GEOG102 Midterm 1 Review PDF

Summary

This document is a review for a midterm exam on Earth System Science Geography. It covers topics like systems, sustainability, feedback loops, equilibrium, climate change. Review strategies and question types are also outlined and examples are used for clarity.

Full Transcript

GEOG 102 MIDTERM 1 REVIEW
 Mid-Term Structure
Mid-term comprised of 10 multiple choice and 7 short
answer questions, 5 of which you have to answer (worth
4 marks each).
Answers to be in sentences, not point form.
You can draw figures/diagrams to aid in your answer.
Each answer has a half page allocated.
 Mid-Term Review Strategy
Advice:
Find the core concepts for each lecture
Look at the overview and summary slides for the broad topics
covered.
Review the lecture slides for those concepts
Go to assigned textbook readings for each week for more context on
each of the topics.
In your studying:
Be able to explain each concept, using examples as well as
comparing and contrasting to other concepts.
For example: explaining a system in metastable equilibrium using a
contrasting example of system in dynamic equilibrium.
EARTH
SYSTEM
SCIENCE GEOG 102 Week 2,
 The human footprint
Sustainability in agriculture, energy, resources,
development

Belgian wind farms Rio de Janeiro deforestation

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
 The Anthropocene
Ray Troll/Troll Art

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
 Open systems
Systems in nature are not usually self-contained

Have both inputs and outputs (energy and
matter)

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
 Closed system i.e. self-contained
Earth in some ways: finite resources of water, air,
physical matter

Source: https://course.oeru.o
Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
 System feedback loops
Positive feedback enhances the
original change

- Result increasingly differs from the
starting state

Negative feedback damps down
(diminishes) original change

- Tends to preserve the starting state

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
Positive feedback
Mechanism within the
system that
amplifies or
reinforces the
effects of an initial
change

Destabilizing

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
 Negative feedback
Mechanism within the system that
lessens or dampens the effects of an
initial change
Stabilizing
Processes of self-regulation

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
 Equilibrium
Equilibrium: system remains
balanced
over time

- Steady-state: values fluctuate
around a steady average

- Dynamic: values of the average may
themselves change

- Metastable: results from an abrupt
change from one state to another

Spatial Concepts Human Activities Open/Closed Systems Feedback loops Equilibrium
Week 2, Lecture
 Axial tilt (obliquity)
Plane of ecliptic =
horizontal plane dividing
the earth into 2

This is not the same as the
equator

Axis tilt is fixed relative to
this plane

Axis is tilted 66.5° from
plane of ecliptic

Revolution Axis Tilt Rotation Earth Shape Seasons Milankovitch
 Earth’s shape impacts the amount
of sunlight received

The same amount of
sunlight is spread over
a much larger area at
the poles because of
the curve and shape of
the Earth

Revolution Axis Tilt Rotation Earth Shape Seasons Milankovitch
Milankovitch
cycles

Revolution Axis Tilt Rotation Earth Shape Seasons Milankovitch
 Solar and
Terrestrial
Energy
Figure shows the “atmospheric
windows”, where electromagnetic
radiation is transmitted through
the atmosphere.
Incoming solar radiation peaks in
the visible light spectrum (blue –
red), with infrared radiation
providing heat to the planet.
Earth’s emitted radiation (black
curve on right) in the infrared
region shows several absorption
bands (trapping heat in form of
longwave radiation).

Radiation Outputs Electro. Spectrum Radiation Budget Insolation
 Earth’s Radiation Budget

Figure 2.8

Radiation Outputs Electro. Spectrum Radiation Budget Insolation
 Insolation Receipts and Earth’s Curved
Surface

Radiation Outputs Electro. Spectrum Radiation Budget Insolation
 Shortwave Longwave
radiation radiation

Radiation re-emitted by the
SOLAR RADIATION (0.2-4.0 μm) atmosphere and by other
objects (>4.0 μm)
Mostreceived when incoming Amount of radiation depends
radiation is 90o to the surface on the temperature of the
emitter
Radiation Outputs Electro. Spectrum Radiation Budget Insolation
Week 3 , Lecture 4
 Albedo
Smooth surface versus rough surface
Light color surface versus dark color surface

Albedo Absorption Scattering Refraction
 Transmission and Absorption

Transmission refers to the
passage of shortwave and transmissio
longwave energy through n Absorbe
d
the atmosphere window
Absorption is the
assimilation of radiation by
molecules of matter and its
conversion from one form
of energy to another.
CO2 and water vapour
absorb solar radiation and
longwave radiation.

Albedo Absorption Scattering Refraction
 Absorption of Sun’s Energy by Earth’s
Atmosphere

UV VIS INFRARED
Oxygen and
ozone
absorb
incoming
ultra light

Cumulative
gases
in atmosphere
result in
window for
peak incoming

solar
radiation.

