The document discusses the greenhouse effect, carbon cycle, and rising global temperatures. It notes that scientists have debated whether temperature rise is natural or human-caused. The 2007 IPCC report concluded global warming is very likely due to human activities like fossil fuel use that emit greenhouse gases like carbon dioxide, disrupting the natural carbon cycle. The greenhouse effect occurs as certain gases trap infrared radiation emitted from the Earth's surface, and rising CO2 levels from activities such as deforestation and burning fossil fuels are enhancing the greenhouse effect.
2. THE QUESTION OF THE CENTURY:
•Natural?
OR
• Human-
caused?
WHY THE GLOBAL
TEMPERATURE RISE?
This issue has been debated hotly for years
3. THE ANSWER……
In 2007, the world’s climate scientists combined to
produce the single most comprehensive and
authoritative research summary on climate change:
The Fourth Assessment Report of the
Intergovernmental Panel on Climate Change (IPCC)
The IPCC report summarized all scientific data on
climate change, future predictions, and possible impacts
and concluded:
“….global warming is very likely man-
made (or anthropogenic).”
4. SUMMARY
Virtually all climate researchers agree that global
climate is changing
Virtually all climate researchers agree that human
fossil fuel use plays a large role in driving climate
change.
In order to understand how fossil fuel is causing
climate change, one must understand:
1. The Greenhouse Effect
2. Greenhouse Gasses
3. Disruption of the Carbon Cycle
Let’s take a closer look….
5. THE GREENHOUSE EFFECT, CARBON
CYCLE & RISING TEMPERATURES
I. The Greenhouse Effect
A. Earth’s Energy Balance
B. Greenhouse Gases
II. Carbon Cycle
A. Carbon sources & sinks
B. Long-term records of carbon dioxide
III. Rising Temperatures
A. Recent & Long-term Temperatures Trends
B. Datasets & Proxy Records
IV. Modeling Climate Change
A. The Earth As a System
B. Forward & Negative Feedback Loops
C. A closer look at the role of water vapor
7. THE GREENHOUSE EFFECT--
OVERVIEW
Vocabulary in the graphic:
• 1) Incoming solar energy is called solar radiation
• 2) Solar radiation warms the earth
• 3) The warmed earth radiates heat. However, this is not called ‘heat’, but rather in
scientific terms it is energy. The correct term is infrared radiation
• 4) The atmospheric ‘blanket’ is gas molecules in the atmosphere.
Definition
Radiation: energy
that is
propagated in the
form of
electromagnetic
waves.
13. GREENHOUSE GASES
Obviously, those ‘greenhouse gases’ play an
important role in trapping the infrared radiation.
What are they?
In order of abundance:
1.Water vapor (H2O)
2.Carbon Dioxide (CO2)
3.Methane (CH4)
4.Nitrous Oxide (N2O )
5.Ozone (O3)
14. GREENHOUSE GASES
1. The atmosphere is a layer of gaseous materials,
some of which interact with infrared radiation and
absorb and re-radiate that energy
2. The greenhouse gases have been in the
atmosphere a long time (billions of years). They
maintain the planet’s global temperature in a
range that allowed our life forms to evolve
3. If they have always been there, and the
‘greenhouse effect’ is natural, then why do we now
hear about it causing the earth’s temperature to
rise?
4. Answer?
The amount of greenhouse gases in the
atmosphere is increasing
15. GREENHOUSE GASES
Greenhouse Gas Increases in the last 100 years
Greenhouse
Gas
Concentration
1800s
Concentration
1990s
Percent
Increase
Anthropogenic
Sources
CO2 280 ppm 360 ppm 29% burning fossil
fuels;
deforestation
CH4 0.95 ppm 1.7 ppm 79% agriculture; fuel
leakage
CFCs 0 0.7 ppb ---- refrigerants
N2O 250 ppb 310 ppb 24% agriculture;
combustion
O3 15 ppb 20-30 ppb 33-100% urban pollution
16. GREENHOUSE GASES
The biggest problem is
increasing CO2, carbon
dioxide.
