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− | {{honor_header|1|1944|Nature<br>General Conference<br>2001 Edition}}
| + | [[Image:Wave cloud.jpg|thumb|320 px|This wave cloud pattern formed off of the [[Île Amsterdam]] in the far southern [[Indian Ocean]], due to orographic lift of an airmass by the island, producing alternating bands of condensed and invisible humidity downwind of the island as the moist air moves in vertical waves and the moisture successively condenses and evaporates.]] |
− | ==1. Explain how each of the following is formed:==
| + | '''Orographic lift''' occurs when an [[air mass]] is forced from a low [[elevation]] to a higher elevation as it moves over rising terrain. As the air mass gains [[altitude]] it expands and cools [[Adiabatic cooling|adiabatically]]. This cooler air cannot hold the moisture as well as warm air and this effectively raises the [[relative humidity]] to 100%, creating [[cloud]]s and frequently [[precipitation (meteorology)|precipitation]]. |
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− | ===a. Fog ===
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− | [[Image:Acadia NP fog 2005-1-18.JPG|thumb|Fog in Acadia National Park]] | |
− | Relative humidity is a measure of how much water is in the air compared to how much water ''can'' be in the air. As the temperature rises, the air can hold more water, and as it drops, it can hold less. When the humidity is 100% and the temperature drops, the air can no longer hold all the water that is in it. Fog is moisture that gets squeezed out of the air when the temperature drops.
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− | <br style="clear:both">
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− | ===b. Rain ===
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− | [[Image:22 Regen ubt.jpeg|thumb|Rain]] | |
− | Rain forms when separate drops of water fall to the Earth's surface from clouds
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− | ===c. Dew ===
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− | [[Image:Water drops on spider web.jpg|thumb|Dew on s spider web]] | |
− | Dew is water in the form of droplets that appears on thin, exposed objects in the morning or evening. As the exposed surface cools by radiating its heat to the sky, atmospheric moisture condenses at a rate greater than that of which it can evaporate, resulting in the formation of water droplets.
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− | ===d. Snow===
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− | [[Image:Biella-Panoramica Zegna-Bielmonte.jpg|thumb|Snow]] | |
− | Snow is precipitation in the form of crystalline water ice, consisting of a multitude of snowflakes. Since it is composed of small rough particles it is a granular material. It has an open and therefore soft structure, unless packed by external pressure.
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− | Snow is commonly formed when water vapor undergoes deposition high in the atmosphere at a temperature of less than 0°C (32°F). It can also be produced by falling particles of ice fog formed when the humidity in surface air freezes at very low temperatures.
| + | ==Effects of orographic lifting== |
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| + | ===Precipitation=== |
− | ===e. Sleet=== | + | Precipitation induced by orographic lift occurs in [[Rain shadow#Regions of notable rain shadow|many places throughout the world]]. Examples include: |
− | In Britain and other Commonwealth countries, sleet refers to snow that has partially melted on its fall to the ground, due to surrounding air that is sufficiently warm to partially melt it while falling, but not warm enough to fully melt it into rain. Thus it refers to partially melted droplets, a mixture of snow and rain. It does not tend to form a layer on the ground, unless the ground has a temperature that is below freezing, when it can form a dangerous layer of invisible ice on surfaces known as 'black ice'.
| + | * The eastern seaboard of Australia, which faces prevailing easterly winds, |
| + | * The mountains of [[New Zealand]], which faces a prevailing westerly flow off the [[Tasman Sea]]. |
| + | * The southern [[Andes]], which faces a prevailing westerly flow off the [[Pacific Ocean]]. |
| + | * The [[Northwestern United States]] and [[Canada]] ([[Oregon]], [[Washington]] and [[British Columbia]]) see prevailing westerly flow off the northern [[Pacific Ocean]]. Places on the sea-facing side of coastal mountains see over 100 inches (over 2.5 m) of [[precipitation (meteorology)|precipitation]] per year. These locales are on the side of the [[mountain]]s which are in the path of [[storm]] systems, and therefore receive the moisture which is effectively squeezed from the clouds. |
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− | In American usage, sleet is a form of precipitation consisting of tiny frozen raindrops, or ice pellets. This is often mistaken for hail, but forms in a different fashion and is usually (but not always) smaller. This occurs when snow flakes falling through a small layer of warmer air in the atmosphere will begin to melt. They can then refreeze if they pass back into a layer of colder, sub-freezing air closer to the ground, resulting in little balls of ice. These ice balls may bounce when they hit the ground, and do not freeze into a solid mass unless mixed with freezing rain.
