Post on 12-Feb-2016
description
Chapter 7Water & Atmospheric
Moisture
Hydrological Cycle
Hydrogen Bonding
Credit: http://bio.winona.msus.edu/berg/ILLUST/H-bond5.gif
Water is a polar or charged molecule
+ charge on the hydrogen side & a
- charge on oxygen
hydrogen bonding is the attraction between oxygen
and hydrogen atoms on adjacent
molecules
polar covalent bonds
Phenomena due to hydrogen bonding
surface tension – cohesive force that pulls a surface closer together – water has highest
surface tension
capillary action - ascent of water up a tube thanks to the ‘pull’ of water molecules on one
another
Phenomena due to hydrogen bonding
Solvent – Water is an excellent solvent as it can electrically “surround a salt”
http://www.brooklyn.cuny.edu/bc/ahp/SDPS/SD.PS.water.html
720 calories required -->
<-- 720 calories released
Latent Heat Exchanges in the Environment
Show water phases shockwave
Measures of Humidity humidity - refers to water vapor
in airrelative humidity - ratio of the water vapor
content of air to the maximum possible water vapor content at that temperature
specific humidity - mass of water vapor (g) divided by the mass of air (kg) – independent of changes in pressure,
volume, and temperature
dew point temperature - temperature at which air is saturated with water vapor
water vapor capacity is set by air temperature
Saturation Vapor Pressure vs T
0
10
20
30
40
50
60
70
80
-20 -15 -10 -5 0 5 10 15 20 25 30 35 40Temperature (C)
SVP
(mba
r)
How much water can air hold?
saturation vapor pressure is the maximum amount of water air can
holdrule of thumb - slope is ~ 1.5
mbar/°C in typical ambient range
think of this like the amount of sugar you can dissolve in coffee or tea before it precipitates
out
air in the tropics can hold about 10x as much water vapor as air at the
poles
the saturation vapor density (or pressure) roughly doubles for
every 10 C increase
Figure Credit: “Earth’s Climate” by W.
Ruddiman
Specific &
Relative Humidity
RH = (SH/max SH)*100
RH = (20/28)*100 = ~71%
Diurnal Variations in Relative Humidity
temperature & RH can be anti-correlated
-if the specific humidity is
constant & daily heating occurs
Dew Point
if dew point is close to the ambient air
temperature,
relative humidity is very
high
Saturation Vapor Pressure vs T
0
10
20
30
40
50
60
70
80
-20 -15 -10 -5 0 5 10 15 20 25 30 35 40Temperature (C)
SVP
(mba
r)
Tdew
Dew Point Temperature
air is saturated when its water vapor content equals its water holding capacity
(RH = 100%)this temperature is the dew
point RH < 100%
Measuring Relative Humidityhair absorbs water
vapor and this increases its length
think about how your hair gets in
very humid climates
this system works so well that it was used for over 200
years!
Measuring Relative Humidity IIsling psychrometer
the principles of sling psychrometry
2 thermometers side by sideone is a ‘dry-bulb’
thermometer which measures ambient
temp.other is a ‘wet bulb’ thermometer that is wetted by a wick -
twirling drives evaporation and
depression of temp.
would the wet bulb temperature be
more depressed in a dry or a wet environment?