CH4, Methane, is also
increasing and interacts
with IR and has more
“global warming potential”
than CO2
Water in the atmosphere
is in the gas or vapor form.
(In fact if it becomes liquid
form then it falls out of the
atmosphere.. as..?)
Water vapor also traps
heat and is a GG
But - It’s a complicated
story because vapor as
clouds may cool the earth
Things to Know Water vapor
17. NOTICE!:
1) THE CO2-TEMP CORRELATION. IS IT CAUSE-EFFECT?
2) THE RATE AND DEGREE OF CHANGE OF C02 IN THE
PAST 200 YEARS. HOW DOES IT COMPARE TO THE PAST
150,000 YEARS?
Long-term Records of C02
Long-term proxy
records show
that the earth’s
temperature
varied
considerably
over the past
150,000 years
20. INTRODUCTION TO CARBON
CYCLING
This module will introduce you to the global carbon cycle.
An important idea in this section is that the atmosphere, oceans
and land are all connected through the cycling of elements such
as carbon.
The earth is one system and everything that happens on our
planet becomes part of the interactions between air, water, land
and life.
The global carbon cycle has been disrupted and is causing climate
change.
21. THE CARBON CYCLE: WHAT IS
CARBON?
Carbon is an element. ‘C’
It can bond with oxygen and form Carbon Dioxide
or ‘CO2’. CO2 is found in the atmosphere (and the
air around us).
C can dissolve in water and bond with other
molecules to form liquid compounds such as
carbonic acid.
C also bonds with other carbon molecules to form
numerous compounds, for example sugars and
carbohydrates, that are a part of all living
organisms.
22. THE CARBON CYCLE: WHAT IS
CARBON?
Two important points:
1) Carbon can be in the form of a gas (in the atmosphere), a liquid
(in oceans) and a solid (in all living things on land, and in some
rock formations).
2) Carbon forms the backbone of the biology of all life on earth.
All plants and animals on land and in the water use carbon as a
basic building block. To date, no life has been observed that is
not carbon-based.
( Star Trek had a
silica-based life
form called a
horta)
23. THE CARBON CYCLE: WHAT IS A
CYCLE?
The carbon cycle: what does ‘cycle’ mean?
A cycle has no distinct beginning and end
Carbon is a part of the biogeochemical cycling of elements
that interconnects the land, the air, and the waters
‘Bio’ – living or biotic elements
‘Geo’ – earth, geology, soils
‘Chemical’ – molecules and compounds
This is a cycle.
It is a circular pathway and has
no clear start and finish.
This is a line.
This is a linear process.
24. The Carbon Cycle: What is a cycle? When you
think of the earth, think of it as a system.
The earth is a system in which materials, suchas
carbon and water, continuously cycle. Keep this
image in mind.
Or, do you know another image that means ’inter-
connectedness’ to you?
25. THE CARBON CYCLE
Carbon molecules cycle, meaning that they move
through the land, the air, and the water.
Here is one example of a ‘trip’ that a carbon molecule
may take:
A tree in a forest is made of carbon (C ). When it burns, some C is
converted/released as carbon dioxide (CO2). This CO2 goes into the
atmosphere and travels through the air currents. A corn plant then
takes up that CO2 in photosynthesis and uses it to make
carbohydrates that go into a corn kernel. The corn is harvested and
made into breakfast cereal that you eat - and that C is now a part
of you.
Carbon illustrates the interconnection of all organisms on earth,
and their connection to the atmosphere and waters of the planet.
26. CARBON CYCLING ON THE LAND:
PLANTS AND SOIL
Carbon moves in and
out of plants and soil as
CO2
Photosynthesis in plant
leaves
Takes in CO2
CO2 is ‘food’ for plants
Respiration in plant
leaves, roots, and soil
Releases CO2
CO2 is produced in
metabolism and the extra
is released
Soils have microbes that
decompose plant material when it
falls to the ground. Microbes are
alive and they respire as part of
their metabolism.
