Deck 4: Atmospheric Energy and Global Temperatures

A)transmission;before
B)transmission;after
C)refraction;before
D)refraction;after
E)reflection;before

A)sensible heat.
B)latent heat.
C)radiation.
D)conduction.
E)convection.

A)gamma rays,X-rays,and ultraviolet radiation.
B)ultraviolet radiation and visible radiation.
C)visible and infrared radiation.
D)thermal infrared radiation.
E)microwaves and radio waves.

A)usually low at the equator.
B)generally greater at high latitudes because of day length.
C)greatest over low-latitude deserts with their cloudless skies.
D)inadequate to sustain life.
E)highest in the mid-latitudes due to seasonality.

A)refraction.
B)absorption.
C)reflection.
D)transmission.
E)scattering.

A)conduction.
B)absorption.
C)albedo.
D)scattering.
E)transmission.

A)It changes,depending upon the Sun angle.
B)It is greatest when the Sun is low in the sky.
C)It never changes-albedos are constant values.
D)It is less for frozen water than for liquid water.
E)It is greatest for rough waters.

A)reflection;albedo.
B)Rayleigh scatter;albedo.
C)reflection;refraction.
D)mirage;refraction.
E)Mie scatter;refraction.

A)Mie scattering.
B)refraction.
C)Rayleigh scattering.
D)transmission.
E)albedo.

A)its temperature increases.
B)its temperature decreases.
C)its temperature is unaffected.
D)refraction occurs.
E)diffuse radiation occurs.

A)high;higher
B)lower;higher
C)low;lower
D)moderate;extreme
E)higher;lower

A)direct insolation.
B)diffuse radiation.
C)direct radiation.
D)indirect insolation.
E)reflective radiation.

A)longwave radiation and ultraviolet light.
B)ultraviolet,visible,and near infrared radiation.
C)near infrared and far infrared (i.e. ,longwave radiation).
D)gamma rays,X-rays,and ultraviolet radiation.
E)microwaves and radio waves.

A)10 percent.
B)31 percent.
C)51 percent.
D)69 percent.
E)75 percent.

A)transmission happens.
B)Rayleigh scattering is the predominant effect.
C)refraction occurs.
D)it is usually not affected physically.
E)albedo increases.

A)Mie scattering.
B)refraction.
C)Rayleigh scattering.
D)transmission.
E)albedo.

A)absorption.
B)transmission.
C)refraction.
D)insolation.
E)reflection.

A)forests
B)asphalt
C)dry,light sandy soils
D)fresh snow
E)the Moon

A)oxygen and hydrogen
B)ozone and dust
C)nitrogen and oxygen
D)water vapor and carbon dioxide
E)helium and argon

A)the greenhouse effect
B)latent heat transfer
C)stratospheric ozone radiation
D)conduction from the surface
E)longwave radiation from Earth's surface

A)Averaged over a year,Earth's surface has an energy surplus.
B)Averaged over a year,Earth's surface has an energy deficit.
C)Averaged over a year,Earth's atmosphere has an energy budget.
D)Averaged over a year,Earth's atmosphere has an energy gain.
E)The Earth's energy is never in balance because surface deficits are greater than atmosphere surpluses.

A)contrails have a very limited effect on the Earth's energy budget.
B)contrails reflect more insolation than trap outgoing radiation from Earth.
C)contrails contribute more to cloud-albedo forcing than cloud-greenhouse forcing.
D)contrails are difficult to distinguish from natural cirrus clouds.
E)contrails contribute more to cloud-greenhouse forcing than cloud-albedo forcing.

A)conduction.
B)advection.
C)latent heat.
D)greenhouse heat.
E)counterradiation.

A)is completely unrelated to our Earth-atmosphere system,and should never have been used to describe global warming.
B)describes exactly how the Earth-atmosphere system operates.
C)is a useful,but inaccurate model since atmospheric gases do not trap,but absorb heat.
D)incorrectly describes shortwave energy transmission but perfectly encapsulates how longwave terrestrial radiation is trapped.
E)is antiquated and rarely used anymore to describe our Earth-atmosphere system.

