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Q.	Troposphere?	Related Search: Homework Help
	I have to make a poster pretending im a travel agent promoting the troposphere. I have no idea what to put any idea?
A.	Troposphere is the bottom most layer of the earth's atmosphere, i.e. it is the layer that we live in, so any thing around you would be in this layer. As your poster has to be made attractive, try using all the colourful pictures you can get, only discrad the pictures of Jet Aircrafts, rockets, Space objects, under water and under ground pictures. Goodluck.

Q.	Why is the troposphere thinner at the poles?	Related Search: Earth Sciences & Geology
	Why is the troposphere thinner at the poles? I need this question answered ASAP please. Homework help. Thank youuu.
A.	the air is usualy warmer, you can read a good explanation here: [Link]

Q.	What location in the troposphere would the risk of potential danger of the balloon leaking be the most acute?	Related Search: Earth Sciences & Geology
	At extremely low temperatures, thin polyethylene fabric would become brittle. Any small flaws in the fabric could cause a balloon made of the fabric to spring a leak and break. Which location, upper, middle, or lower, in the troposphere would the danger be most acute?
A.	Are you referring to a "hot air" balloon or a gas filled balloon (like from a balloon vendor)? Hot air balloons are usually made of nylon (not polyethylene) and work on the principle of heated air rising. This material does not break, it can tear, so it does not really fit your question. Gas filled balloons can be made of polyethylene but are usually made of a latex compound. Latex expands as the balloon goes higher due to the differing air pressure inside and outside the balloon. Polyethylene is only marginally plastic (stretchy) so it will tear/rupture rather than burst if it is punctured. Regardless of balloon type, the higher up you go, the greater the danger - higher has lower relative air pressure, colder air temperature and stronger winds. You would probably get a better (more educated) answer if you posted this question in the "Weather" section of Y/A.

Q.	Why do the winds in the upper troposphere blow from west to east?	Related Search: Weather
	In the midlatitudes of both the Northern and Southern hemisphere the winds of the upper troposphere blow from west to east. Why is this so?
A.	Consider an idealized model of Earth as a non-rotational sphere with uniform solid surface. Since the sun heats the equatorial regions more intensely than the polar regions, a convection cell will develop in each hemisphere due to meridional temperature gradient on the sunny side of the globe. The planetary-scale air will then circulate between the equator and the poles such that warm (less dense) air rises at the equator, and flows toward the poles aloft, while cold (dense) air sinks at the poles and flows toward the equator at surface. If the idealized Earth begins to rotate, the Coriolis force will shift the surface winds to southwest in the Northern Hemisphere, northwest in the Southern Hemisphere. now.... Midlatitude westerlies: the highly variable planetary-scale winds that blow from southwest in the Northern Hemisphere and from northwest in the Southern Hemisphere between 30 and 60 latitude. In middle- and upper-troposphere, midlatitude westerlies blow west to east in a wavelike pattern of ridges and troughs. These winds are responsible for the development and displacement of the weather systems (highs, lows, and air masses) and for the poleward heat transfer. The tropopause is not continuous from poles to equator but occurs in discrete segments. The altitude of the tropopause is directly proportional to the mean temperature of the troposphere; therefore, it decreases with latitude.

Q.	why is the troposphere thicker in the tropics?	Related Search: Earth Sciences & Geology
	why is the troposphere thicker in the tropics?
A.	Warmer temperatures

Q.	What is the average temperature of the troposphere?	Related Search: Weather
	I need to know thins for Mandatory Extra credit for science. If you know it and can help me, I'd really appreciate it!
A.	In the troposphere the temperature decreases with height at an average rate of 6.4 C for every 1 km increase in height. This decrease in temperature is caused by adiabatic cooling - as air rises the atmospheric pressure falls and so the air expands . [Link] > Generally speaking , the temperature decreases in the troposphere ( where our weather occurs ) at an average rate of 6.5C per 1000 metres. ( As far as the weather is concerned , all the action takes place in the troposphere ) . [Link]

Q.	Why is Carbon Monoxide unevenly distributed (in the troposphere) between the northern and southern hemisphere?	Related Search: Earth Sciences & Geology
	Need help finding this answer! PLEASE HELP... Also, what are three things humans are doing right now to cause the fastset rate of extinction in earths history?
A.	Because more is being produced in the northern hemisphere.

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Atmosphere diagram showing the troposphere and other layers. The layers are not to scale.

Temperature and density against altitude from the NRLMSISE-00 standard atmosphere model

View of Earth's troposphere from an airplane.

The troposphere is the lowest portion of Earth's atmosphere. It contains approximately 75% of the atmosphere's mass and almost all of its water vapor and aerosols. The troposphere is constantly convecting air.

The average depth of the troposphere is about 11 km (7 miles) in the middle latitudes. It is deeper in the tropical regions (up to 20 km (12 miles)) and shallower near the poles (about 7 km (4 miles) in summer, indistinct in winter). The lowest part of the troposphere, where friction with the Earth's surface influences air flow, is the planetary boundary layer. This layer is typically a few hundred meters to 2 km (1.2 miles) deep depending on the landform and time of day. The border between the troposphere and stratosphere, called the tropopause, is a temperature inversion.^[1]

The word troposphere derives from the Greek "tropos" for "turning" or "mixing," reflecting the fact that turbulent mixing plays an important role in the troposphere's structure and behavior. Most of the phenomena we associate with day-to-day weather occur in the troposphere.^[1]

1 Pressure and temperature structure
2 See also
3 References
4 External links

[edit] Pressure and temperature structure

[edit] Composition

The chemical composition of the troposphere is essentially uniform, with the notable exception of water vapor. The source of water vapor is at the surface through the processes of evaporation and transpiration. Furthermore the temperature of the troposphere decreases with height, and saturation vapor pressure decreases strongly with temperature, so the amount of water vapor that can exist in the atmosphere decreases strongly with height. Thus the proportion of water vapor is normally greatest near the surface and decreases with height.

