Getting Energy to the Biosphere Science 10 PDF

Summary

This presentation about the biosphere provides information on various aspects of Earth's natural systems. It covers numerous topics about weather, climate, and the different components of the earth, along with their interrelation.

Full Transcript

THE BIOSPHERE Science 10
WEATHER & CLIMATE
Weather refers to the conditions of
temperature, air pressure, cloud cover,
precipitation, and humidity that occur
at a particular place at a particular
time.
E.g., Today the weather is sunny, but
tomorrow the weather may be
overcast.
Climate is the average weather
conditions that occur in a region over a
long period of time; usually a
minimum of 30 years.
E.g., On average the weather is
Calgary is much warmer than Northern
Alberta.
THE EARTH
Earth’s biosphere is a relatively thin
layer of Earth that is suitable for
supporting life.
The biosphere is made of three
interacting components:
1. Atmosphere - The layer of gases
surrounding the Earth
2. Lithosphere - The solid portion of
Earth, composed of rocks, minerals
and elements
3. Hydrosphere - All the water on
Earth, whether present as liquid,
vapour, or ice
1. ATMOSPHERE
The atmosphere rises 500 km from the
surface of the Earth.
It is mainly composed of a mixture of gases
(air).
Nitrogen, the most abundant gas, is
required for plant growth.
Gas Percent of
Oxygen is required for life and key to many Atmosphere by
Volume (%)
chemical reactions.
Nitrogen (N) 78.08
Water vapour exists in the atmosphere, Oxygen (O) 20.95
but at variable levels. Other Gases* 0.97

* Includes argon, carbon dioxide, neon,
helium, methane and krypton.
2. LITHOSPHERE

Sun
The lithosphere is the solid portion
of the biosphere.
The lithosphere extends from the
surface to a depth of about 100km.
Deeper than this is the upper mantle
which is partially molten.
The lithosphere is found on land
and under the worlds oceans.
The lithosphere is warmed by:
1. Incoming energy from the Sun