A)There is an energy balance between energy gains and losses around 36° latitude.
B)There is year-round energy deficit at the Tropic of Capricorn.
C)The equator has an energy balance in the summer,but a deficit in the winter.
D)Energy imbalances between the tropics and the poles are negligible.
E)The greatest energy deficit occurs between the tropics.

A)A greenhouse allows longwave radiation to escape and mix with the surrounding air,unlike the Earth's atmosphere.
B)The glass of a greenhouse is designed to allow transmission of both longwave and shortwave radiation,whereas certain atmospheric constituents only allow transmission of shortwave radiation.
C)It is exceedingly rare for a greenhouse to contain carbon dioxide like the Earth's atmosphere contains.
D)Passage of longwave radiation to space is delayed by certain atmospheric constituents,but not trapped like an actual greenhouse.
E)A greenhouse is designed to artificially warm an area and has built in ventilation,whereas there is no such ventilation system in the Earth-atmosphere system.

A)high insolation
B)indirect solar radiation
C)consistent daylength
D)little seasonal variations
E)small diurnal and annual insolation differences

A)conduction - molecule-to-molecule heat transfer
B)advection - strongly vertical mixing
C)radiation - assimilation and conversion of
D)convection - strongly horizontal mixing
E)latent heat - energy that can be sensed

A)cool the planet in a process called cloud-albedo forcing.
B)warm the planet in a process called cloud-greenhouse forcing.
C)warm the planet in a process called cloud-albedo forcing.
D)cool the planet in a process called cloud-greenhouse forcing.
E)have no effect on the planet's temperature because insolation is constant.

A)strong vertical movement of air in the atmosphere.
B)strong horizontal movement of air in the atmosphere.
C)the molecule-to-molecule transfer of heat energy.
D)the behavior of something.
E)heat that can be sensed by humans as temperature.

A)global dimming.
B)the greenhouse effect.
C)cloud-albedo forcing.
D)global warming.
E)latent heat transfer.

A)air temperature reaches a maximum at noon when absorbed insolation also reaches a maximum.
B)air temperature reaches a maximum afternoon,whereas absorbed insolation reaches a maximum at noon.
C)air temperature maximum and minimums are not related to absorbed insolation.
D)air temperature reaches a minimum at midnight when there is no absorbed insolation.
E)air temperature minimum corresponds to maximum insolation absorption.

A)sensible heat.
B)latent heat.
C)radiation.
D)conduction.
E)convection.

A)advection.
B)convection.
C)conduction.
D)transmission.
E)diffusion.

A)insolation - shortwave radiation - UV,visible,and near infrared
B)insolation - longwave radiation - thermal infrared radiation
C)terrestrial radiation - shortwave radiation - UV,visible,and near infrared
D)terrestrial radiation - shortwave radiation - thermal infrared radiation
E)both insolation and terrestrial radiation - shortwave radiation - UV,visible,and near infrared

A)The equatorial zone is a region of net deficits.
B)The polar regions are areas of net surpluses.
C)The distribution shows an imbalance of net radiation from equator to poles.
D)More energy is lost than is gained in the equatorial regions.
E)The midlatitudes are the area of the largest surpluses throughout the year.

A)little seasonal variability
B)low sun angle
C)high albedo due to snow and ice
D)up to six months without insolation
E)large diurnal and annual insolation differences

A)conduction
B)convection
C)kinetic
D)latent
E)sensible

A)cool;absorption
B)cool;reflectivity
C)warm;absorption
D)warm;reflectivity
E)warm;conduction

A)comes primarily from infrared energy emitted by the atmosphere.
B)comes directly from the Sun.
C)comes from diffuse solar radiation.
D)comes from UV radiation reflected from the bottoms of clouds.
E)encompasses energy primarily in the visible portion of the electromagnetic spectrum.

A)a barometric thermometer.
B)a mercury thermometer.
C)a bulb mounted in direct sunshine.
D)an alcohol thermometer.
E)Aneroid thermometer.

A)is used exclusively in the United States.
B)places melting point of ice at 0° and was formerly called centigrade.
C)was developed by the British physicist Lord Kelvin.
D)was developed by Fahrenheit,who also developed the alcohol and mercury thermometers.
E)places melting point of ice at 32° and boiling at 212°.