| + | ===Rain shadowing=== |
− | ===f. Hail===
| + | [[Image:New-Mexico-Lenticular.jpg|thumb|200px|right|A lenticular cloud in New Mexico.]] |
− | [[Image:Hailstorm.jpg|thumb|Hailstorm]] | + | [[Image:Orographic lifting of the air - NOAA.jpg|thumb|200px|right|A cap cloud.]] |
− | Hail forms on condensation nuclei such as dust, insects, or ice crystals, when supercooled water freezes on contact. Hailstones are usually from the size of a pea to the size of a golfball.
| + | [[Image:Tadrart01.JPG|thumb|200px|right|Wave clouds.]] |
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| + | [[Image:Koryaksky Volcano.jpg|thumb|200px|right|Koryaksy volcano, Kamchatka, Russia, showing banner clouds streaming to the right from the peaks.]] |
− | ===g. Frost===
| + | [[Image:chinook19.11.05.JPG|thumb|200px|right|Chinook arch in Calgary, Alberta, November 19, 2005]] |
− | [[Image:Frost-oliv.JPG|thumb|Frost]] | + | [[Image:Mountains from westlands.jpg|thumb|400px|right|A view of the Front Range of the Rockies capped by a föhn wall.]] |
− | If solid surfaces in contact with the air are chilled below the frost point, then structures of ice grow out from the solid surface. The size of the crystals depends on time and the amount of water vapor available.
| + | :''Main article: [[Rain shadow]]'' |
− | <br style="clear:both"> | + | The highest precipitation amounts are found slightly upwind from the prevailing winds at the crests of mountain ranges, where they relieve and therefore the upward lifting is greatest. As the air descends the lee side of the mountain, it warms and dries, creating a rain shadow. On the lee side of the mountains, sometimes as little as 15 miles (25 km) away from high precipitation zones, annual [[precipitation (meteorology)|precipitation]] can be as low as 8 inches (200 mm) per year.<ref name="Whiteman">{{cite book|author=Whiteman, C. David|title=Mountain Meteorology: Fundamentals and Applications |publisher=Oxford University Press|year=2000|id=ISBN 0-19-513271-8}}</ref> |
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− | ==2. Identify either in the sky or from pictures the following types of clouds: cirrus, cumulus, stratus, nimbus. What kind of weather is associated with each.==
| + | Areas where this effect is observed include: |
− | <gallery>
| + | * The [[Atacama]] Desert in [[Peru]] and [[Chile]]. |
− | Image:Cirrus over Warsaw, June 26, 2005.jpg|Cirrus
| + | * [[Switzerland]]'s [[Rhône River|Rhone valley]]. |
− | Image:Cumulus clouds in fair weather.jpeg|Cumulus
| + | * Areas east of the [[Cascade range]] in the Pacific Northwest ([[Washington]] and [[Oregon]]). |
− | Image:St1.jpg|Stratus
| + | * Areas east of the [[Olympic Mountains]] in Washington state. |
− | Image:Rolling-thunder-cloud.jpg|Nimbus
| + | * Canadian [[Prairies]] |
− | </gallery>
| + | * The [[Hawaii|Hawaiian]] [[island]] of [[Kauai]]. |
− | ;Cirrus: Cirrus clouds are at the highest altitudes. They often appear thin and wispy. They are associated with fair weather.
