Troposphere

The troposphere is the lowest layer of the atmosphere of Earth. It contains 80% of the total mass of the planetary atmosphere and 99% of the total mass of water vapor and aerosols, and is where most weather phenomena occur. From the planetary surface of the Earth, the average height of the troposphere is 18 km (11 mi; 59,000 ft) in the tropics; 17 km (11 mi; 56,000 ft) in the middle latitudes; and 6 km (3.7 mi; 20,000 ft) in the high latitudes of the polar regions in winter; thus the average height of the troposphere is 13 km (8.1 mi; 43,000 ft).

**Atmospheric circulation:** the *three-cell model* of the **circulation** of the planetary atmosphere of the Earth, of which the troposphere is the lowest layer.

The term troposphere derives from the Greek words tropos (rotating) and sphaira (sphere) indicating that rotational turbulence mixes the layers of air and so determines the structure and the phenomena of the troposphere. The rotational friction of the troposphere against the planetary surface affects the flow of the air, and so forms the planetary boundary layer (PBL) that varies in height from hundreds of meters up to 2 km (1.2 mi; 6,600 ft). The measures of the PBL vary according to the latitude, the landform, and the time of day when the meteorological measurement is realized. Atop the troposphere is the tropopause, which is the functional atmospheric border that demarcates the troposphere from the stratosphere. As such, because the tropopause is an inversion layer in which air-temperature increases with altitude, the temperature of the tropopause remains constant. The layer has the largest concentration of nitrogen.

The atmosphere of the Earth is in five layers:
(i) the **exosphere** at 600+ km;
(ii) the **thermosphere** at 600 km;
(iii) the **mesosphere** at 95–120 km;
(iv) the **stratosphere** at 50–60 km; and
(v) the troposphere at 8–15 km.
The distance from the planetary surface to the edge of the stratosphere is ±50 km, less than 1.0% of the radius of the Earth.

Structure

Composition

The Earth's planetary atmosphere contains, besides other gases, water vapour and carbon dioxide, which produce carbonic acid in rain water, which therefore has an approximate natural pH of 5.0 to 5.5 (slightly acidic). (Water other than atmospheric water vapour fallen as fresh rain, such as fresh/sweet/potable/river water, will usually be affected by the physical environment and may not be in this pH range.) Atmospheric water vapour holds suspended gasses in it (not by mass),78.08% nitrogen as N₂, 20.95% oxygen as O₂, 0.93% argon, trace gases, and variable amounts of condensing water (from ). Any carbon dioxide released into the atmosphere from a pressurised source combines with the carbonic acid water vapour and momentarily reduces the atmospheric pH by negligible amounts. Respiration from animals releases out of equilibrium carbonic acid and low levels of other ions. Combustion of hydrocarbons which is not a chemical reaction releases to atmosphere carbonic acid water as; saturates, condensates, vapour or gas (invisible steam). Combustion can releases particulates (carbon/soot and ash) as well as molecules forming nitrites and sulphites which will reduce the atmospheric pH of the water slightly or harmfully in highly industrialised areas where this is classed as air pollution and can create the phenomena of acid rain, a pH lower than the natural pH5.56. The negative effects of the by-products of combustion released into the atmospheric vapour can be removed by the use of scrubber towers and other physical means, the captured pollutants can be processed into a valuable by-product. The sources of atmospheric water vapor are the bodies of water (oceans, seas, lakes, rivers, swamps), and vegetation on the planetary surface, which humidify the troposphere through the processes of evaporation and transpiration respectively, and which influences the occurrence of weather phenomena; the greatest proportion of water vapor is in the atmosphere nearest the surface of the Earth. The temperature of the troposphere decreases at high altitude by way of the inversion layers that occur in the tropopause, which is the atmospheric boundary that demarcates the troposphere from the stratosphere. At higher altitudes, the low air-temperature consequently decreases the saturation vapor pressure, the amount of atmospheric water vapor in the upper troposphere.

