Hurricane Katrina A Problem-Based Learning Module
ESSEAEarth System Science Education Alliance
March 2010 l http://essea.strategies.org
FOR THE TEACHER n KEY CONCEPTS1. Hurricanes are tropical cyclones that
contain winds in excess of 119 km/hr (74 mph) or more. They are fueled by the energy stored in warm tropical ocean waters.
2. Hurricanes impact all the Earth’s spheres because of their size and energy.
3. NASA and NOAA observe hurricanes to learn more about predicting their path and behaviors.
4. Atmospheric patterns are complex and varied, making hurricane prediction and study difficult.
5. A majority of Earth’s inhabitants live close enough to coastal areas to be affected by tropical cyclones.
6. Damage from hurricanes is not confined to terrestrial areas—for example, coral reefs near shore are often affected.
7. Hurricanes damage infrastructure, housing, agriculture, and threaten lives. A single storm’s impact is often felt for years or decades.
8. The relationship of climate change to projected increases in hurricane numbers and intensity is the subject of much current research.
Recent assessments from the Intergovernmental Panel on Climate Change (IPCC, 2007) and the U.S. Climate Change Science Program (CCSP, June 2008) state it is likely that tropical cyclones (typhoons and hurricanes) will become more intense, with increased rainfall and wind speeds, in response to increases in tropical sea surface temperatures.
A more recent study by top climate change and hurricane scientists found that climate change is likely to result in fewer but stronger hurricanes (Knutson et al., Nature Geoscience, Feb. 2010).
n SOURCESClimate Change 2007: The Physical Science Basis. Contribution of Working Group I to the Fourth Assessment Report of the IPCC • http://www.ipcc.ch/ipccreports/ar4-wg1.htmCCSP, Weather and Climate Extremes in a Changing Climate, June 2008 • http://www.climatescience.gov/Library/sap/sap3-3/final-report/default.htmAmerican Meteorological Society, Climate Change Information Statement, 2007 • http://www.ametsoc.org/POLICY/2007climatechange.html
“Tropical cyclones and climate change,” Nature Geoscience, Feb. 2010 • http://www.nature.com/ngeo/journal/vaop/ncurrent/full/ngeo779.html
n RELATED INVESTIGATIONSMY NASA DATA: Hurricanes As Heat Engines (Grades 6–12)http://mynasadata.larc.nasa.gov/Hurricane_Heat_Engine.htmlStudents examine sea surface temperature data to explore how hurricanes extract heat energy from the ocean surface. Stronger Hurricanes? (Grades 5–12)http://www.pbs.org/wgbh/nova/sciencenow/3302/07.html A six-minute segment from NOVA examines the link between rising sea surface temperature and storm intensity. Links are also provided to additional resources, including a teacher’s guide and transcript of the broadcast.
The student pages of this activity (pgs. 2–4) can be viewed online or downloaded at: http://www.strategies.org/Katrina_StudentActivityPBL.pdf
The full version, with teacher notes, can be downloaded at: http://www.strategies.org/Teacher2010Pages/ KatrinaAll.pdfNational Science Education Standards
Grades 5-8 Grades 9-12
Science as Inquiry
Abilities necessary to do scientific inquiry;
Life Science
Populations and ecosystems Interdependence of organisms;Matter, energy and organization in living things
Earth and Space Science
Structure of the Earth system—oceans hold a large amount of heat and have a major effect on climate
Energy in the Earth system;Geochemical cycles
Science in Personal and Social Perspectives
Populations, resources and environments;Natural resources; Risks and benefits
Natural and human-induced hazards; Science and technology in local, national and global challenges
Understandings about scientific inquiry
FOR THE STUDENT n SCENARIO Summer 2005 was winding down when a monster storm was just beginning to brew. Hurricane Katrina started as a tropical storm in the Bahamas on Aug. 24. It began moving slowly to the northwest, then west, gaining strength as it moved through the warm Atlantic waters. Just a few hours before hitting the Florida coast on Aug. 25, Katrina became a Category 1 hurricane—wind speeds over 119 km/hr (74 miles per hour) or more. The storm’s winds slowed only slightly as it moved across the tip of the Florida peninsula in seven hours.
Then the storm hit the warm waters of the Gulf of Mexico and quickly picked up speed. It moved across the Gulf where conditions in the atmosphere and sea surface were perfect for fueling the storm. Katrina exploded into a Category 5 hurricane on Aug. 28, with winds peaking at 282 km/hr (175 mph). Before making landfall on Aug. 29, the storm was at the top end of Category 3 intensity, with estimated sustained winds of 110 knots (127 mph).NASA—http://disc.gsfc.nasa.gov/hurricane/HurricaneKatrina2005.shtml
Katrina was one of the deadliest and costliest hurricanes to hit the United States. It killed over 1,500 and caused an estimated $80–$100 billion in
damages. The storm’s destruction spread along the U.S. central Gulf Coast, from central Florida to Texas. Coastal cities such as New Orleans, Louisiana, Mobile, