What Happens to Incoming Solar Radiation
Reflection and Scattering: Reflection and Earth’s Albedo
Reflection is the process whereby light bounces back from an object at the same angle and intensity (Figure 2-16a). The fraction of radiation that is reflected by an object is called its albedo. The albedo for Earth as a whole (planetary albedo) is 30 percent.

38. 2.19 Which of the following surfaces has the highest albedo?
Forests
Asphalt
Sandy beach
Fresh snow
Plowed field

39. 2.19 Which of the following surfaces has the highest albedo?
Forests
Asphalt
Sandy beach
Fresh snow
Plowed field
What Happens to Incoming Solar Radiation
Reflection and Scattering: Reflection and Earth’s Albedo
Figure 2-17 gives the albedos for various surfaces. Fresh snow and thick clouds have high albedos (good reflectors). By contrast, dark soils and parking lots have low albedos and thus absorb much of the radiation they receive. In general, light-colored surfaces tend to be more reflective than dark-colored surfaces and thus have higher albedos.

40. 2.20 Which is true of solar radiation reaching the Earth’s surface?
It is the primary energy input driving the Earth’s climate system.
It consists of diffused solar radiation.
It consists of direct solar radiation.
All of these are correct.
None of these are correct.

41. 2.20 Which is true of solar radiation reaching the Earth’s surface?
It is the primary energy input driving the Earth’s climate system.
It consists of diffused solar radiation.
It consists of direct solar radiation.
All of these are correct.
None of these are correct.

42. 2.21 The two most important heat absorbing gases in the lower atmosphere are:
Oxygen and nitrogen
Water vapor and carbon dioxide
Argon and oxygen
Ozone and chlorofluorocarbons
Carbon dioxide and carbon monoxide

43. 2.21 The two most important heat absorbing gases in the lower atmosphere are:
Oxygen and nitrogen
Water vapor and carbon dioxide
Argon and oxygen
Ozone and chlorofluorocarbons
Carbon dioxide and carbon monoxide

44. 2.22 Which one of the following produces the greenhouse effect?
Absorption and re-emission of visible light by the ground
Absorption and re-emission of ultraviolet radiation by the atmosphere
Absorption and re-emission of infrared radiation by the atmosphere
Absorption and re-emission of visible light by clouds
All of these are correct.

45. 2.22 Which one of the following produces the greenhouse effect?
Absorption and re-emission of visible light by the ground
Absorption and re-emission of ultraviolet radiation by the atmosphere
Absorption and re-emission of infrared radiation by the atmosphere
Absorption and re-emission of visible light by clouds
All of these are correct.

46. 2.23 Longwave radiation arriving at the surface:
Comes primarily from longwave radiation emitted by the atmosphere
Comes directly from the Sun
Comes from diffused solar radiation
Comes from direct solar radiation
Comes from ultraviolet radiation reflected from the bottom of clouds

47. 2.23 Longwave radiation arriving at the surface:
Comes primarily from longwave radiation emitted by the atmosphere
Comes directly from the Sun
Comes from diffused solar radiation
Comes from direct solar radiation
Comes from ultraviolet radiation reflected from the bottom of clouds

48. 2.24 The annual balance of Earth’s incoming and outgoing radiation and the energy balance between the surface and atmosphere is called
Earth’s energy budget
Albedo
Greenhouse effect
Radiative cooling
Absorption

49. 2.24 The annual balance of Earth’s incoming and outgoing radiation and the energy balance between the surface and atmosphere is called
Earth’s energy budget
Albedo
Greenhouse effect
Radiative cooling
Absorption