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Thermal Processes SOEE 1400 : Lecture 10 Radiation Processes reflected solar radiation 107 W m2 Incoming solar radiation 342 W m2 Outgoing longwave radiation 235 W m2 40 30 Reflected by clouds, aerosol & atmosphere 77 Absorbed by atmosphere 165 emitted by atmosphere 67 24 78 350 back radiation 324 Reflected by surface 30 40 168 24 Absorbed by surface 78 thermals Evapotranspiration SOEE1400 : Meteorology and Forecasting 390 324 Surface radiation Absorbed by surface 2 Adiabatic Processes • An adiabatic process is one in which no energy enters or leaves the system. • Many atmospheric processes are adiabatic (or nearly so) – particularly those involving the vertical movement of air. – Air is a poor thermal conductor, and mixing is often slow enough for a body of air to retain its identity distinct from the surrounding air during ascent. • Near-surface processes are frequently non-adiabatic. Adiabatic Processes: – Ascent of dry convective plumes – Large scale lifting/subsidence Non-Adiabatic Processes: – Radiative heating/cooling – Surface heating/cooling – Loss of water through precipitation – Addition of water from evaporation of precipitation falling from above – Condensation/evaporation within an airmass is known as “pseudoadiabatic” SOEE1400 : Meteorology and Forecasting 3 Lapse Rate Dry Adiabatic Lapse Rate 1km Altitude • Lapse Rate is the term given to the vertical gradient of temperature. • The fall in temperature with altitude of dry air that results from the decrease in pressure is called the Dry Adiabatic Lapse Rate = -9.8°C/km. SOEE1400 : Meteorology and Forecasting 9.8°C Temperature 4 Altitude • Condensation releases latent heat, thus saturated air cools less with altitude than dry air. • There is no single value for the saturated adiabatic lapse rate. It increases as temperature decreases, from as low as 4°C/km for very warm, tropical air, up to 9°C/km at -40°C. Dry Adiabatic Lapse Rate Saturated Adiabatic Lapse Rate SOEE1400 : Meteorology and Forecasting Temperature 5 Pressure & Temperature P5 P5 P4 P4 P3 P3 P2 P2 P1 P1 P0 cool z warm P0 • A column of air has pressure levels P1, P2, etc. • If the column is warmed, the air will expand and its density at any given level will decrease. • The vertical interval between pressure levels increases, so that at any given altitude the pressure in the warmer column is greater than in the cooler. • N.B. since the total mass of air in the column is constant, the pressure at the surface does not change SOEE1400 : Meteorology and Forecasting 6 Thickness • The thickness is the vertical spacing between two pressure levels (usually 1000 hPa and 500 hPa) • It can be shown that the thickness is directly proportional to the mean temperature in the layer: Δz = R <T> / g SOEE1400 : Meteorology and Forecasting 7 Cold-core Low intensifies with height Warm-core High intensifies with height L H L warm H warm cool Warm-core Low weakens with height, may form a high aloft cool warm cool cold-core High weakens with height, may form a low aloft H L cool L warm H cool warm SOEE1400 : Meteorology and Forecasting cool warm 8 • Mid-latitude low-pressure cells have colder air to the rear. • As a result, the axis of the low slopes towards the colder air Cold low L Warm high Sea-level isobars 500 mb contours SOEE1400 : Meteorology and Forecasting 9 • High pressure cells slope towards the warmest air aloft. • The centre of the cell at 3000m may be displaced 10-15° towards the equator. Cold low H Warm high Sea-level isobars 500 mb contours SOEE1400 : Meteorology and Forecasting 10 The Thermal Low (or ‘heat low’) • Thermal lows result from the strong contrast in surface heating between land and sea • Land heats up (solar radiation) and cools down (infra-red radiation) much more rapidly than ocean large diurnal cycle cross-coast temperature gradient • N.B. A thermal low results from fine, clear, warm weather, and thus differs from the depressions associated with cloud and bad weather. SOEE1400 : Meteorology and Forecasting 11 1. Start with a horizontally uniform pressure distribution. Solar radiation starts to warm land. Air near surface is warmed by land, convection mixes warm air upwards and whole boundary layer warms. 