A)near the poles.
B)over the subtropics.
C)in the tropics.
D)in the midlatitudes.
E)in continental interiors.

A)at the same time that maximum absorbed insolation occurs,because that is when maximum energy is available for heating the air.
B)before the time of maximum absorbed insolation,because the residual heat energy left over in the atmosphere from the previous day adds to the energy supplied by insolation.
C)before the time of maximum absorbed insolation occurs,because the thermosphere transfers heat energy to the surface during the early morning hours as the layers in the ionosphere become active.
D)after the time of maximum absorbed insolation,because an energy surplus accumulates in the atmosphere while the Sun is still high in the sky and reaches a peak in mid-afternoon.
E)after the time of maximum absorbed insolation,because the ground starts to reflect heat energy in the late afternoon,and this creates an energy surplus.

A)measured using a ground network of at least one station per 250,000 km2 across the globe.
B)often much cooler than air temperature due to vegetation cover.
C)highest in areas with high albedo and dense cloud cover.
D)a measure of the heating of the land surface and is distinct from air temperature.
E)typically much cooler than air temperature.

A)exhibits a lag of several hours between the plotted lines.
B)shows little or no relationship between the two variables.
C)shows that peak temperatures occur near noon,whereas peak insolation receipt is at 3:00 or 4:00 P.M.
D)coincides at noon.
E)indicates that absorbed insolation is constant,whereas daily air temperature is not.

A)during the night when +LW is at a maximum.
B)after dusk due to a lag effect of outgoing infrared radiation.
C)during daylight hours,peaking just after noon with the peak of insolation.
D)during the daylight hours,peaking just after sunrise.
E)around midnight when +SW is the highest.

A)convection and conduction.
B)evaporation of water.
C)reflection of insolation.
D)ground heating.
E)latent heat of evaporation.

A)astronomy.
B)meteorology.
C)micrometeorology.
D)microclimatology.
E)microastronomy.

A)the net energy expended for ground heating and cooling.
B)the balance of all radiation incoming and outgoing at Earth's surface.
C)the amount of insolation coming into the surface.
D)the amount of insolation not absorbed at the surface.
E)the sum of outgoing radiation from Earth,averaged over a year.

A)non-ventilated and black boxes,placed at ground level.
B)placed a few feet above the ground in louvered white boxes.
C)in black boxes placed in direct sunlight for maximum insolation absorption.
D)at ground level,in direct sunlight.
E)in shade or near buildings or other shelters.

A)the same as 273 Kelvin.
B)an average boiling temperature.
C)0 absolute temperature.
D)not possible on any scale.
E)freezing point of water.

A)twice as large as one Celsius degree.
B)the same size as one Celsius degree.
C)two times smaller than one Celsius degree.
D)the same size as one Fahrenheit degree.
E)twice as large as one Fahrenheit degree.

A)Energy is stored within the water.
B)Energy is released to the surface.
C)The surface is warmed.
D)Heat is transferred back and forth between the air and surface.
E)Energy flows into the ground by conduction.

A)a form of energy.
B)heat,as perceived by humans and other living things.
C)a function of insolation and wind speed.
D)measure of the average kinetic energy of individual molecules in matter.
E)a measure of the amount of heat in a substance.

A)-40°.
B)-273°.
C)0°.
D)212°.
E)10°.

A)heat.
B)insolation.
C)reflection.
D)outgoing infrared radiation.
E)NET R.

A)In the U.S. ,the solar energy arriving every 35 minutes is equivalent to the energy produced by fossil fuels in a year.
B)It can provide both heat and electricity.
C)Photovoltaic capacity has not increased in recent years.
D)New solar cell technology makes them suitable for rooftop tiles or shingles.
E)Growth of solar energy in the U.S.has lagged behind that of Europe.

A)near the poles.
B)over the subtropics.
C)in the tropics.
D)in the midlatitudes.
E)on the eastern side of continents.

A)movement.
B)evaporation.
C)cloud cover.
D)specific heat.
E)latitude.

