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Lecture 24
Terrestrial planets: atmospheres
Atmospheres are created by three processes:
Outgassing
Evaporation/sublimation
Impacts
All planets probably had minimal (primary. H,He) atmospheres at some point after they formed
How do you keep an atmosphere?
Gravity attracts gas towards the planet. Thermal motions of the gas can cause it to escape. Gravity determines the escape velocity Temperature determines the thermal velocity.
Large planets hold onto atmospheres easier than small planets
Cooler planets hold onto atmospheres easier than hot ones.
Original primary atmospheres (H,He) were swept away from the terrestrial planets early in their life.
Jovian planets still have these primary atmospheres
Present day terrestrial atmospheres are secondary atmospheres, formed primarily by outgassing (mostly carbon dioxide - CO2)
or, in the case of the Earth, a tertiary atmosphere of oxygen and nitrogen (secondary atmosphere modified by life and presence of liquid water)
Which moons have atmospheres?
Jupiter's Io (tenuous sulfur dioxide) Jupiter's Europa (tenuous oxygen) Saturn's largest moon Titan (dense nitrogen &
methane) Neptune's largest moon Triton (tenuous nitrogen &
methane).
Moon and Mercury
“black sky”
The little atmosphere that exists consists of particles of the solar wind that are temporarily trapped.
Mars
Very little atmosphere today (CO2)
Mars had standing and running water on its surface in the past.
Therefore, it must have had a more substantial atmosphere in the past
Does it have water today? Yes - frozen in polar ice caps and possibly beneath its soil
Earth
A moderate atmosphere today
Mostly nitrogen (N2), with some oxygen (O2), carbon dioxide (CO2), etc.
Enough to enable liquid water to exist (temperature and pressure adequate)
Together the air & water produce erosion
Venus
Densest atmosphere of all Terrestrials
Mostly CO2
Temperature at surface hot enough to melt lead
Pressure at the surface ~ 90 times that on Earth
Perpetual cloud cover, sulfuric acid rain
How do we account for these differences?
Composition of outgassed gasses
The dominant gasses arising from outgassing
were carbon dioxide and water vapor, with minor
amounts of nitrogen, sulfer, argon, …
Each terrestrial planet’s outgassed atmosphere
was roughly the same.
How do we account for these differences?
Composition of outgassed gasses
(Carbon dioxide and water vapor)
Temperature appropriate for liquid water?
Distance from the sun, amount of greenhouse
gasses in atmosphere.
Oceans absorb carbon dioxide -> carbonate rocks
How do we account for these differences?
Composition of outgassed gasses
(Carbon dioxide and water vapor)
Temperature appropriate for liquid water?
(Carbon dioxide dissolves in oceans)
Interaction of light and atmospheres
Dissociation of water and ammonia molecules
by UV light, and warming by the greenhouse effect
How do we account for these differences?
Composition of outgassed gasses
(Carbon dioxide and water vapor)
Temperature appropriate for liquid water?
(Carbon dioxide dissolves in oceans)
Interaction of light and atmospheres
(dissociation and the greenhouse effect)
Photosynthetic life - generation of oxygen
• X rays
• ionize atoms & molecules
• dissociate molecules
• absorbed by almost all gases
• Ultraviolet (UV)
• dissociate some molecules
• absorbed well by O3 & H2O
• Visible (V)
• passes right through gases
• some photons are scattered
• Infrared (IR)
• absorbed by greenhouse gases
Interactions of light with atmospheric gasses
Exosphere
hottest layer, v. rarified
Thermosphere
absorbs X-rays, ionized, ionosphere, reflects some radio, aurora
Mesosphere• weakly absorbs UV
Stratosphere• strongly absorbs UV,
ozone (O3), stratified (no convection)
Troposphere• absorbs IR (greenhouse);
convective; weather
The greenhouse effect Planets heat up by absorbing the Sun’s visible light
Planets cool off by radiating infrared out to space
Greenhouse gasses trap infrared radiation in
troposphere (lowest level of atmosphere), heating lower
atmosphere.