28. CARBON CYCLING ON THE LAND:
PLANTS AND SOIL
Just to be sure you understand this…..
Plants run the carbon cycle on land.
CO2 +
Water +
Sunlight
Photosynthesis
Make C-rich
sugars and
carbohydrate
s to feed
themselves
and grow
Respiration
Grow and
store C in
the plant
Some CO2 is lost
from the plant in
the process of
metabolism
CO2 + O2
Die, decay
and store
C in soil
29. CAN YOU DRAW THE PLANT AND SOIL C
CYCLE ?
For practice - draw a simple diagram of the carbon cycle in a forest.
Where is CO2 moving into and out of the atmosphere? Draw arrows
showing how CO2 cycles between the atmosphere, plants, and soil.
Leaves take in CO2 from the air and use it for photosynthesis
All plant parts – leaves, wood, even roots – respire CO2 back out to
the air
Also, as plants decay, soil microbes respire CO2 into the air
Where is carbon stored? Label where Carbon is stored as plant material
or in soils.
Carbon is in wood, leaves, flowers, all plant parts
Carbon is belowground in the roots
Carbon is in the soil as organic matter – the decaying plant parts
30. CARBON CYCLING IN THE OCEAN
The oceans play a vital
role in the global
carbon cycle
CO2 mixes in the ocean
and cycles between the
ocean surface and the
atmosphere
CO2 is stored in the
ocean waters and in
sediments of the deep
ocean floor
Carbon is stored in the ocean as it
dissolves in sea water, and it is stored
when it forms sedimentary rock in the
deep ocean floor
CO2 mixing
Dissolved carbon
in ocean water
Calcium carbonate
in ocean floor
31. CAN YOU DRAW THE GLOBAL C CYCLE
FOR LAND AND OCEANS ?
Go back to the simple drawing you did of the carbon cycle on land in a forest.
Now add carbon cycling of the ocean to the drawing.
Where is CO2 moving into and out of the atmosphere? ? Draw arrows showing
how CO2 cycles between the atmosphere, plants, and soil. Draw arrows showing
how CO2 cycles between the atmosphere and ocean.
Where is carbon stored? Label where carbon is stored as plant material or in
soils. Also label the carbon stored in seawater and in the ocean floor.
IMPORTANT: The movement of C in and out of the atmosphere as CO2 is called
a ‘flux’. Fluxes are shown by arrows in a diagram. When C is stored it is just
labeled as carbon or else it is shown in a box in a diagram.
Student Handout #2 – graphic of the carbon cycle. Compare your drawing and
check to see if your drawing has the correct ideas.
32. THE GLOBAL CARBON CYCLE
Which exchanges of CO2
with the atmosphere
have always been a
part of the global
carbon cycling system
and are in your
drawing?
Which are not in your
drawing? These are
due to human
activities!
Terrestrial Oceans
(Student Handout #2 here –
“Intro to C cycling” for use in
class with next 3 slides)
33. DISRUPTION OF THE NATURAL
GLOBAL CARBON CYCLE
The two human activities that add the most CO2 to the
atmosphere are:
Extracting the very old,
buried C that is oil, coal
and natural gas.
Burning it for energy
releases CO2.
Land clearing and
deforestation of tropical
forests. The slash piles are
burned and release CO2
34. THE GLOBAL CARBON CYCLE
Ok – one more
time: Where is
carbon?
1)Atmosphere
2) Ocean
3) Land
And…
buried deep in
the earth as
decayed plant
material from
long ago.... Fossil
Fuels such as
coal, oil and gas
35. DO YOU GET THE CONCEPT?
Take a minute and answer these questions:
What is a possible connection between a car driving down the
road and the amount of CO2 in the atmosphere. Between a
tree growing in a forest and the amount of CO2 in the
atmosphere?
CO
2
CO
2CO2 CO2
36. CARBON CYCLING: IMPORTANT!!!
THE AMOUNT OF CO2 IN THE
ATMOSPHERE IS INCREASING
Since the 1970s scientists
have been measuring the
concentration of CO2 in
the atmosphere at a tower
in Mauna Loa, Hawaii.