| + | * [[California]]'s [[Central Valley (California)|Central Valley]]. |
| + | * The [[Great Basin]]. |
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− | ;Cumulus: Cumulus clouds are usually puffy and often have very distinct edges and usually a noticeable vertical development. They often have a popcorn-like appearance. Cells can be rather isolated or they can be grouped together in clusters. The first rain to fall out of the base of a cumulus cloud evaporates into the air beneath, cooling the air - often by several degrees. This cooled air descends, and the more it is cooled the more rapidly it descends. Thus instead of air rising into a cloud we have not only rain falling out the cloud, but air as well. This is why cool and rainy weather is assocaited with cirrus clouds.
| + | ===Atmospheric waves=== |
| + | As air flows over mountain barriers, orographic lift can create a variety of wave effects, which produce vertical air motion. If the air mass is close to the dew point, the waves may show as a variety of leeward clouds<ref name="Whiteman" />: |
| + | * [[Lenticular cloud]]s are stationary lens-shaped clouds that form at high altitudes, normally aligned at right-angles to the wind direction. Orographic lifting creates a wave which creates the condition for cloud formation. |
| + | * A ''cap cloud'' is a special form of the lenticular cloud with a base low enough that it forms around and covers the peak, capping it.<ref name="Whiteman" /> |
| + | * [[Wave cloud]]s are lenticular clouds, created when an [[air mass]] passes over a geographic feature and a standing wave forms downwind. |
| + | * A ''banner cloud'' is a cloud that forms downstream from the upper lee slopes of isolated, steep-sided mountains. This cloud is similar to the condensation observed off the tips of high-performance aircraft wings when they operate in humid conditions; it is created by the vortices and local uplifting in the air caused by the orographic lifting as the wind passes the mountain. The most famous such cloud forms routinely in the lee of the [[Matterhorn]].<ref name="Whiteman" /><ref>[http://www.atmos.washington.edu/gcg/Atlas/phot_oro03.html Example of a banner cloud forming in the lee of the Matterhorn.]</ref>. |
| + | * A ''foehn wall'' is an extensive cloud formed along and parallel to the ridge line. The wall appears stationary, while the wind flows through; moisture condenses on the upslope and evaporating when it descends the lee slope. When viewed as one faces it, it often appears to have an abrupt wall like edge. The foehn wall (or föhn wall) is a common feature along the [[Front Range]] of the [[Colorado]] Rockies.<ref name="Whiteman" /> |
| + | * A ''[[Chinook wind#Chinook arch|chinook arch cloud]]'' forms above a mountain range, usually at the beginning of a chinook wind as a resulting of orographic lifting over the range. It appears when seen from downwind to form an arch over the mountain range. A layer of clear air separates it from the mountain.<ref name="Whiteman" /> |
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− | ;Stratus: Stratus clouds belong to a class characterized by horizontal layering with a uniform base, as opposed to convective clouds that are as tall or taller than wide (these are termed cumulus clouds). More specifically, the term stratus is used to describe flat, featureless clouds of low altitude varying in color from dark gray to nearly white. These clouds are essentially fog that is above ground level and are formed either through the lifting of morning fog or when cold air moves at low altitudes over a region. These clouds do not usually bring precipitation, although if sufficiently low in altitude to become fog, drizzle or mist may result.
| + | ===Leeward winds=== |
| + | Downslope winds occur on the leeward side of mountain barriers when a stable air mass is carried over the mountain by strong winds that increase in strength with height. Moisture is removed and latent heat released as the air mass is orographically lifted. As the air mass descends, it is compression heated. The warm [[Föhn wind]], locally known as the [[Chinook wind]], [[Bergwind]] or [[Diablo wind]] or "Nor-Wester" depending on the region, provide examples of this type of wind, and are driven in part by latent heat released by orographic lifting induced precipitation. |
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− | ;Nimbus: Nimbus clouds are dark, precipituous clouds. Nimbus is a Latin word meaning cloud or rain storm. These are commonly called "thunderclouds."
