☁️ What is a Cloud? Crash Course Geography #10
Summary
TLDRThis script from Crash Course Geography explores the historical and scientific significance of clouds in weather prediction and atmospheric analysis. It explains the composition and anatomy of clouds, their role in the hydrological cycle, and their impact on Earth's energy balance. The video delves into cloud types, their formation, and how they influence weather patterns, highlighting the importance of understanding clouds for climate science and human life.
Takeaways
- 🌤️ Clouds were historically used to predict weather, with sayings like 'red sky in the morning, sailor's warning' indicating weather patterns.
- 🌦️ Modern meteorologists continue to study clouds for weather forecasting, as they provide information on temperature and moisture in the atmosphere.
- 🌍 A global map of clouds can reveal energy flows and weather patterns, helping us understand atmospheric warming.
- ☁️ Clouds are composed of water droplets and ice crystals that are too small to form raindrops, and they float in the atmosphere.
- 🌬️ Clouds have distinct anatomies, heights, and names, similar to different types of atmospheric 'persons'.
- 🏙️ Smog, a type of cloud, is a harmful pollution that traps heat in the atmosphere, contributing to global warming.
- 🌈 Clouds play a significant role in the Earth's energy balance, with different types reflecting and absorbing varying amounts of solar radiation.
- 🌀 Cumulonimbus clouds are powerful rain clouds that demonstrate a significant release of energy during storms.
- 🌡️ Clouds naturally cool and heat the lower atmosphere, with the degree depending on altitude, type, cloud cover, and thickness.
- 💧 The hydrological cycle involves water evaporating into the atmosphere, storing energy as latent heat of evaporation, which is released during condensation.
- 🌡️ Humidity is linked to the energy available for weather production, with high humidity indicating more potential for intense weather events.
Q & A
What was the primary method of weather prediction before the advent of weather satellites and advanced forecasting technology?
-Before the advent of weather satellites and advanced forecasting technology, the primary method of weather prediction was observing clouds. Clear skies or high clouds indicated fine weather, while low or dark clouds often signaled rain.
What is the significance of the sayings like 'red sky in the morning, sailor’s warning; red sky at night, sailor’s delight'?
-These sayings are based on cloud observations and have been used to predict weather conditions. A red sky in the morning suggests that rain might be coming from the west, while a red sky at night indicates that the weather will likely be clear the next day.
How do clouds provide information about the temperature and moisture in the atmosphere?
-Clouds provide information about temperature and moisture in the atmosphere by showing how and why they form. Different types of clouds form at different altitudes and temperatures, and their formation is influenced by the amount of moisture present.
What is the role of clouds in the energy flows and weather patterns of the Earth?
-Clouds play a crucial role in energy flows and weather patterns by reflecting, absorbing, and trapping solar radiation. They influence the Earth's energy balance and contribute to the natural greenhouse effect, which helps regulate the planet's temperature.
What is the composition of clouds, and how do they stay suspended in the atmosphere?
-Clouds are composed of billions of tiny water droplets and ice crystals that are too small to form raindrops. These small particles stay suspended in the atmosphere due to the upward movement of air currents.
What is smog, and how does it affect the environment and human health?
-Smog is a type of pollution that combines smoke and fog, creating a layer of cloud on the ground. It can harm human lungs, irritate eyes and throats, corrode structures over time, and trap extra heat in the atmosphere, contributing to global warming.
How do different types of clouds reflect and scatter solar radiation differently?
-Cirrus clouds reflect about 50% of incoming solar radiation and are good at trapping longwave radiation, insulating and warming the Earth's atmosphere. Stratus clouds reflect and scatter about 90% of insolation, cooling the Earth by preventing energy from reaching the ground. Cumulus clouds are generally neutral, reflecting as much energy as they absorb.
What is the importance of understanding clouds for climate scientists?
-Understanding clouds is critical for climate scientists because clouds play a significant role in how the Earth warms and cools. They affect the global energy budget and are part of the processes that drive climate change.
How does the cloud classification system based on appearance help in understanding their impact on the atmosphere?
-The cloud classification system helps in understanding their impact on the atmosphere by categorizing them into three main types based on appearance: cirrus, stratus, and cumulus. Each type has unique characteristics that affect how they interact with solar radiation and influence the Earth's energy balance.
What is the hydrological cycle, and how does it relate to the formation of clouds?
-The hydrological cycle is the continuous movement of water on, above, and below the surface of the Earth. It involves processes like evaporation, condensation, and precipitation. Clouds form as part of this cycle when water evaporates, rises, cools, and condenses around condensation nuclei in the atmosphere.
How does humidity affect the energy available in the atmosphere for weather events?
-Humidity, which is the amount of water vapor in the air, affects the energy available in the atmosphere for weather events because water vapor can store energy as latent heat of evaporation. Higher humidity means more energy is available for weather phenomena like storms and hurricanes.
