☁️ What is a Cloud? Crash Course Geography #10

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Before there were weather satellites and sophisticated forecasting technology, clouds were the best

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way to predict what weather was coming. Clouds high up in the sky or no clouds at all meant

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fine weather. But clouds moving low in the sky or dark clouds meant rain was on its way. 

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Common sayings even sprung up from our cloud observations, like "red sky in the morning,

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sailor’s warning, red sky at night, sailor’s delight." And there are many more across time

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and different cultures.

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Today, geographers and meteorologists still rely on clouds to forecast the weather by

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studying how and why they form. Clouds give us important information on the temperature

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and amount of moisture in the atmosphere, which can help us predict weather from cloudless

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summer afternoons to overcast winter mornings.  

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More than that, a map of the world's clouds tells us about today's energy flows and weather

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patterns. And unlocking the mysteries of clouds will help us better understand how the atmosphere

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is warmed.

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So today we’ll join countless peoples throughout history and look up -- at the clouds. 

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I’m Alizé Carrère and this is Crash Course Geography.

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INTRO

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Clouds are often described with dramatic words like “ethereal” or “ominous”. They

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seem alive, born from the atmosphere, appearing as mysterious objects like UFOs. 

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But clouds are also useful atmospheric data. 

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Clouds are basically big water buckets floating in the atmosphere. They’re composed of billions

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of so-small-they’re-invisible water droplets and ice crystals too small to form raindrops,

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so they stay suspended in the atmosphere. 

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In fact, each cloud has its own anatomy, height, name, and reason for being, kind of like an

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atmospheric person. 

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Sailors of yore and scientists of today know that clouds can tell us more than whether

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it might rain. For example, we often see a villainous type of cloud hanging over cities,

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called smog.

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A London physician first coined the word "smog" in 1900 to describe the combination of smoke

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and fog -- the layer of cloud on the ground -- that cast a pall over the city. 

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Smog is pollution that harms our lungs, irritates our eyes and throat, and even corrodes structures

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over long periods of time. It also traps extra heat in the atmosphere, contributing to human-caused

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global warming.

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But the presence or absence of clouds can make a big difference in the amount of energy

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that reaches the surface of the Earth, too. Let’s go to the Thought Bubble to meet them.

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As modern storm chasers, we’re ready to drive for hours to document unique cloud formations

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and send data back to local meteorologists. 

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We have to know who we’re dealing with, but luckily, the vast majority of clouds

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are classified into three types, based on the way they look. 

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The first clouds we spot are wispy tendrils of white. These cirrus clouds or “mare’s

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tails” are made up of ice crystals, and they only exist way high up above 6000 meters.

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Cirrus clouds like these reflect about 50% of insolation, or incoming solar radiation. 

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But they’re even better at trapping longwave radiation trying to move back out to space, 

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insulating and warming the Earth’s atmosphere as part of the natural greenhouse effect.

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Miles down the road, the sky is filled with dull, gray, flat, horizontal layers of low-level

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clouds below 2000 meters. 

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Stratus clouds like these reflect and scatter about 90% of insolation, which cools the Earth

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by keeping incoming energy from reaching the ground.

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You can blame them for the dreary weather.

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We keep driving as the weather clears, but now we notice lumpy cumulus clouds taking

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over the sky.

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Cumulus clouds are signs the energy in the atmosphere is shifting around.

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Because they can be so thick and reach so far up into the atmosphere, they generally

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reflect as much energy away from the Earth as they absorb to warm the Earth.

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So they’re basically neutral in terms of warming the atmosphere. 

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If we’re lucky driving through this hot afternoon, we’ll see the bright, lumpy cumulus

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clouds keep growing higher and thicker.

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Now the rain is picking up and we’ve found our storm: the rain -- or nimbus -- form of

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cumulus clouds. 

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Cumulonimbus clouds are towering rain clouds which showcase a powerhouse of energy exploding

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as big storms.

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Thanks, Thought Bubble! To climate scientists, understanding clouds and how energy flows

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through them is critical to understanding how our earth warms and cools and how climates

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change. 

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While cirrus clouds only appear at high levels, stratus and cumulus clouds can appear at any

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level. And cloud names actually describe this.

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So just like people can be complex, we could have, say, lumpy

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cumulus clouds growing in the middle above 2000 meters but below 6000 meters -- at the alto

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level. There are called altocumulus. Or we could have horizontal stratus clouds way high above

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6000 meters, forming icy cirrostratus layers.

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Cirrus or the prefix cirro means high-level, alto refers to the mid-level, and low-level

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clouds are just plain stratus or cumulus. Maybe with a “nimbus” tacked on if it’s raining.

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But no matter where or what they are, clouds

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naturally cool and heat the lower atmosphere, though how much depends on the altitude, cloud

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type, amount of cloud cover, and thickness.

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Basically, if we imagine clouds as floating water buckets, each type holds different amounts

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of water. And clouds are just one phase of the hydrological cycle that circulates water

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between the atmosphere, the hydrosphere, the lithosphere, and the biosphere.

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(Clouds tie the atmosphere and hydrosphere together, by the way!) 

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To form clouds, water has to enter the atmosphere through evaporation, which is when liquid

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water molecules absorb enough heat to become energized and break away from the surface

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as water vapor. The water vapor stores this extra energy as latent heat of evaporation. 

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For a gram of liquid water to turn into water vapor it absorbs 585 calories, which for us

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would be like eating 5 large-ish bananas. This is why when sweat evaporates from our

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bodies, it usually has a cooling effect. The liquid water absorbs some heat from our bodies

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and some water molecules turn into vapor. 