Concentration is
measured in ppm (parts
per million).
CO2 has increased from an
average of about 325 ppm
in 1970 to an average of
about 385 ppm in 2008
(Student Handout #3
here – “Increasing
atmospheric CO2” - for
use in class with next 2
slides)
37. CO2 IN THE ATMOSPHERE IS
INCREASING
How can scientists know what the atmospheric concentration of CO2 was
before they had the Mauna Loa tower?. They can estimate CO2 using ice
cores pulled from ice sheets in Antarctica and Greenland.
This is called a ‘proxy record’
Measurements from Antarctic ice cores show that atmospheric CO2
concentrations stayed between about 200 and 290 ppm during the
preceding 400,000 years.
38. NOTICE:
1) THE CO2-TEMP CORRELATION. IS IT CAUSE-EFFECT?
2) THE RATE AND DEGREE OF CHANGE OF C02 IN THE
PAST 200 YEARS. HOW DOES IT COMPARE TO THE PAST
150,000 YEARS?
Long-term records of temperature & C02
Long-term proxy
records show
that the earth’s
temperature
varied
considerably
over the past
150,000 years
40. Houghton, unpublished
Carbon Emissions from Tropical Deforestation
PgCyr-1
0.00
0.20
0.40
0.60
0.80
1.00
1.20
1.40
1.60
1.80 1850
1860
1870
1880
1890
1900
1910
1920
1930
1940
1950
1960
1970
1980
1990
2000
Africa
Latin America
S. & SE Asia
Source: Anthropogenic C Emissions: Land Use
Change
SUM
2000-2006
1.5 Pg C y-1
(16% total emissions)
42. Partition of Anthropogenic Carbon Emissions into Sinks
Canadell et al. 2007, PNAS
Ocean removes _ 24% Land removes _ 30%
55% were removed by natural sinks
45% of all CO2 emissions accumulated in the atmosphere
The Airborne Fraction
The fraction of the annual
anthropogenic emissions that
remains in the atmosphere
Atmosphere
[2000-2006]
43. Carbon Intensity and the Global Economy
Canadell et al. 2007, PNAS
Carbonintensity
(KgC/US$) Kg Carbon Emitted
to Produce 1 $ of Wealth
1960 1970 1980 1990 2000 20
Photo:CSIRO
44. Raupach et al 2007, PNAS
0.5
0.6
0.7
0.8
0.9
1
1.1
1.2
1.3
1.4
1.5
1980
0.5
0.6
0.7
0.8
0.9
1
1.1
1.2
1.3
1.4
1.5
1980
World
0.5
0.6
0.7
0.8
0.9
1
1.1
1.2
1.3
1.4
1.5
1980 1985 1990 1995 2000 2005
F (emissions)
P (population)
g = G/P
h = F/G
Factor(relativeto1990)
Emissions
Population
Wealth = per capita GDP
Carbon intensity of GDP
Drivers of Anthropogenic Emissions
Population growth & Carbon Intensity
45. The Efficiency of Natural Sinks: Land and Ocean Fractions
Land
Ocean
Canadell et al. 2007, PNAS
46. Part of the decline is attributed to up
to a 30% decrease in the efficiency of
the Southern Ocean sink over the
last 20 years.
This sink removes annually 0.7 Pg of
anthropogenic carbon.
The decline is attributed to the
strengthening of the winds around
Antarctica which enhances ventilation
of natural carbon-rich deep waters.
The strengthening of the winds is
attributed to global warming and the
ozone hole.
Causes of the Declined in the Efficiency of the Ocean Sink
Le Quéré et al. 2007, Science
Credit:N.Metzl,August2000,oceanographiccruiseOISO-5
48. RISING TEMPERATURE
The earth’s temperature has increased in the
last 200 years - this is a scientific fact.
The temperature increase of the last 200 years
has been measured.
Temperature change is not the same all over the
world. In fact, some places are the same or
cooler, although most places are warmer. It’s
the global average that’s increased.