Outlines
🌤️ Clouds: Ancient Weather Predictors and Atmospheric Indicators
This paragraph delves into the historical and modern significance of clouds in weather prediction. It explains how the presence and characteristics of clouds have been used to anticipate weather conditions, with clear skies or high clouds indicating fine weather, while low, dark clouds signal rain. The paragraph introduces common sayings derived from cloud observations and highlights the ongoing importance of clouds in meteorology. It also discusses the role of clouds in the atmosphere's energy flows and weather patterns, and how understanding them can help in comprehending atmospheric warming. The introduction of the video's host, Alizé Carrère, and the Crash Course Geography series is also included.
🌦️ Cloud Composition and Their Impact on Earth's Energy Balance
This paragraph provides an in-depth look at the composition of clouds, describing them as 'big water buckets floating in the atmosphere' made up of billions of tiny water droplets and ice crystals. It explains the anatomy of clouds, including their height, type, and formation reasons, and touches on the historical and scientific understanding of clouds' role in weather prediction. The paragraph also discusses the impact of clouds on the Earth's energy balance, including their reflection and absorption of solar radiation, and their contribution to the greenhouse effect. It further explains the classification of clouds into three main types based on appearance: cirrus, stratus, and cumulus, and how each type interacts differently with the energy from the Sun, affecting the warming or cooling of the Earth's atmosphere.
🌡️ Humidity and Its Effects on Weather and Human Comfort
This paragraph explores the concept of humidity, explaining how it measures the amount of water vapor in the air and its correlation with temperature and weather events. It contrasts the low humidity of colder regions like the Arctic with the high humidity of tropical areas, and how this affects the energy available for weather phenomena. The paragraph also discusses the personal experience of humidity, such as its effect on hair and the sensation of discomfort during high humidity days. It explains relative humidity as a comparison between the current amount of water vapor and the maximum possible at a given temperature. The paragraph further describes how temperature changes can affect relative humidity and lead to the formation of dew or fog, and the role of condensation nuclei in cloud formation. Finally, it touches on the energy released during the condensation phase of the hydrological cycle and the unique factors that contribute to the formation of different cloud types.
Mindmap
Keywords
💡Clouds
💡Weather Forecasting
💡Cirrus Clouds
💡Stratus Clouds
💡Cumulus Clouds
💡Cumulonimbus Clouds
💡Hydrological Cycle
💡Evaporation
💡Humidity
💡Dew Point
💡Condensation Nuclei
Highlights
Before modern technology, clouds were used to predict weather.
High clouds or no clouds indicated fine weather, while low or dark clouds signaled rain.
Sayings like 'red sky in the morning, sailor’s warning' originated from cloud observations.
Geographers and meteorologists study clouds to understand temperature and moisture in the atmosphere.
Clouds help us predict weather and understand energy flows and weather patterns.
Clouds are composed of billions of small water droplets and ice crystals.
Different clouds have unique anatomies, heights, names, and formation reasons.
Smog, a combination of smoke and fog, was first named in 1900 and is harmful to health.
Cirrus clouds reflect 50% of solar radiation and trap longwave radiation, warming the atmosphere.
Stratus clouds reflect 90% of solar radiation, cooling the Earth by blocking incoming energy.
Cumulus clouds are neutral in terms of warming as they reflect and absorb similar amounts of energy.
Cumulonimbus clouds are powerful rain clouds that drive big storms.
Cloud names indicate their level and type, with prefixes like cirro (high), alto (mid-level), and nimbus (rain).
Humidity and relative humidity are critical in weather forecasting and are influenced by temperature.
Condensation nuclei, like dust and pollen, are essential for cloud formation.
Transcripts
Before there were weather satellites and sophisticated forecasting technology, clouds were the best
way to predict what weather was coming. Clouds high up in the sky or no clouds at all meant
fine weather. But clouds moving low in the sky or dark clouds meant rain was on its way.
Common sayings even sprung up from our cloud observations, like "red sky in the morning,
sailor’s warning, red sky at night, sailor’s delight." And there are many more across time
and different cultures.
Today, geographers and meteorologists still rely on clouds to forecast the weather by
studying how and why they form. Clouds give us important information on the temperature
and amount of moisture in the atmosphere, which can help us predict weather from cloudless
summer afternoons to overcast winter mornings.
More than that, a map of the world's clouds tells us about today's energy flows and weather
patterns. And unlocking the mysteries of clouds will help us better understand how the atmosphere
is warmed.
So today we’ll join countless peoples throughout history and look up -- at the clouds.
I’m Alizé Carrère and this is Crash Course Geography.
INTRO
Clouds are often described with dramatic words like “ethereal” or “ominous”. They
seem alive, born from the atmosphere, appearing as mysterious objects like UFOs.