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Humidity describes how much water vapor is in the air. In general, the air at high latitudes

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like in the Arctic and the Antarctic is naturally colder because of less sunlight, so it has

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much less water vapor and is less humid. Places like the Caribbean or other tropical and equatorial

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regions of Earth have hotter air with more water vapor and more humidity.

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Because water vapor can store energy as latent heat of evaporation, humidity is linked to

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how much energy is available in the atmosphere to produce weather. So low humidity is part

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of why we don’t usually hear about devastating weather events like hurricanes coming down

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from the Arctic. 

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And we can sense humidity on a personal level, because hair lengthens as humidity increases

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and contracts as humidity decreases. [I know a thing or two about that...]

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In weather reports on the news when they talk about "a warm front moving in and 55% humidity

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outside, back to you, Barbara", they're actually talking about relative humidity. Relative

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humidity is a comparison between the actual amount of water vapor in the air and how much

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could be in the air.

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When air at a certain temperature is at 100% relative humidity, it contains the maximum

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amount of water vapor possible. So it’s saturated -- like a sponge full of water that

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can't soak up any more unless you squeeze it out. Except "squeezing water out" of the

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atmosphere is… rain.

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Any kind of humidity strongly depends on the air temperature and how much moisture is available.

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At higher temperatures, it’s more likely that more liquid water molecules will have

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the energy to evaporate into water vapor and float around in the atmosphere. So in hotter

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areas, the air can “hold” more water. 

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Of course, just because warm air can hold more water doesn't mean that there's always

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water vapor around. Inland regions, like the central Sahara desert, are very dry because

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they’re far from the oceans and there’s not a lot of liquid water available to be evaporated.

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But let's say we're staying in a cabin by a lake -- so there's plenty of liquid water

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around. The same relative humidity can feel very different depending on the air temperature.

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On a hot day, 70% relative humidity can feel heavy, sticky, and uncomfortable, almost like

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standing in a cloud. Because the air can hold more total water, 70% of saturation is a lot

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of vapor! Plus, when we're hot, we sweat, and when there’s a ton of moisture already

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in the air, our sweat can't evaporate as easily, so we're stuck feeling damp.

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On a cold day, 70% relative humidity is much more comfortable because the colder air can

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hold less water, so 70% of saturation isn't as much water vapor. Plus, it’s cooler so

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we don’t need to sweat as much. Changing temperatures can also change the relative

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humidity even if the amount of moisture stays the same. Like during the day it might be

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sunny and hot and the relative humidity is only at 50%. 

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But as the sun sets, and temperatures drop at night, the air has a harder time holding

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onto the water vapor. By morning, it feels very damp, and dew drops form on the grass.

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We’ve reached 100% saturation even though no extra water vapor was added to the air. 

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During the night, we reached the dew point, which is the temperature when water vapor

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can condense back into liquid droplets, given the current amount of water vapor in the air. 

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Like as dew on the grass or fog (which is really just a cloud on the ground). 

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So at the dew point, our metaphorical sponge would be full and a cloud can be born. 

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If we compare a dry region such as the Sahara desert to a humid region such as Mississippi,

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it takes a lot more cooling to reach the dew point and get condensation in the desert than

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it does in Mississippi.

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Even though water vapor and liquid water are just two different arrangements of water molecules,

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it's nearly impossible for condensation to happen if there's no surface for a water droplet

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to cling to, like the outside of a cold soda can. So there's one key ingredient of clouds

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that we haven't mentioned yet: condensation nuclei. These are microscopic particles like

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sea salt spray, dust, smoke, pollen, and volcanic material in the atmosphere that provide a

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surface for condensation to take place. 

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As trillions of our water molecules cling to specks of dust and form billions of tiny

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liquid water droplets, and sometimes freeze into ice crystals after that, we get a cloud!

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(So I guess clouds are more like a big bucket of dusty water.)

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The condensation phase of the hydrological cycle releases all the stored-up energy in

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that water vapor -- for every gram of water, 585 calories or 5 large-ish bananas are freed

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as the latent heat of condensation. 

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So if a small, puffy, cumulus cloud holds 500 to 1000 tons of moisture droplets, that’s

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a tremendous amount of energy being released that can power a storm. 

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Every cloud is really the result of cooling. We’ve only described in general how clouds

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form from water molecules being energized and evaporating before condensing into liquid

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droplets in the atmosphere. 

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But so much more goes into creating the unique panormas that fill the sky. Each cloud is

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one-of-a-kind, just like even though we can generalize about how people are born and grow

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up, there are so many intricacies that make a person who they are.  

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Even whether our cloud will be a small, puffy cumulus cloud or an ominous cumulonimbus cloud

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depends on so many factors. Like the specific temperature and humidity of the initial air,

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and changing atmospheric conditions as our evaporated water molecules rise. 

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And with 50% of the Earth covered by clouds at any given moment, there are so many possible

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shapes and sizes it’s no wonder clouds are such an ever changing and beautiful aspect

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of our environment. 

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All of these elements come together to deeply affect  the Earth and us humans too. We’ve

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paid attention to clouds for 1000s of years not just because of their beauty, but because

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they absorb, scatter, and reflect rays from the Sun, influence the global energy budget,

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and circulate the key ingredient for life -- water! -- around the globe. But more on

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that -- and raindrops -- next time.

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Thanks for watching this episode of Crash Course Geography. Which was made with the help of all these nice people.

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