Here is the important point:
The globally averaged earth surface temperature
has increased, it has increased in the last 200
years, and the increase was measured by
weather instruments.
49. WHAT IS KNOWN—THE EARTH IS
WARMING
“Warming of the climate
system is unequivocal,
as is now evident from
observations of
increases in global
average air and ocean
temperatures,
widespread melting of
snow and ice and
rising global average
sea level.”
IPCC report 2007, synthesis, p. 30
50. IPCC 2007 REPORT
Eleven of the last twelve years (1995–2006) rank
among the 12 warmest years in the instrumental
record of global surface temperature (since 1850).
The linear warming trend over the last 50 years
(0.13°C [0.10°C to 0.16°C] per decade) is nearly
twice that for the last 100 years.
The total temperature increase from 1850–1899
to 2001–2005 is 0.76°C [0.57°C to 0.95°C].
Urban heat island effects are real but local, and have a negligible influence (less
than 0.006°C per decade over land and zero over the oceans) on these values.
52. RISING TEMPERATURE
200 years
Measured
Scientific
Fact
What about the last 2000 years?
Or 200,000 years?
How do we determine this?
Scientists use “proxy methods” to
estimate temperature and carbon
dioxide concentrations
Temperature
Increase
What about longer than
200 years?
53. PROXY RECORDS: ICE CORES
Ice caps and glaciers
accumulated over thousands
or millions of years.
They contain bubbles of gas
preserved from the time
when each layer formed.
Scientists drill cores and
analyze the gas bubbles in
each layer to see what the
atmosphere was like at that
time.
Figure 12.5
54. PROXY RECORDS: POLLEN
ANALYSIS
Scientists also drill
cores into the
sediments of ancient
lake beds.
By identifying types of
pollen grains in each
layer, they can tell
what types of plants
were growing there at
the time.
55. PROXY RECORDS: PACKRAT MIDDENS
For information on other tools used to reconstruct past
climate, see http://cpluhna.nau.edu/Tools/tools.htm
White-throated woodrat
A giant 28,000+
year-old packrat
midden under an
overhang at Capitol
Reef National Park,
Utah. Orange
notebook is 7" X 4".
Photo by Ken Cole
Note: Photos & text on this slide are from:
http://cpluhna.nau.edu/Tools/packrat_middens.htm
Fossil packrat (or woodrat) middens provide
information on past environments because they
are a rich source of debris collected by packrats
in the past.
The packrat often urinates on its garbage pile, marking its territory. When this
urine crystallizes, it acts as a glue holding the entire garbage pile together. Fossil
debris held within the midden becomes mummified, preserving it indefinitely.
56. CLIMATE CHANGE AND THE IPCC
REPORT
Proxy indicators of temperature (from pollen, ice cores,
etc.) were reviewed to establish ancient temperatures.
These data (BLUE) overlapped with the direct temperature
measurements (RED). (Gray shows statistical uncertainty.)
58. STUDYING CLIMATE CHANGE:
MODELING
To predict what will happen to climate in the
future, scientists use climate models:
Computer simulations that use known
behavior of past climate to analyze how climate
should behave as variables are changed.
Coupled general circulation models
(CGCMs) are models that combine, or couple,
the effects of both atmosphere and ocean.
59. EARTH’S ENVIRONMENTAL
SYSTEMS
Our planet consists of many complex, large-scale,
interacting systems.
System = a network of relationships among a group of
parts, elements, or components that interact with and
influence one another through the exchange of energy,
matter, and/or information
Feedback loop = a circular process whereby a
system’s output serves as input to that same system.
60. FEEDBACK LOOPS: NEGATIVE
FEEDBACK
In a negative feedback loop, output acts as input that
moves the system in the opposite direction.
This compensation stabilizes the system
61. NEGATIVE FEEDBACK LOOPS
1. Increase oceanic
algae = more
absorption
2. Increase plant
growth = more
absorption
3. More polar snow
= more
reflectance
4. More clouds =
more reflectance
62. FEEDBACK LOOPS: POSITIVE
FEEDBACK
In a positive
feedback loop,
output acts as
input that moves
the system
further in the
same direction.