But clouds are also useful atmospheric data.
Clouds are basically big water buckets floating in the atmosphere. They’re composed of billions
of so-small-they’re-invisible water droplets and ice crystals too small to form raindrops,
so they stay suspended in the atmosphere.
In fact, each cloud has its own anatomy, height, name, and reason for being, kind of like an
atmospheric person.
Sailors of yore and scientists of today know that clouds can tell us more than whether
it might rain. For example, we often see a villainous type of cloud hanging over cities,
called smog.
A London physician first coined the word "smog" in 1900 to describe the combination of smoke
and fog -- the layer of cloud on the ground -- that cast a pall over the city.
Smog is pollution that harms our lungs, irritates our eyes and throat, and even corrodes structures
over long periods of time. It also traps extra heat in the atmosphere, contributing to human-caused
global warming.
But the presence or absence of clouds can make a big difference in the amount of energy
that reaches the surface of the Earth, too. Let’s go to the Thought Bubble to meet them.
As modern storm chasers, we’re ready to drive for hours to document unique cloud formations
and send data back to local meteorologists.
We have to know who we’re dealing with, but luckily, the vast majority of clouds
are classified into three types, based on the way they look.
The first clouds we spot are wispy tendrils of white. These cirrus clouds or “mare’s
tails” are made up of ice crystals, and they only exist way high up above 6000 meters.
Cirrus clouds like these reflect about 50% of insolation, or incoming solar radiation.
But they’re even better at trapping longwave radiation trying to move back out to space,
insulating and warming the Earth’s atmosphere as part of the natural greenhouse effect.
Miles down the road, the sky is filled with dull, gray, flat, horizontal layers of low-level
clouds below 2000 meters.
Stratus clouds like these reflect and scatter about 90% of insolation, which cools the Earth
by keeping incoming energy from reaching the ground.
You can blame them for the dreary weather.
We keep driving as the weather clears, but now we notice lumpy cumulus clouds taking
over the sky.
Cumulus clouds are signs the energy in the atmosphere is shifting around.
Because they can be so thick and reach so far up into the atmosphere, they generally
reflect as much energy away from the Earth as they absorb to warm the Earth.
So they’re basically neutral in terms of warming the atmosphere.
If we’re lucky driving through this hot afternoon, we’ll see the bright, lumpy cumulus
clouds keep growing higher and thicker.
Now the rain is picking up and we’ve found our storm: the rain -- or nimbus -- form of
cumulus clouds.
Cumulonimbus clouds are towering rain clouds which showcase a powerhouse of energy exploding
as big storms.
Thanks, Thought Bubble! To climate scientists, understanding clouds and how energy flows
through them is critical to understanding how our earth warms and cools and how climates
change.
While cirrus clouds only appear at high levels, stratus and cumulus clouds can appear at any
level. And cloud names actually describe this.
So just like people can be complex, we could have, say, lumpy
cumulus clouds growing in the middle above 2000 meters but below 6000 meters -- at the alto
level. There are called altocumulus. Or we could have horizontal stratus clouds way high above
6000 meters, forming icy cirrostratus layers.
Cirrus or the prefix cirro means high-level, alto refers to the mid-level, and low-level
clouds are just plain stratus or cumulus. Maybe with a “nimbus” tacked on if it’s raining.
But no matter where or what they are, clouds
naturally cool and heat the lower atmosphere, though how much depends on the altitude, cloud
type, amount of cloud cover, and thickness.
Basically, if we imagine clouds as floating water buckets, each type holds different amounts
of water. And clouds are just one phase of the hydrological cycle that circulates water
between the atmosphere, the hydrosphere, the lithosphere, and the biosphere.
(Clouds tie the atmosphere and hydrosphere together, by the way!)
To form clouds, water has to enter the atmosphere through evaporation, which is when liquid
water molecules absorb enough heat to become energized and break away from the surface
as water vapor. The water vapor stores this extra energy as latent heat of evaporation.
For a gram of liquid water to turn into water vapor it absorbs 585 calories, which for us
would be like eating 5 large-ish bananas. This is why when sweat evaporates from our
bodies, it usually has a cooling effect. The liquid water absorbs some heat from our bodies
and some water molecules turn into vapor.
Humidity describes how much water vapor is in the air. In general, the air at high latitudes
like in the Arctic and the Antarctic is naturally colder because of less sunlight, so it has
much less water vapor and is less humid. Places like the Caribbean or other tropical and equatorial
regions of Earth have hotter air with more water vapor and more humidity.
Because water vapor can store energy as latent heat of evaporation, humidity is linked to
how much energy is available in the atmosphere to produce weather. So low humidity is part
of why we don’t usually hear about devastating weather events like hurricanes coming down
from the Arctic.