| + | A similar class of winds, the [[Sirocco]], the [[Bora]] and [[Santa Ana wind]]s, are examples where orographic lifting has limited effect since there is limited moisture to remove in the [[Sahara]]n or other air masses; the Sirocco, Bora and Santa Ana are driven primarily by compression heating. |
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− | ==3. Explain the action of a mercury or spirit thermometer, a mercury barometer, an aneroid barometer, and a rain gauge.== | + | ==References== |
− | ===Spirit thermometer===
| + | <!--See http://en.wikipedia.org/wiki/Wikipedia:Footnotes for an explanation of how to generate footnotes using the <ref(erences/)> tags--> |
− | A spirit thermometer and a mercury thermometer work on the same principles. The "spirit" in a spirit thermometer is alcohol, and both alcohol and mercury expand and contract with temperature changes. When it's cold, they contract, and when it's hot, they expand. A thermometer can be built to exploit and amplify these properties. A glass tube with a bulb at the bottom is filled with alcohol. The tube allows for a greater volume of alcohol, so there is more of it to expand. When it expands, the only place it can go is into the narrow tube. The temperture is read based on how high up the tube the expansion sends the alcohol.
| + | <references/> |
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− | ===Mercury barometer===
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− | [[Image:Hg barometer.PNG|thumb|Mercury barometer]]
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− | A standard mercury barometer has a glass column of 76 cm (30 inches) in height, closed at one end, with an open mercury-filled reservoir at the base. Mercury in the tube adjusts until the weight of the mercury column balances the atmospheric force exerted on the reservoir. High atmospheric pressure places more downward force on the reservoir, forcing mercury higher in the column. Low pressure allows the mercury to drop to a lower level in the column by lowering the downward force placed on the reservoir.
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− | ===Aneroid barometer===
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− | [[Image:Barometre aneroide.png|thumb|Aneroid barometer]]
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− | The purpose of a barometer is to measure the weight of the atmosphere, or the pressure exerted by the air. An aneroid barometer is similar to a balloon, in that it has a cell filled with air. When the outside air pressure increases, the air inside the cell is also increased. The only way it can do that is by decreasing the volume of the cell - in other words, the outside air pressure squishes the cell. Going back to the ballon analogy, the balloon would get smaller. When the outside air pressure decreases, the air inside the cell follows by decreasing its pressure as well. The only way it can do this is by expanding, taking up more volume, and making the cell containing it larger. In the balloon analogy, the balloon gets larger. An aneroid barometer basically measures the thickness of the cell.
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− | ===Rain gauge===
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− | [[Image:Standard rain Guage.JPG|thumb|Rain guage]]
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− | The standard rain gauge consists of a funnel attached to a graduated cylinder that fits into a larger container. If the water overflows from the graduated cylinder the outside container will catch it. So when it is measured the cylinder will be measured and then the excess will be put in another cylinder and measured. In most cases the cylinder is marked in mm and in the picture above will measure up to 25 mm (0.98 in) of rainfall. Each horizontal line on the cylinder is 0.2 mm (0.007 in). The larger container collects any rainfall amounts over 25 mm that flows from a small hole near the top of the cylinder. A metal pipe is attached to the container and can be adjusted to ensure the rain gauge is level. This pipe then fits over a metal rod that has been placed in the ground.
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− | ==4. Why is it possible to be rainy on one side of the mountain range and dry on the other? Give an illustration for your country or region.<br>a. Why is it cooler and more moist in the mountains than in the lowlands?<br>b. From which direction do rain and clear weather usually come in your locality?==
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− | ==5. Show with the help of a diagram how the earth's relationship to the sun produces the seasons.==
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− | [[Image:Seasons.jpg]]
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− | The Earth's tilt on its axis causes the seasons. When the axial tilt points a hemisphere away from the sun, it is winter, and when it points it towards the sun it is summer. This is ''not'' because the distance between that part of the Earth and the Sun varies, but rather, it is because the angle of the sunlight is either more direct, or less direct. The Earth's elliptical orbit about the sun causes its distance from the Sun to vary by a lot more than the axial tilt does.