Pressure

The maximum air pressure (weight of the atmosphere) is at sea level and decreases at high altitude because the atmosphere is in hydrostatic equilibrium, wherein the air pressure is equal to the weight of the air above a given point on the planetary surface. The relation between decreased air pressure and high altitude can be equated to the density of a fluid, by way of the following hydrostatic equation:

{\frac {dP}{dz}}=-\rho g_{n}=-{\frac {mPg_{n}}{RT}}

where:

g_n is the standard gravity
ρ is the density

z is the altitude
P is the pressure
R is the gas constant
T is the thermodynamic (absolute) temperature
m is the molar mass

Temperature

The planetary surface of the Earth heats the troposphere by means of latent heat, thermal radiation, and sensible heat. The gas layers of the troposphere are less dense at the geographic poles and denser at the equator, where the average height of the tropical troposphere is 13 km, approximately 7.0 km greater than the 6.0 km average height of the polar troposphere at the geographic poles; therefore, surplus heating and vertical expansion of the troposphere occur in the tropical latitudes. At the middle latitudes, tropospheric temperatures decrease from an average temperature of 15 °C (59 °F) at sea level to approximately −55 °C (−67 °F) at the tropopause. At the equator, the tropospheric temperatures decrease from an average temperature of 20 °C (68 °F) at sea level to approximately −70 to −75 °C (−94 to −103 °F) at the tropopause. At the geographical poles, the Arctic and the Antarctic regions, the tropospheric temperature decreases from an average temperature of 0 °C (32 °F) at sea level to approximately −45 °C (−49 °F) at the tropopause.

Altitude

A picture of Earth's atmosphere as viewed from an airplane, traveling over the Arctic.

The temperature of the troposphere decreases with increased altitude, and the rate of decrease in air temperature is measured with the Environmental Lapse Rate ( $-dT/dz$ ) which is the numeric difference between the temperature of the planetary surface and the temperature of the tropopause divided by the altitude. Functionally, the ELR equation assumes that the planetary atmosphere is static, that there is no mixing of the layers of air, either by vertical atmospheric convection or winds that could create turbulence.

The difference in temperature derives from the planetary surface absorbing most of the energy from the sun, which then radiates outwards and heats the troposphere (the first layer of the atmosphere of Earth) while the radiation of surface heat to the upper atmosphere results in the cooling of that layer of the atmosphere. The ELR equation also assumes that the atmosphere is static, but heated air becomes buoyant, expands, and rises. The dry adiabatic lapse rate (DALR) accounts for the effect of the expansion of dry air as it rises in the atmosphere, and the wet adiabatic lapse rate (WALR) includes the effect of the condensation-rate of water vapor upon the environmental lapse rate.

**Environmental Lapse Rate (ELR)**
Altitude Region	Lapse rate	Lapse Rate
(m)	(°C / km)	(°F / 1000 ft)
0.0 – 11,000	6.50	3.57
11,000 – 20,000	0.0	0.0
20,000 – 32,000	−1.0	−0.55
32,000 – 47,000	−2.8	−1.54
47,000 – 51,000	0.0	0.0
51,000 – 71,000	2.80	1.54
71,000 – 85,000	2.00	1.09

Compression and expansion

A parcel of air rises and expands because of the lower atmospheric pressure at high altitudes. The expansion of the air parcel pushes outwards against the surrounding air, and transfers energy (as work) from the parcel of air to the atmosphere. Transferring energy to a parcel of air by way of heat is a slow and inefficient exchange of energy with the environment, which is an adiabatic process (no energy transfer by way of heat). As the rising parcel of air loses energy while it acts upon the surrounding atmosphere, no heat energy is transferred from the atmosphere to the air parcel to compensate for the heat loss. The parcel of air loses energy as it reaches greater altitude, which is manifested as a decrease in the temperature of the air mass. Analogously, the reverse process occurs within a cold parcel of air that is being compressed and is sinking to the planetary surface.