2. Air over land warms and expands. Can’t expand sideways, so column expand upwards produces high pressure aloft. H cool warm cool Thickness has increased with temperature. N.B. Surface pressure remains constant at this stage. SOEE1400 : Meteorology and Forecasting 12 3. Horizontal pressure gradient aloft drives a flow from over land to over ocean. H cool warm cool H cool L warm cool 4. Mass of air in column over land is reduced surface pressure falls to produce a surface low. High pressure aloft weakens, but is maintained by continued heating at surface. Surface pressure gradient drives flow from sea to land: the sea breeze. SOEE1400 : Meteorology and Forecasting 13 Note that steps 1-4 happen almost simultaneously, and continuously, throughout the day. As the air warms, the high pressure aloft is continually removing mass from the warm column (and it is gradually replaced by air drawn into the low pressure at low levels). SOEE1400 : Meteorology and Forecasting 14 5. When solar heating stops, pressure driven flows act to equalize pressure, restoring conditions to the initial uniform pressure field. H If land cools sufficiently at night, the reverse situation can be established. L L H warm cool warm Over large land masses there may be insufficient time over night for the sea breeze to reach regions far from the coast, and a weak surface low is maintained over night. This then deepens during the following days, and a heat low may be maintained for days or weeks, until synoptic conditions change. SOEE1400 : Meteorology and Forecasting 15 Sea Breeze • Formation of local thermal low over land, results in the formation of a sea-breeze • In-flowing cool air from the sea forms a sea-breeze front – a miniature cold front • Air ahead of the front is forced upward, contributing to the formation of cumulus. 950 mb 975 mb 1000 mb 25C 15C SOEE1400 : Meteorology and Forecasting 16 Sea breeze dynamics By day: At sunset • The air accelerates down the pressure gradient • Coriolis force turns it right (N. Hemisphere), over a period of hours • If the weather is warm, convective turbulence imposes a strong drag force on the air • The sea breeze front may be quite diffuse, due to turbulent mixing. • Convective turbulence becomes weak: drag force reduces rapidly • The sea breeze accelerates, and moves more rapidly inland (50200km) • A strong front may develop. SOEE1400 : Meteorology and Forecasting 17 Pressure as an indicator of temperature Because the depth of a layer of air increases as its temperature increases, we can use the thickness as an indicator of the mean temperature of the layer. Charts are usually produced of the thickness between 1000 and 500 mb. The thickness is usually quoted in deca-metres (10s of metres) A useful rule of thumb is that for 1000-500 mb layer depths less than 528 dm (5280 m) any precipitation will fall as snow rather than rain. SOEE1400 : Meteorology and Forecasting 18 SLP (mb) & 1000-500 thickness : 48hr forecast valid 0000 040922 SOEE1400 : Meteorology and Forecasting 19 SOEE1400 : Meteorology and Forecasting 20 SLP (mb) & 1000-500 thickness (dm) : 36hr forecast valid 0000 040930 SOEE1400 : Meteorology and Forecasting 21 SLP (mb) & 1000-500 thickness (dm) : analysis valid 0000 040930 SOEE1400 : Meteorology and Forecasting 22 2°C 12°C 850 mb Temperature (2°C contours), RH (%), wind (m s-1) : analysis valid 0000 040930 SOEE1400 : Meteorology and Forecasting 23 Surface temperature (2°C contours) and SLP (mb)(5mb contours) : analysis valid 0600 040930 SOEE1400 : Meteorology and Forecasting 24 The Thermal Wind • It is commonly observed that clouds at different altitudes move in different directions winds are in different directions. • The gradient of wind velocity (speed & direction) is called the (vertical) wind shear. • In the free air, away from surface (where friction effects complicate matters), the wind shear depends upon the temperature structure of the air. • The thermal wind is a theoretical wind component equal to the difference between the actual wind at two different altitudes. • Any two levels can be used, but unless otherwise stated the altitudes of the 1000mb and 500mb levels are usually used. • Note that the 1000mb level might be below sea level, and is usually within the boundary layer and thus influenced by friction effects at the surface. SOEE1400 : Meteorology and Forecasting 25 cold LOW warm 500mb HIGH Vg(1000) LOW 996 1000mb HIGH 1004 1008 SOEE1400 : Meteorology and Forecasting 26 500-1000 mb thickness 5580 5640 5700 LOW VG1000 5640 5700 VT LOW VG500 0 5760 60 5820 HIGH 120 Contours of 1000 mb surface 180 Contours of 500 mb surface HIGH SOEE1400 : Meteorology and Forecasting 27 • Note that cold air is to the left of the thermal wind vector (looking along wind) in the northern hemisphere, to the right in the southern hemisphere. • The decrease in temperature towards the poles results in a westerly thermal wind in the upper atmosphere in both hemispheres. • The largest meridional temperature gradient occurs in mid-latitudes across the polar front. • The thermal wind makes up a significant component of the jet-stream, located over the upper part of the polar front. SOEE1400 : Meteorology and Forecasting 28