[edit] Pressure

The pressure of the atmosphere is maximum at sea level and decreases with higher altitude. This is because the atmosphere is very nearly in hydrostatic equilibrium, so that the pressure is equal to the weight of air above a given point. The change in pressure with height therefore can be equated to the density with this hydrostatic equation:^[2]

$\frac{dp}{dz} = -\rho g_n = - \frac {mpg}{RT}$

where:

g_n stands for the standard gravity
ρ stands for density
z stands for height
p stands for pressure
R stands for the gas constant
T stands for temperature in kelvins
m stands for the molar mass

Since temperature in principle also depends on altitude, one needs a second equation to determine the pressure as a function of height, as discussed in the next section.

[edit] Temperature

Main article: Lapse rate

The temperature of the troposphere generally decreases as altitude increases. The rate at which the temperature decreases, $- d T / d z$ , is called the lapse rate. The reason for this decrease is as follows. When a parcel of air rises, it expands, because the pressure is lower at higher altitudes. As the air parcel expands, it pushes on the air around it, doing work; but generally it does not gain heat in exchange from its environment, because its thermal conductivity is low (such a process is called adiabatic). Since the parcel does work and gains no heat, it loses energy, and so its temperature decreases. (The reverse, of course, will be true for a sinking parcel of air.) ^[1]

Since the heat exchanged dQ is related to the entropy change dS by dQ=T dS, the equation governing the temperature as a function of height for a thoroughly mixed atmosphere is

$\frac{dS}{dz} = 0$

where S is the entropy. The rate at which temperature decreases with height under such conditions is called the adiabatic lapse rate.

For dry air, which is approximately an ideal gas, we can proceed further. The adiabatic equation for an ideal gas is ^[3]

$p(z)T(z)^{-\frac{\gamma}{\gamma-1}}=constant$

where $γ$ is the heat capacity ratio ( $γ$ =7/5, for air). Combining with the equation for the pressure, one arrives at the dry adiabatic lapse rate,^[4]

$\frac{dT}{dz}=- \frac{mg}{R} \frac{\gamma-1}{\gamma}=-9.8^{\circ}\mathrm{C}/\mathrm{km}$

If the air contains water vapor, then cooling of the air can cause the water to condense, and the behavior is no longer that of an ideal gas. If the air is at the saturated vapor pressure, then the rate at which temperature drops with height is called the saturated adiabatic lapse rate. More generally, the actual rate at which the temperature drops with altitude is called the environmental lapse rate. In the troposphere, the average environmental lapse rate is a drop of about 6.5 °C for every 1 km (1000 meters) increase in height. ^[1]

The environmental lapse rate (the actual rate at which temperature drops with height, $d T / d z$ ) is not usually equal to the adiabatic lapse rate (or correspondingly, $dS/dz \ne 0$ ). If the upper air is warmer than predicted by the adiabatic lapse rate ( $d S / d z > 0$ ), then when a parcel of air rises and expands, it will arrive at the new height at a lower temperature than its surroundings. In this case, the air parcel is denser than its surroundings, so it sinks back to its original height, and the air is stable against being lifted. If, on the contrary, the upper air is cooler than predicted by the adiabatic lapse rate, then when the air parcel rises to its new height it will have a higher temperature and a lower density than its surroundings, and will continue to accelerate upward.^[1]^[2]

Temperatures decrease at middle latitudes from an average of 15°C at sea level to about -55°C at the beginning of the tropopause. At the poles, the troposphere is thinner and the temperature only decreases to -45°C, while at the equator the temperature at the top of the troposphere can reach -75°C.^{[citation needed]}

[edit] Tropopause

Main article: Tropopause

The tropopause is the boundary region between the troposphere and the stratosphere.

Measuring the temperature change with height through the troposphere and the stratosphere identifies the location of the tropopause. In the troposphere, temperature decreases with altitude. In the stratosphere, however, the temperature remains constant for a while and then increases with altitude. The region of the atmosphere where the lapse rate changes from positive (in the troposphere) to negative (in the stratosphere), is defined as the tropopause.^[1] Thus, the tropopause is an inversion layer, and there is little mixing between the two layers of the atmosphere.

An idealised view of three large circulation cells.

[edit] See also

[edit] References

^ ^a ^b ^c ^d ^e ^f Danielson, Levin, and Abrams, Meteorology, McGraw Hill, 2003
^ ^a ^b Landau and Lifshitz, Fluid Mechanics, Pergamon, 1979
^ Landau and Lifshitz, Statistical Physics Part 1, Pergamon, 1980
^ Kittel and Kroemer, Thermal Physics, Freeman, 1980; chapter 6, problem 11

[edit] External links

Look up troposphere in
Wiktionary, the free dictionary.

The vertical structure of the atmosphere
Composition of the Atmosphere, from the University of Tennessee Physics dept.
Chemical Reactions in the Atmosphere

v • d • e Earth's atmosphere

Troposphere • Stratosphere • Mesosphere • Thermosphere • Exosphere

Tropopause • Stratopause • Mesopause • Thermopause / Exobase

Ozone layer • Turbopause • Ionosphere

Retrieved from "http://en.wikipedia.org/wiki/Troposphere"

Categories: Atmosphere | Atmospheric thermodynamics

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