The compression and the expansion of an air parcel are reversible phenomena in which energy is not transferred into or out of the air parcel; atmospheric compression and expansion are measured as an isentropic process ( $dS=0$ ) wherein there occurs no change in entropy as the air parcel rises or falls within the atmosphere. Because the heat exchanged ( $dQ=0$ ) is related to the change in entropy ( $dS$ by $dQ=TdS$ ) the equation governing the air temperature as a function of altitude for a mixed atmosphere is: ${\frac {\,dS\,}{dz}}=0$ where $S$ is the entropy. The isentropic equation states that atmospheric entropy does not change with altitude; the adiabatic lapse rate measures the rate at which temperature decreases with altitude under such conditions.

Humidity

If the air contains water vapor, then cooling of the air can cause the water to condense, and the air no longer functions as an ideal gas. If the air is at the saturation vapor pressure, then the rate at which temperature decreases with altitude is called the saturated adiabatic lapse rate. The actual rate at which the temperature decreases with altitude is the environmental lapse rate. In the troposphere, the average environmental lapse rate is a decrease of about 6.5 °C for every 1.0 km (1,000m) of increased altitude. For dry air, an approximately ideal gas, the adiabatic equation is: $p(z){\Bigl [}T(z){\Bigr ]}^{-{\frac {\gamma }{\,\gamma \,-\,1\,}}}={\text{constant}}$ wherein $\gamma$ is the heat capacity ratio ( $\gamma \approx \,$ 7⁄5) for air. The combination of the equation for the air pressure yields the dry adiabatic lapse rate: ${\frac {\,dT\,}{dz}}=-{\frac {\;mg\;}{R}}{\frac {\;\gamma \,-\,1\;}{\gamma }}=-9.8^{\circ }\mathrm {C/km}$ .

Environment

The environmental lapse rate ( $dT/dz$ ), at which temperature decreases with altitude, usually is unequal to the adiabatic lapse rate ( $dS/dz\neq 0$ ). If the upper air is warmer than predicted by the adiabatic lapse rate ( $dS/dz>0$ ), then a rising and expanding parcel of air will arrive at the new altitude at a lower temperature than the surrounding air. In which case, the air parcel is denser than the surrounding air, and so falls back to its original altitude as an air mass that is stable against being lifted. If the upper air is cooler than predicted by the adiabatic lapse rate, then, when the air parcel rises to a new altitude, the air mass will have a higher temperature and a lower density than the surrounding air and will continue to accelerate and rise.

Tropopause

The tropopause is the atmospheric boundary layer between the troposphere and the stratosphere, and is located by measuring the changes in temperature relative to increased altitude in the troposphere and in the stratosphere. In the troposphere, the temperature of the air decreases at high altitude, however, in the stratosphere the air temperature initially is constant, and then increases with altitude. The increase of air temperature at stratospheric altitudes results from the ozone layer's absorption and retention of the ultraviolet (UV) radiation that Earth receives from the Sun. The coldest layer of the atmosphere, where the temperature lapse rate changes from a positive rate (in the troposphere) to a negative rate (in the stratosphere) locates and identifies the tropopause as an inversion layer in which limited mixing of air layers occurs between the troposphere and the stratosphere.

Atmospheric flow

The general flow of the atmosphere is from west to east, which, however, can be interrupted by polar flows, either north-to-south flow or a south-to-north flow, which meteorology describes as a zonal flow and as a meridional flow. The terms are used to describe localized areas of the atmosphere at a synoptic scale; the three-cell model more fully explains the zonal and meridional flows of the planetary atmosphere of the Earth.

Three-cell model

**Zonal Flow:** a **zonal flow regime** indicates the dominant west-to-east flow of the atmosphere in the 500 hPa height pattern.

**Meridional Flow:** The meridional flow pattern of 23 October 2003 shows amplified troughs and ridges in the 500 hPa height pattern.