A)higher;slowly
B)higher;quickly
C)lower;slowly
D)lower;quickly
E)equal;evenly

A)insolation.
B)altitude.
C)distribution of land and water.
D)latitude.
E)cloud cover.

A)altitude.
B)specific heat.
C)transparency.
D)evaporation.
E)movement.

A)93°F
B)96.5°F
C)103.5°F
D)107°F
E)89.5°F

A)They increase temperature minimums and temperature maximums.
B)They cover about 15 percent of Earth's surface at any one time.
C)They have a moderating influence on temperatures.
D)They decrease nighttime temperatures and increase daytime temperatures.
E)They have only a negligible effect on temperature and climate.

A)20 m (66 ft);30 m (100 ft)
B)100 m (330 ft);500 m (1,640 ft)
C)60 m (200 ft);300 m (1,000 ft)
D)30 m (100 ft);900 m (3,000 ft)
E)5 m (16.4 ft. );30 m (100 ft)

A)27.2°C
B)33.6°C
C)46.4°C
D)52.8°C
E)21.8°C

A)the height of a point on Earth's surface;the height above Earth's surface
B)the height above Earth's surface;the height of a point on Earth's surface
C)the height of a point on Earth's surface;the latitude at which a location occurs
D)Both elevation and altitude refer to the height above Earth's surface.
E)Both elevation and altitude refer to the height of a point on Earth's surface.

A)Northern Hemisphere temperatures are more strongly dominated by continentality than are Southern Hemisphere temperatures.
B)Southern Hemisphere temperatures are more strongly dominated by continentality than are Northern Hemisphere temperatures.
C)The Northern and Southern hemispheres are dominated equally by maritime influences.
D)The Northern and Southern hemispheres are dominated equally by continentality.
E)Continentality does not follow any hemispheric patterns.

A)The climates of the two cities are quite similar.
B)Annual temperatures for the city at the lower elevation are lower than those at the city at the higher elevation.
C)The city at the higher elevation has extremely cold winters (similar to those at high latitudes).
D)The city at the higher elevation has average monthly and yearly temperatures lower than the city near sea level.
E)The average annual temperatures for the city at the higher elevation are higher than the city at sea level.

A)Higher elevations experience higher temperatures during the day because they are closer to the Sun.
B)Higher elevations experience lower average temperatures during both day and night.
C)The density of air increases with increasing elevation creating overall warmer temperatures.
D)Temperatures at night are greater,though lower in the day,at higher elevations.
E)Temperatures increase with altitude and,therefore,are higher at higher elevations.

A)Evaporation tends to increase temperatures over land.
B)Evaporation tends to lower temperatures more over water bodies than over land.
C)Evaporation tends to increase the temperature over water.
D)Evaporation affects land more than ocean surfaces.
E)Evaporation affects the temperature of land surfaces and water bodies the same amount.

A)22
B)37
C)84
D)76
E)5

A)The maritime effect
B)Specific heat
C)Heat dome
D)Continentality
E)Opacity

A)Earth's tilt,rotation,revolution,and sphericity.
B)latitude,altitude,land-water heating differences,cloud cover,and ocean currents.
C)the distance of the Earth from the sun and sunspot activity.
D)the seasons and human activity.
E)latitude and elevation,only.

A)warmer;warmer
B)warmer;cooler
C)cooler;warmer
D)cooler;cooler
E)much warmer;much cooler

A)San Francisco experiences several months with average temperatures below the freezing point.
B)Annual temperature ranges in Wichita are greater than those in San Francisco.
C)Summer temperatures in San Francisco far exceed those of Wichita.
D)Minimum average temperatures in Wichita are consistently lowers than those in San Francisco.
E)On average,December temperatures in San Francisco tend to be lower than those in Wichita.

A)absorb;reflect
B)scatter;refract
C)reflect;absorb and counterradiate
D)reflect;scatter
E)scatter;absorb and counterradiate

A)Trondheim's high degree of continentality.
B)Trondheim's maritime location.
C)The urban heat island of Trondheim.
D)Thick cloud cover in Trondheim traps in longwave radiation.
E)Influence of the subpolar low pressure system.