greenhouse gasses (e.g., H2O, CO2, CH4 -
methane) transmit visible light but absorb
infrared light
Greenhouse effect raises temperature of lower atmosphere
Greenhouse effect is critical to the existence of life on Earth – it raises temperatures to “habitable” level, permits liquid water
Terrestrial planets: atmospheres Question: Why does Venus have so much more
atmosphere than Earth? The answer is found in what Venus’
atmosphere is made of: CO2 (carbon monoxide)
What happens if there is a lot of CO2 in a planet’s atmosphere?
Due to the large amount of CO2 in its atmosphere, the surface temperature on Venus is over 700 K, instead of the 230 K that it should be at this distance from the Sun.
Does this also explain why Venus has so much atmosphere???
YES!
because water can exist in liquid form On Earth there are oceans
Original CO2 has dissolved into oceans,
rocks (carbonates) which keeps levels of CO2 just balanced in
atmosphere keeps planet WARM but not HOT
if planet were hotter, CO2, H2O would
be boiled out of oceans and baked out of rocks more CO2, H2O enter Atmosphere
Evolution of Atmospheres:
Earth vs. Venus
Evolution of Atmospheres:
Earth vs. Venus
Liquid water may have existed early in Venus’ history – but most vaporized into atmosphere: T was hotter on Venus
H2O vapor is a greenhouse gas - trapped energy making planet hotter; eventually T so high that water boils
‘runaway’ because more H20 goes into the Atmosphere as it evaporates; no water left on planet to dissolve CO2 – out of balance!
eventually stabilized when H20 broken down by UV sunlight and no further CO2 to bake out of the Venus surface
Earth has about the same amount of CO2 as Venus
Much of the Earth’s CO2 is ‘frozen’ into the rocks
However, if we could raise the temperature of our atmosphere a little bit, it would release a little bit more CO2 into the air
This would trap a little bit more heat, raising the temperature a little bit more…
This would release a little bit more CO2…
…which would trap a little bit more heat…
…which would raise the temperature a little bit more…
…which would release a little bit more CO2…
…which would trap a little bit more heat…
…which would raise the temperature a little bit more…
…which would release a little bit more CO2…
You get the idea!
This is called the runaway greenhouse effect
It happened on Venus because Venus is closer to the Sun
So - Earth has less atmosphere because most of our CO2 is still frozen in rocks
Global warming concern
There has been a large Increase in atmospheric CO2
Human activity is responsible for this increase.
CO
2 is a strong greenhouse gas
There is a strong correlation between the increase in carbon dioxide in the atmosphere and the global temperature.
Essentially all evidence indicates that human activity is a significant contributor to this trend (50%, 100% ???).
Can it be halted? reversed?
red) Ozone is broken apart by ultraviolet radiation.
What Determines a Planet’s Surface Temperature?
In the absence of the Greenhouse Effect:
the planet's distance from the Sun the planet’s overall reflectivity
• the higher the albedo (reflectivity), the less light absorbed planet cooler
What Determines a Planet’s Surface Temperature?
Greenhouse Effect. cannot change incoming Sunlight, so it cannot
change the total energy returned to space it increases the energy (heat) in lower atmosphere,
keeping the surface warmer It works like a blanket
Greenhouse Effect on the Planets
Greenhouse Effect warms Venus, Earth, & Mars on Venus: it is very strong on Earth: it is moderate on Mars: it is weak avg. temp. on Venus & Earth would be freezing
without it
Global warming concern
There has been a large Increase in atmospheric CO2
Human activity is responsible for this increase.
CO
2 is a strong greenhouse gas
There is a strong correlation between the increase in carbon dioxide in the atmosphere and the global temperature.
Essentially all evidence indicates that human activity is a significant contributor to this trend (50%, 100% ???).
Can it be halted? reversed?