The three-cell model of the atmosphere of the Earth describes the actual flow of the atmosphere with the tropical-latitude Hadley cell, the mid-latitude Ferrel cell, and the polar cell to describe the flow of energy and the circulation of the planetary atmosphere. Balance is the fundamental principle of the model — that the solar energy absorbed by the Earth in a year is equal to the energy radiated (lost) into outer space. The Earth's energy balance does not equally apply to each latitude because of the varying strength of the sunlight that strikes each of the three atmospheric cells, consequent to the inclination of the axis of planet Earth within its orbit of the Sun. The resultant atmospheric circulation transports warm tropical air to the geographic poles and cold polar air to the tropics. The effect of the three cells is the tendency to the equilibrium of heat and moisture in the planetary atmosphere of Earth.

Zonal flow

A zonal flow regime is the meteorological term meaning that the general flow pattern is west to east along the Earth's latitude lines, with weak shortwaves embedded in the flow. The use of the word "zone" refers to the flow being along the Earth's latitudinal "zones". This pattern can buckle and thus become a meridional flow.

Meridional flow

When the zonal flow buckles, the atmosphere can flow in a more longitudinal (or meridional) direction, and thus the term "meridional flow" arises. Meridional flow patterns feature strong, amplified troughs of low pressure and ridges of high pressure, with more north–south flow in the general pattern than west-to-east flow.

References

"Troposphere". Concise Encyclopedia of Science & Technology. McGraw-Hill. 1984. It [the troposphere] contains about four-fifths of the mass of the whole atmosphere.
Danielson W, Levin J, Abrams E (2003). Meteorology. McGraw Hill.
Landau and Lifshitz, Fluid Mechanics, Pergamon, 1979
Lydolph, Paul E. (1985). The Climate of the Earth. Rowman and Littlefield Publishers Inc. p. 12.
Kittel C, Kroemer H (1980). Thermal Physics. Freeman. chapter 6, problem 11.
Landau LD, Lifshitz EM (1980). Statistical Physics. Part 1. Pergamon.
"The Stratosphere — Overview". University Corporation for Atmospheric Research. Archived from the original on 29 May 2018. Retrieved 25 July 2018.
"Meteorology – MSN Encarta, "Energy Flow and Global Circulation"". Encarta.Msn.com. Archived from the original on 2009-10-28. Retrieved 2006-10-13.
"American Meteorological Society Glossary – Zonal Flow". Allen Press Inc. June 2000. Archived from the original on 2007-03-13. Retrieved 2006-10-03.
"American Meteorological Society Glossary – Meridional Flow". Allen Press Inc. June 2000. Archived from the original on 2006-10-26. Retrieved 2006-10-03.

External links

"Layers of the Atmosphere". U.S. National Weather Service. Archived from the original on 2017-05-13.
Chemical Reactions in the Atmosphere

[1] "Troposphere". Concise Encyclopedia of Science & Technology. McGraw-Hill. 1984. It [the troposphere] contains about four-fifths of the mass of the whole atmosphere.

[DLA-2] Danielson W, Levin J, Abrams E (2003). Meteorology. McGraw Hill.

[LL-3] Landau and Lifshitz, Fluid Mechanics, Pergamon, 1979

[ZonalFlowDef-4] Lydolph, Paul E. (1985). The Climate of the Earth. Rowman and Littlefield Publishers Inc. p. 12.

[5] Kittel C, Kroemer H (1980). Thermal Physics. Freeman. chapter 6, problem 11.

[LL1-6] Landau LD, Lifshitz EM (1980). Statistical Physics. Part 1. Pergamon.

[ucarOverview-7] "The Stratosphere — Overview". University Corporation for Atmospheric Research. Archived from the original on 29 May 2018. Retrieved 25 July 2018.

[ThreecellEncarta-8] "Meteorology – MSN Encarta, "Energy Flow and Global Circulation"". Encarta.Msn.com. Archived from the original on 2009-10-28. Retrieved 2006-10-13.

[ZonalFlowDef2-9] "American Meteorological Society Glossary – Zonal Flow". Allen Press Inc. June 2000. Archived from the original on 2007-03-13. Retrieved 2006-10-03.

[MeridonialFlow-10] "American Meteorological Society Glossary – Meridional Flow". Allen Press Inc. June 2000. Archived from the original on 2006-10-26. Retrieved 2006-10-03.