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− | It is better to think of it this way: shine a flashlight on a piece of paper or cardboard. When the rays from the flashlight are parallel to the paper, the spot is circular. If you tilt the paper, the spot becomes elongated. The same amount of light strikes the paper in both cases, but the light is more concentrated in the circular spot verses the elongated spot. The ''area'' illuminated by the elongated spot is greater, so less light hits each square inch in the elongated "light spot". Less light means less heat, and in the case of the Earth, that means "winter".
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− | ==6. What causes lightning and thunder? What different kinds of lightning are there?==
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− | ===Lightning===
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− | Lightning is caused when electrical charges build up in clouds. Scientists are still unsure exactly why that happens, but it is plausible that water droplets and ice travelling up and down within the cloud separate electrons from one another and transport them to the lower portions of the cloud. However this happens, it causes the cloud to have an electric field. When this field becomes strong enough, the electrons in the cloud begin to repel electrons on the ground, causing the ground to have a positive charge. When the voltage difference between the ground and the cloud becomes great enough, the air ''breaks down'' and actually conducts electricity. The air actually turns into plasma. When it conducts, the result is a lightning strike.
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− | Many people mistakenly believe that the reason a car is a good place to be during a lightning storm is because the rubber in the tires insulates the riders from the ground. But considering the fact that a lightning bolt may have just travelled a mile though the air, how much do you think a quarter inch of rubber is going to slow it down? ''Not at all!'' The reason you are safe in a car is because you are surrounded by a metal shell that will carry the electrical current around you instead of through you.
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− | ===Thunder===
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− | Thunder is, even today, not completely understood by modern science. The word usually describes a sonic shock wave caused by the rapid heating and expansion of the air surrounding and within a bolt of lightning. The bolt changes the air into plasma and it instantly explodes, causing the sound known as a thunder clap.
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− | This phenomenon occurs at the same time as a lightning flash, but a thunder clap is usually heard after lightning is seen because light travels faster (300,000,000 meters per second) than sound (around 300 meters per second). In very close proximity to the lighting strike, sound and light can be heard and seen almost simultaneously.
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− | ===Kinds of Lightning===
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− | Some lightning strikes take on particular characteristics; scientists and the public have given names to these various types of lightning.
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− | ====Intracloud lightning, sheet lightning, anvil crawlers====
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− | Intracloud lightning is the most common type of lightning, and occurs completely inside one cumulonimbus cloud; it is termed sheet lightning because the bolt is not seen, instead one sees the whole cloud light up from inside. Lightning that appears to travel extensively along the cloud anvil or its base is commonly called a crawler, or sometimes 'spider lightning'. Discharges of electricity in anvil crawlers travel up the sides of the cumulonimbus cloud branching out at the anvil top.
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− | ====Cloud-to-ground lightning, anvil-to-ground lightning====
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− | Cloud-to-ground lightning is a great lightning discharge between a cumulonimbus cloud and the ground initiated by the downward-moving leader stroke. This is the second most common type of lightning. One special type of cloud-to-ground lightning is anvil-to-ground lightning, a form of positive lightning, since it emanates from the anvil top of a cumulonimbus cloud where the ice crystals are positively charged. In anvil-to-ground lightning, the leader stroke issues forth in a nearly horizontal direction until it veers toward the ground. These usually occur miles ahead of the main storm and will strike without warning on a sunny day. They are signs of an approaching storm and are known colloquially as "bolts out of the blue".Cloud-to-cloud lightning
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− | ====Cloud-to-cloud lightning====
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− | Cloud-to-cloud or intercloud lightning is a somewhat rare type of discharge lightning between two or more completely separate cumulonimbus clouds.