And we can sense humidity on a personal level, because hair lengthens as humidity increases
and contracts as humidity decreases. [I know a thing or two about that...]
In weather reports on the news when they talk about "a warm front moving in and 55% humidity
outside, back to you, Barbara", they're actually talking about relative humidity. Relative
humidity is a comparison between the actual amount of water vapor in the air and how much
could be in the air.
When air at a certain temperature is at 100% relative humidity, it contains the maximum
amount of water vapor possible. So it’s saturated -- like a sponge full of water that
can't soak up any more unless you squeeze it out. Except "squeezing water out" of the
atmosphere is… rain.
Any kind of humidity strongly depends on the air temperature and how much moisture is available.
At higher temperatures, it’s more likely that more liquid water molecules will have
the energy to evaporate into water vapor and float around in the atmosphere. So in hotter
areas, the air can “hold” more water.
Of course, just because warm air can hold more water doesn't mean that there's always
water vapor around. Inland regions, like the central Sahara desert, are very dry because
they’re far from the oceans and there’s not a lot of liquid water available to be evaporated.
But let's say we're staying in a cabin by a lake -- so there's plenty of liquid water
around. The same relative humidity can feel very different depending on the air temperature.
On a hot day, 70% relative humidity can feel heavy, sticky, and uncomfortable, almost like
standing in a cloud. Because the air can hold more total water, 70% of saturation is a lot
of vapor! Plus, when we're hot, we sweat, and when there’s a ton of moisture already
in the air, our sweat can't evaporate as easily, so we're stuck feeling damp.
On a cold day, 70% relative humidity is much more comfortable because the colder air can
hold less water, so 70% of saturation isn't as much water vapor. Plus, it’s cooler so
we don’t need to sweat as much. Changing temperatures can also change the relative
humidity even if the amount of moisture stays the same. Like during the day it might be
sunny and hot and the relative humidity is only at 50%.
But as the sun sets, and temperatures drop at night, the air has a harder time holding
onto the water vapor. By morning, it feels very damp, and dew drops form on the grass.
We’ve reached 100% saturation even though no extra water vapor was added to the air.
During the night, we reached the dew point, which is the temperature when water vapor
can condense back into liquid droplets, given the current amount of water vapor in the air.
Like as dew on the grass or fog (which is really just a cloud on the ground).
So at the dew point, our metaphorical sponge would be full and a cloud can be born.
If we compare a dry region such as the Sahara desert to a humid region such as Mississippi,
it takes a lot more cooling to reach the dew point and get condensation in the desert than
it does in Mississippi.
Even though water vapor and liquid water are just two different arrangements of water molecules,
it's nearly impossible for condensation to happen if there's no surface for a water droplet
to cling to, like the outside of a cold soda can. So there's one key ingredient of clouds
that we haven't mentioned yet: condensation nuclei. These are microscopic particles like
sea salt spray, dust, smoke, pollen, and volcanic material in the atmosphere that provide a
surface for condensation to take place.
As trillions of our water molecules cling to specks of dust and form billions of tiny
liquid water droplets, and sometimes freeze into ice crystals after that, we get a cloud!
(So I guess clouds are more like a big bucket of dusty water.)
The condensation phase of the hydrological cycle releases all the stored-up energy in
that water vapor -- for every gram of water, 585 calories or 5 large-ish bananas are freed
as the latent heat of condensation.
So if a small, puffy, cumulus cloud holds 500 to 1000 tons of moisture droplets, that’s
a tremendous amount of energy being released that can power a storm.
Every cloud is really the result of cooling. We’ve only described in general how clouds
form from water molecules being energized and evaporating before condensing into liquid
droplets in the atmosphere.
But so much more goes into creating the unique panormas that fill the sky. Each cloud is
one-of-a-kind, just like even though we can generalize about how people are born and grow
up, there are so many intricacies that make a person who they are.
Even whether our cloud will be a small, puffy cumulus cloud or an ominous cumulonimbus cloud
depends on so many factors. Like the specific temperature and humidity of the initial air,
and changing atmospheric conditions as our evaporated water molecules rise.
And with 50% of the Earth covered by clouds at any given moment, there are so many possible
shapes and sizes it’s no wonder clouds are such an ever changing and beautiful aspect
of our environment.
All of these elements come together to deeply affect the Earth and us humans too. We’ve
paid attention to clouds for 1000s of years not just because of their beauty, but because
they absorb, scatter, and reflect rays from the Sun, influence the global energy budget,
and circulate the key ingredient for life -- water! -- around the globe. But more on
that -- and raindrops -- next time.
Thanks for watching this episode of Crash Course Geography. Which was made with the help of all these nice people.
If you want to help keep Crash Course free for everyone, forever, you can join our community on Patreon.
5.0 / 5 (0 votes)