This
magnification of
effects
destabilizes the
system.
63. POSITIVE FEEDBACK LOOPS
5. More clouds =
more greenhouse
effect
6. Melting
permafrost =
more methane
7. Less snow/ice =
less reflectance
8. More warmth =
more air
conditioning
65. GREENHOUSE GASES
WHAT ABOUT CLOUDS?
Most scientists predict that cloudiness will
increase as the climate warms. But, what
do more clouds do to the earth’s
temperature?
1. Increase temperature because water
vapor traps heat? A positive feedback
2. Decrease temperature by shielding the
earth from incoming solar radiation. A
negative feedback.
3. Hard to know. Plus – depends on the
66. WHAT ABOUT CLOUDS?
Altitude
10 km
Cumulus/stratus clouds
Cirrus clouds
(Thin)
(Thicker)
Less reflection
More reflection
Fat, low clouds could cool
the earths temperature by
blocking incoming radiation
Thin, High clouds could warm
the earth’s temperature by
trapping IR
IR
67. Canadell JG, Corinne Le Quéré, Michael R. Raupach, Christopher B. Field, Erik T. Buitehuis,
Philippe Ciais, Thomas J. Conway, NP Gillett, RA Houghton, Gregg Marland (2007) PNAS.
Canadell JG, Pataki D, Gifford R, Houghton RA, Lou Y, Raupach MR, Smith P, Steffen W
(2007) in Terrestrial Ecosystems in a Changing World, eds Canadell JG, Pataki D, Pitelka L
(IGBP Series. Springer-Verlag, Berlin Heidelberg), pp 59-78.
Raupach MR, Marland G, Ciais P, Le Quéré C, Canadell JG, Klepper G, Field CB, PNAS
(2007) 104: 10288-10293.
Le Quéré C, Rödenbeck C, Buitenhuis ET, Thomas J, Conway TJ, Langenfelds R, Gomez A,
Labuschagne C, Ramonet M, Nakazawa T, Metzl N, et al. (2007) Science 316:1735-1738.
References
Notes de l'éditeur
The earth’s atmosphere serves as a blanket that lets in energy from the sun (heat) and traps some of it. It does not trap all of the energy (heat) but rather some heat escapes back out to the atmosphere. In this way the earth maintains a nice ‘liveable’ warm temperature under its cozy atmosphere blanket. If the atmosphere blanket gets thicker, its OK, because it still lets in the energy needed to keep the earth warm. However, there is a problem. If the atmospheric blanket gets thicker it does not let enough heat escape back out to the atmosphere. A thick atmospheric blanket means that more and more heat is trapped.
This is similar to what happens in a car sitting in the sun with closed windows. Or, in a greenhouse (get it?).
You will now learn how to describe this ‘cozy blanket’ in terms of the earth’s energy balance.
Notice that for the first time in 50 years, emissions from tropical Latin American are similar to those from South and Southeast Asia.
Current emissions are tracking above the most intense fossil fuel scenario established by the IPCC SRES (2000), A1FI- A1 Fossil Fuel intensive; and moving away from stabilization scenarios of 450 ppm and 650 ppm.
Carbon intensity of the global economy has stopped decreasing after decades of doing so. The lack of improvement (decrease) has been maintained since 2000 to 2006.
This implies that relatively more global wealth is produced by using more carbon intensive energy systems than we did in the past.
The carbon intensity of the economy is the amount of C emissions required to produce 1$ of wealth (GDP-Gross Domestic Product at the country level, or Gross World Product if referred globaly)
In this analysis we don’t detect a trend in the fraction of carbon being removed by the land sink; this doesn’t exclude the possibility that there is a trend given the large inter-annual variability of the land sink, and the fact that the land sink is not calculated directly but obtained as a residual quantity from closing the carbon budget.
The fraction going into the ocean sink has clearly declined over the last 50 years.