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− | ====Ground-to-cloud lightning====
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− | Ground-to-cloud lightning is a lightning discharge between the ground and a cumulonimbus cloud from an upward-moving leader stroke. These thunderstorm clouds are formed wherever there is enough upward motion, instability in the vertical, and moisture to produce a deep cloud that reaches up to levels somewhat colder than freezing. These conditions are most often met in summer.
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− | ====Heat lightning or summer lightning====
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− | Heat lightning (or, in the UK, "summer lightning") is nothing more than the faint flashes of lightning on the horizon or other clouds from distant thunderstorms. Heat lightning was named because it often occurs on hot summer nights. Heat lightning can be an early warning sign that thunderstorms are approaching. In Florida, heat lightning is often seen out over the water at night, the remnants of storms that formed during the day along a seabreeze front coming in from the opposite coast. In some cases, the thunderstorm may be too distant to hear the associated thunder from the lightning discharge.
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− | ====Ball lightning====
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− | Ball lightning is described as a floating, illuminated ball that occurs during thunderstorms. They can be fast moving, slow moving or nearly stationary. Some make hissing or crackling noises or no noise at all. Some have been known to pass through windows and even dissipate with a bang. Ball lightning has been described by eyewitnesses but rarely, if ever, recorded by meteorologists.
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− | ==7. Show with the help of a diagram what a convection is. What is its relation to winds?==
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− | ==8. Explain how radar, satellites, and computers are used in weather forecasting.==
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− | ===Radar===
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− | A weather radar is a type of radar used to locate precipitation, calculate its motion, estimate its type (rain, snow, hail, etc.), and forecast its future position and intensity. Modern weather radars are mostly doppler radars, capable of detecting the motion of rain droplets in addition to intensity of the precipitation. Both types of data can be analyzed to determine the structure of storms and their potential to cause severe weather.
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− | ===Satellites===
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− | A weather satellite is a type of satellite that is primarily used to monitor the weather and climate of the Earth. These meteorological satellites, however, see more than clouds and cloud systems. City lights, fires, effects of pollution, auroras, sand and dust storms, snow cover, ice mapping, boundaries of ocean currents, energy flows, etc., are other environmental information collected from weather satellites.
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− | El Niño and its effects on weather are monitored daily from satellite images. The Antarctic ozone hole is mapped from weather satellite data. Collectively, weather satellites flown by the U.S., Europe, India, China, Russia, and Japan provide nearly continuous observations for a global weather watch.
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− | Visible-light images from weather satellites during local daylight hours are easy to interpret even by the average person; clouds, cloud systems such as fronts and tropical storms, lakes, forests, mountains, snow ice, fires, and pollution such as smoke, smog, dust and haze are readily apparent. Even wind can be determined by cloud patterns, alignments and movement from successive photos.
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− | ===Computers===
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− | Computers are largely responsible for the accuracy of today's weather forecasts. Various computers are used not only collect weather data from thousands of sensors around the world, but also for running weather simulations, and for presenting the information to the public on television news broadcasts.
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− | Of these tasks, running weather simulations is certainly the most demanding. Numerical weather prediction models are computer simulations of the atmosphere. They take the analysis as the starting point and project the state of the atmosphere forward in time using an understanding of physics and fluid dynamics. The complicated equations which govern how the state of a fluid changes with time require supercomputers to solve them. The output from the model provides the basis of the weather forecast. There are a number of models that are used in forecasting, and each of them is a little different. Meteorologists look at the output of several and form their forecasts based on this.
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− | ==9. Tell how the following can affect our weather:==
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− | ===a. Jet stream===
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− | [[Image:Jet Stream.jpg|thumb|250px|The main jet streams flow from the west in the upper atmosphere]]
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− | Jet streams are fast flowing, relatively narrow air currents found in the atmosphere at around 11 kilometres (36,000 ft) above the surface of the Earth. They form at the boundaries of adjacent air masses with significant differences in temperature, such as of the polar region and the warmer air to the south. For this reason, areas between the pole and the jet stream are cold, and area between the equator and the jet stream are warm. As the jet stream shifts along the north-south direction, the weather shifts as well.