e
Mantl
2. The molten materials of the
mantle.
3. HYDROSPHERE
The hydrosphere is all the
water on the planet.
Approximately 97% of this water
is salt water in the oceans and
seas.
The remaining 3% is fresh water.
However, this represents all
lakes, rivers, aquifers, water
vapor in the atmosphere, and
glacial snow and ice.
Like the lithosphere, the
hydrosphere is also mostly
warmed by the Sun, but also by
the molten materials of the
mantle.
BIOSPHERE INTERACTIONS
The components of the biosphere
interact with each other.
They all share boundaries and overlap.
Water vapor in the atmosphere is part of
the hydrosphere.
Soil, a part of the lithosphere, also
contains water.
Water is required for life - some of the
most productive aquatic habitats are the
margins where the hydrosphere and
lithosphere come together.
As for the atmosphere, all plants and
animals exchange gases to and from the
atmosphere regardless if they on land or
in water.
SOLAR ENERGY
Virtually all of the energy on Earth
initially comes from the Sun, or from
solar energy.
Some of this energy is stored as
chemical energy by plants.
Most is converted in thermal energy.
Thermal energy is the energy
possessed by a substance by virtue of
the kinetic energy of its molecules of
atoms.
Different areas of Earth receive
different amounts of solar energy.
What causes this relationship and what
consequences does it have for the
biosphere?
RADIANT ENERGY
Solar energy is radiant energy,
or energy that is transmitted as
electromagnetic waves.
Solar energy consists of
electromagnetic waves at
different wavelengths, which make
up the electromagnetic
spectrum.
The electromagnetic spectrum
can be divided into classes of
waves that fall within a certain
wavelength.
Energy per wave also varies across Visible light, the light that humans can see with
the spectrum. our eyes, makes up only a tiny portion of the
Gamma rays carry more energy EMS.
than an equal number of radio
waves.
INSOLATION
Not all regions of the Earth receive the same
amount of energy from the Sun.
In general, regions at, or near, the equator
receive more solar energy than regions nearer
to the poles.
Insolation refers to the amount of solar
energy received by a region on Earth’s surface.
Insolation depends on:
1. Latitude – imaginary lines that run parallel
to Earth’s equator; the equator has a
latitude of 0°, the north pole has a
latitude of 90° N.
2. The specific characteristics of the
lithosphere, atmosphere and
hydrosphere in a region.
ANGLE OF INCLINATION
If we line up Earth’s poles relative
to the plane of its orbit around the
Sun, we see that its slightly tilted.
Angle of inclination – the degree
by which Earth’s poles are tilted
from the perpendicular of the plane
of its orbit.
Earth has an angle of inclination
of 23.5°.
This has consequences for the
amount of solar energy that
strikes Earth’s surface.
EARTH’S ORBIT AND ANGLE
OF INCLINATION
Earth orbits the Sun once per
year.
On the first day of summer
(June 21) the angle of
inclination causes the North
Pole to be tilted towards the
Sun.
This means the North Pole
receives more insolation
during the summer.
At the same time, the South
Pole is tilted away from the Season Simulator
Sun, receiving less insolation
and therefore cooler
temperatures.
LATITUDES
Earth can be divided into different latitudes, which
are imaginary lines that run parallel to the equator
(0°)
At more northern latitudes, there are more hours
of daylight as the North Pole becomes tilted towards
the Sun.
A solstice is one of two points in Earth’s orbit at
which the poles are most tilted towards or away
from the Sun.
Summer solstice (June 21-22) = most hours of
daylight in the year.
Winter solstice (December 21-22) = fewest hours of
daylight in the year.
Regions of Earth nearer to the equator experience
less variation in the hours of sunlight they receive
year round.
INSOLATION AND THE ANGLE
OF INCIDENCE
The shape of Earth also affects the
insolation of regions of different
latitudes.
Angle of incidence is the angle between
a ray falling on a surface and the line of
the perpendicular to that surface.
At the equator, the angle of incidence of
incoming solar radiation is 0°.
The larger the angle of incidence, the
same amount of solar radiation is
spread over a larger distance.
Therefore areas of higher latitude receive
less solar energy per square km than
that of lower latitudes.
ABSORPTION & REFLECTION
Once solar radiation reaches the
Earth one of two things will happen:
1. Reflection – when particles reflect
energy they change its direction.
🢝 Reflected energy goes back into space
or is absorbed elsewhere in the
biosphere.
2. Absorption – when particles
absorb energy its is converted into
another form of energy, typically
thermal energy.
🢝 When a substance absorbs energy, the
temperature of that substance will
increase.
ALBEDO
The solar radiation that does reach Earth’s
surface is either reflected or absorbed.
The amount that is reflected or absorbed
depends on the type of surface the radiation
encounters.
The albedo of a surface is the percent of
solar radiation it reflects.
Light-coloured, shiny surfaces have high
albedo (e.g., snow)
Darker, dull surfaces have low albedo (e.g.,
forests and soil)
One contributing factor to climate change is
the melting of polar ice, which historically has
reflected large amounts of solar radiation.
NATURAL GREENHOUSE
EFFECT
Natural greenhouse effect is
the absorption of thermal energy
by Earth’s atmosphere.
Without this natural process, the
average temperature on Earth’s
surface would be 33°C lower and
most likely be unable to support
life.
Greenhouse gases – gases that
contribute to the greenhouse
effect (mainly H2O, but also CO2,
N2O, CH4, etc.) by absorbing
thermal energy.
NET RADIATION BUDGET
Much of the solar radiation is reflected
out into space or re-emitted as thermal
energy.
Earth’s net radiation budget is the
difference between the amount of
incoming radiation and of outgoing
radiation re-emitted from Earth’s surface
and atmosphere.
Incoming radiation is all the solar
energy that reaches Earth’s surface – it
does not include the radiation reflected by
at atmosphere or surface albedo. Net radiation budget = incoming radiation –
outgoing radiation
Outgoing radiation is the thermal
radiation re-emitted by the atmosphere
and Earth’s surface that is not absorbed by
greenhouse gases.