Atmospheric Stabilitythink of a packet or parcel of air to describe a mass with certain humidity and
temperature characteristics
stability refers to the tendency of an air
parcel to rise or sink
air rises because pressure
decreases with height -
rising air expands and does work, releasing
heatThis is called
adiabatic heating
DAR – Dry Adiabatic Rate
DAR – Dry Adiabatic Rate
Different kinds of lapse rates
Air temperature (Tair)
Altit
ude
(km
)
DAR ~ -10°C/km
MAR ~ -6°C/km
Avg lapse rate ~ -6.5°C/km
this is the environmental lapse rate
we discussed
condensation releases heat (~2500 J/g at
0°C)
DAR - dry adiabatic rateMAR - moist adiabatic
rate
environmental lapse rate (ELR) - the local, background change in air temperature with
heightunstable air - describes an air parcel that is more buoyant than its surrounding air (will
rise) stable air - describes an air parcel that is the same temperature or colder than
surrounding air (will fall or stay at the same elevation)
moist adiabatic rate (MAR) – the rate at which saturated air temperature
decreases with height
dry adiabatic rate (DAR) – the rate at which dry air temperature decreases with
height
we think of three ‘regimes’ of
stability
rising parcel cools faster than surrounding
air (it stays more dense)
rising parcel cools more slowly than surrounding
air (it stays more buoyant)
surrounding air cools at 12 °C/km
buoyancy>gravityUnstable air
surrounding air cools at 5 °C/km
buoyancy<gravityStable air
surrounding air cools at 7 °C/km
buoyancy<gravity if DAR
buoyancy>gravity if MAR
Conditionally unstable air
Shockwave of stability
Precipitation across the Sierras
Credit: S. Booth, Sierra College http://geography.sierra.cc.ca.us/booth/Physical/chp6_precip/oro_precip.jpg
what about temperature gradients?
Elev
atio
n (k
m)
lapse rate type
25 C
15 C
9 C
19 C
29 C
DAR MAR DAR DAR
1 km
2 km
air is compressed and is heated during descent
air temperature on the east side is greater
cross section of the Sierras
DAR
DARMAR
Elev
atio
n (k
m)
Temperature
LCL
LCL = lifting condensation level - the height at which an air parcel reaches 100% RH and
condensation occurs
Cloud formation
how do clouds form?
what are clouds?aggregations of suspended microscopic
water droplets and ice crystals
air must be saturated with water vapor (RH = 100%) and there must be
microscopic nuclei for the vapor to condense onto
a typical raindrop is 2 mm in diameter, or ~a tenth of an inch
How much does a cloud weigh?
this cloud weighs ~1000 metric tons (106 kg)
how much energy was released when water vapor condensed into all these
cloud droplets?condensation releases 585 calories/g or
~2500 J/gThis is 2.5 trillion Joules!!
(for comparison, a 100 W light bulb consumes only 360,000 Joules in an
hour)
raindrop formation
snow formation
Cloud Types and Identificationclouds are flat (stratus),
puffy (cumulus), or wispy (cirrus)
horizontal, layered clouds are stratiformvertically developed
clouds are cumuliform
high, wispy clouds are cirroform
altocumulus clouds
stratus clouds
Cirrus clouds
Cumulus clouds
Cumulonimbus clouds
photo of a cumulonimbus
cloud taken from the space
shuttle
high level winds shear the tops of these clouds, giving them an
anvil appearance
Fog types and fog formationfog is clouds in contact with the
surface
there are, of course, different kinds of fog, but the basic mechanism of fog formation is the
same
if you are right in the middle of a cloud/fog bank, what is the relative
humidity?ok, what does this tell you about the ambient temperature and the dew point
temperature?fog is confined to a restricted layer - this
is because it is ‘capped’ by a thermal inversion
Advection Fogthis is an especially common type of fog
along the CA coastSanta Barbara locals refer to the early summer fog banks as the “June gloom”
the name gives a big hint about how this kind of fog is formed - remember that
advection is simply horizontal mixing of air in response to pressure gradients
think about what would set up a horizontal pressure gradient between the
coast and offshore air
along the CA coast, most of the fogbanks are advection fog - as the central valley
warms up, air rises and a pressure gradient is establishedwarm,
moist air offshore is pulled to the coast and fog
condenses over the
cold waters of
the CA current
Evaporation Fog
this fog forms when cold air overlies a warm body of water, like this lake in the
Sierras
the warm lake is evaporating water which then comes into contact with the cold air and
condensation occurs
Upslope Fogthis fog forms when warm, moist air is uplifted
by a mountain - it cools to its dew point and condenses tropical montane cloud forests occur where this
condensation occurs
Radiation Fog
this kind of fog forms over land that undergoes nighttime radiative cooling,
bringing the overlying air to its dew point
Fog Harvesting for Water by Human Communities
the idea is to strip water droplets out of fog banks and collect the water in containers
for later human usethe amount of
water that can be harvested is
surprisingly large
Plants Also Harvest Fog for WaterRedwood trees get much of their water from
fog