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− | Meteorologists now understand that the path of the jet stream steers cyclonic storm systems at lower levels in the atmosphere, and so knowledge of their course has become an important part of weather forecasting. Jet streams also play an important part in the creation of super cells, the storm systems which create tornados.
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− | ===b. Volcano eruption===
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− | When a volcano erupts, it sends incredible amounts of volcanic ash into the atmosphere. This is enough to decrease the amount of sunlight that reaches the earth, causing a temporary (though sometimes devastating) global cooling. It also affects the intensity of the colors in the sunset for years.
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− | ==10. Make a drawing showing the water cycle in weather.==
| + | [[Category:Climate forcing agents]] |
− | [[Image:Water cycle.png|thumb|500px|The movement of water around, over, and through the Earth is called the water cycle.]] | |
− | The water cycle is the continuous movement of water over, above, and beneath the Earth's surface. It is powered by solar energy, and because it is a cycle, there is no beginning or end. As water moves around in the hydrosphere, it changes state among liquid, vapour, and ice. The time taken for water to move from one place to another varies from seconds to thousands of years, and the amount of water stored in different parts of the hydrosphere ranges up to 1.37 billion km³, which is contained in the oceans. Despite continual movement within the hydrosphere, the total amount of water at any one time remains essentially constant.
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− | ==11. Make a simple wind vane or rain gauge.==
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− | ===Wind Vane===
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− | ===Rain Gauge===
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− | A rain gauge is very simple to make. You will need a small, transparent vessel with constant diameter from top to bottom. If you have difficulty finding a vessel with constant diameter, you may opt to use a two-liter soda bottle. Strip off the label. Cut the top off the bottle, and fill it with plaster to a depth of 4 to 5 cm (this will provide a smooth bottom instead of the knobby bottom with which a two-liter bottle is typically endowed). You may wish to use epoxy instead of plaster - it is more expensive, but is more water proof. Plaster will work fine unless you plan to use the rain gauge for extended periods. You can also improve the water-resistance of the plaster by varnishing it.
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− | Mark the sides of the vessel with a ruler, indicating millimeters and centimters, with the 0 mark coinciding with the bottom of the vessel's ''inside''. Then set it outside where it can collect rain. When the rain ends, a quick comparison of the water level to the indicators will tell you how much rain fell. Empty the rain gauge between storms.
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− | ==12. Keep a weather chart for one week and record readings at 12-hour intervals. Include the following:<br>a. Temperature<br>b. Moisture (dew, fog, rain, frost, or snow)<br>c. Cloud formation<br>d. Wind direction==
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− | You may need to call your Pathfinders every day to get them to do this. It may help to build the weather instruments from requirement 11 first to build some excitement about weather. It may also help to work on this honor during the season in your area that has the most extreme weather. You can download a tracking chart here and give one to each of your students.
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− | http://www.pathfindersonline.org/pdf/resources/weather_tracking_chart.pdf
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− | If you are teaching this honor to a class of Explorers, there is a chart they can fill out in their diaries.
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− | ==References==
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− | * http://science.howstuffworks.com/lightning.htm
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− | * Wikipedia articles
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− | ** [[W:Thunder|Thunder]]
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− | ** [[W:Lightning|Lightning]]
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− | ** [[W:Weather radar|Weather radar]]
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− | ** [[W:Weather forecasting|Weather forecasting]]
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− | ** [[W:Weather satellite|Weather satellite]]
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− | [[Category:Adventist Youth Honors Answer Book|{{SUBPAGENAME}}]] | + | [[es:Nube orográfica]] |
| + | [[fr:Onde orographique]] |
| + | [[it:Sollevamento orografico]] |
| + | [[no:Orografisk heving]] |
| + | [[nn:Orografisk heving]] |
| + | [[fi:Orografinen pilvi]] |