Albedo Absorption Scattering Refraction
Electromagnetic Energy – Atmosphere Interactions
Scattering

Scatter differs from albedo in that the direction associated
with scattering is unpredictable, whereas the direction of
reflection is predictable. There are three types of
scattering:
Rayleigh,
Mie, and
Non-selective.
* These types of scatter correspond to the size of the
target relative to the wavelength of the incident
electromagnetic energy

Albedo Absorption Scattering Refraction
Week 3, Lecture 5
 Greenhouse effect
Longwave radiation from
Earth absorbed by
atmospheric gases: CO2,
H2O, Methane (CH4) other
gases
Increased amounts of
these gases increases the
absorption of heat in lower
atmosphere
Cloud layers (liquid water)
also
absorb longwave radiation
Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Low, thick clouds cool Earth;
high thin clouds warm Earth
Clouds modulate radiation in both the visible and infrared
spectra
Clouds cool the Earth Clouds warm the Earth
Current net
by reflecting sunlight by absorbing longwave
effect is to
(albedo). Depending infrared radiation from
cool the Earth
on the cloud they the Earth and re-
(albedo more
scatter between 20- emitting it.
important
90% of radiation.
than re-
emission).
Clouds reflect about
50 W m-2 of solar
radiation up into
space, and radiate
about 30 W m-2 down
to the ground

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Greenhouse gases

Carbon dioxide (CO2) Radiative effect depends on the wavelengths that gas abso
and amount in atmosphere
Methane (CH4)
Chlorofluorocarbons (CFC’s)
Tropospheric ozone (O3)
Nitrous oxide (N2O)
Water vapour (H20)

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Carbon dioxide (CO2): 1st
place
Natural part of the carbon cycle
Increased above natural levels by:
Fossil fuel burning (70% of emissions)
Destruction of forest and land use change
Highest level since 650,000 years ago

Greenhouse Greenhouse Climate
Climate Change
Change
Greenhouse Effect Greenhouse Gases Climate Change Earth EnergyEarth Energy
Effect
© 2016 Pearson Canada Inc. Gases Impacts
Impacts 4-14
 Methane (CH4): 2 nd

place
Rice cultivation
Farm animal wastes
Bacterial decay in sewage and
landfills
Fossil fuel use
Biomass burning
Wetlands (natural)
Permafrost thawing

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
Nitrous oxide (N2O): 3rd
place
i.e. laughing gas

Motor vehicles
(burning fossil fuel)
Nitrogen fertilizers
Nitrous oxide has one
of the longest
atmospheric lifetimes
of all greenhouse
gases (121 years)

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
Residence time in the
atmosphere
Methane leaves the atmosphere by oxidizing
to C02…
C02 can have a very long 200

residence time in the 180

160
atmosphere (so current levels 140

will stay around a long time) 120

100

80
It depends on uptake rates by 60

ocean, plants, rock chemical 40

weathering etc. 20

0
Carbon dioxide Nitrous oxide Methane

50-200 120 12
years year year
s s

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Future scenarios from climate
change

Shift in agricultural
patterns:
Human populations displaced
Climate Refugees
Natural ecosystems displaced

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Future scenarios from climate
change
Spread of insect-bourne diseases
E.g. Malaria, West Nile fever

Deer Ticks
carrying Lyme
Disease

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Future scenarios from climate
change
Climate boundaries shift
Some regions wetter, some drier

Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Future scenarios from climate
Arctic thawing
change

Houses in Alaska are sinking, falling into rivers as permafrost thaws and
degrades.
kml.gina.alaska.edu Climate Change
Greenhouse Effect Greenhouse Gases Climate Change Earth Energy
Impacts
 Human impact on climate
- The last time CO2 levels
were this high was in the
Pliocene (3-5 million years
ago)
- The Arctic was ~8oC warmer
than it is today
- Sea level was 5-40 m higher
than today

Source: climate.nasa.gov
Week 4, Lecture 6
 What is heat?
Transfer of kinetic energy between molecules
Heat flows from source to sink
i.e. from hot to cold

Temp Control Heating Heat Control Climates Hydro Cycle
 Heat Transfer
Conduction: molecule-to-
molecule transfer (from higher
temperature to lower
temperature)
Radiation: energy traveling
through air or space as
electromagnetic waves
Convection: energy transferred by
vertical movement
Advection: same principles as
convection but with horizontal
motion
Temp Control Heating Heat Control Climates Hydro Cycle
 Sensible heat
Sensible = can be
felt with senses
We sense heat as
transfer of energy
from an object to or
from our skin.
Does it feel hot or
cold outside?

Temp Control Heating Heat Control Climates Hydro Cycle
 Latent heat
Energy consumed or released
during phase change
Breaking/forming hydrogen
bonds
Ice is much more solid than
water – molecules don’t bounce
around so it takes energy to
move the molecules
So when freezing water, you
need less movement and that is
released as latent heat
Freezing things releases heat!

Temp Control Heating Heat Control Climates Hydro Cycle
 Principal Temperature
Controls
Latitude
Altitude/elevation
Cloud Cover
Water Bodies

Temp Control Heating Heat Control Climates Hydro Cycle
 Temperature controls: water bodies vs. land bodies

Temp Control Heating Heat Control Climates Hydro Cycle
 Land–Water Heating Differences

Evaporation
Transparency
Specific heat capacity
Movement and currents

Temp Control Heating Heat Control Climates Hydro Cycle
 Land and Water Contrasts
Maritime temperatures: Coastal regions have smaller daily and annual
temperature ranges
Continental temperatures: Inland regions have greater daily and annual
temperature ranges

Temp Control Heating Heat Control Climates Hydro Cycle
 Hydrologic cycle
Water moves among the ocean, atmosphere and land through:
Evaporation
Cloud formation
Precipitation
Transpiration
Sinks into soil
Recharge of
groundwater
Runoff

Temp Control Heating Heat Control Climates Hydro Cycle