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Lecture 7-8: Energy balance and temperature (Ch 3)
• the diurnal cycle in net radiation, temperature and stratification
• the friction layer
• local microclimates
• influences on regional temperature patterns
The diurnal (daily) cycle in net radiation at the base of the atmos.
Q* = K* + L* = K - K + L - L
L* is typically negative
unless there is low
cloud cover
-L*
Surface energy budget
Q* = QH + QE + QG
Q*
QE
QH
(shows sign convention
only… each flux can have
either sign)
QG (= ground/lake/ocean heat flux)
an arbitrary example of a duirnal
cycle
Understanding the diurnal (daily) cycle in temperature
(similar principles apply to understanding the seasonal cycle)
Fig. 3-22a
Diurnal cycle in near-ground stratification
Daytime near-ground
temperature profile…
“unstable stratification”
z
Upward heat flow,
vertical mixing
enhanced (p65)
T=T(z)
Night-time near-ground
temperature profile…
“stable stratification”
Inversion …
downward heat
flow, mixing
damped
z
T=T(z)
The atmospheric boundary layer and the depth () of mixing
“free atmosphere”
• no friction
• vertical velocities steady and of order cm s-1 except
in clouds/over mountains

“friction layer” or “boundary layer”
z
• friction reduces windspeed
• variation of wind with height, instability (warm air
underneath cold), and flow around obstacles
produce turbulence
• vertical velocities fluctuate and are of order m s-1
Depth () of mixing varies in time/space
Depth of the ABL (i.e. magnitude of ) depends on the turbulence,
and increases with:
• stronger surface heating QH
• stronger wind
• rougher surface
summer
Order 1 km

winter
Order 100 m
dawn
dusk
Nocturnal Radiation Inversion
Cause …  ground cooling: Q* < 0, ie. outgoing longwave
radiation exceeds incoming longwave
 then air above cools by convection (stirring), QH < 0
Conditions for severest inversion …
 clear sky, dry air
 long night with light wind
Result: radiation frost?
Photo :Keith Cooley
Figs. 3-21
Complexity of local (sitespecific) effects on local
radiation and energy
balance… producing
“micro-climates” that
can be manipulated (eg.
windbreaks)
Latitudinal variation in net
allwave radiation
Averaged over a long period,
latitudinal heat advection by
ocean (25%) and atmosphere
(75%) rectifies the imbalance
Fig. 3-15
Why do we consider earth’s global climatological temperature Teq
to be at equilibrium (Sec. 3-2)?
Because there is a stabilizing feedback...
Let Teq be the change in Teq over time interval t. Then:
 Teq
t
area of earth’s surface
area of earth’s shadow
  R (1  a) S0  4  R   T
Rate of change 
2
gains
2
-
4
eq
losses
Where R is earth’s radius, S0 is the solar constant, a (=0.3) is the
planetary albeto,  (1) is the planetary emissivity and  is the
Stefan-Boltzmann constant. The proportionality constant involves the
heat capacity of the earth-atmosphere system. (In reality a, may
depend on Teq ).
At earth’s equilibrium temperature, there is balance...
 R (1  a) S0  4  R  T
2
2
4
eq
 0
Common factor cancels
Set a =0.3 and  =1 to obtain earth’s (radiative) equilibrium
temperature (Sec. 3-2).
Factors controlling temperature on regional & global time &
space scales
• Latitude
•solar radiation
• distribution of land & water**
• surface thermal inertia, surface energy balance
• topographic steering/blockage of winds
• Ocean Currents
• advective domination (horizontal heat transport)
•Elevation
• latitudinal temperature gradient is greatest in the winter hemisphere
• in summer (winter) temperature over land warmer (cooler) than over ocean
Fig. 3-18a
Why are water bodies “more conservative” in their temperature?
• solar radiation penetrates to some depth so warms a volume
• much of the available radiant energy used to evaporate water
• mixing of the water in the ocean/lake “mixed layer” ensures
heat deposited/drawn from a deep layer
• water has a much higher specific heat (4128 J kg-1 K-1) than
“land”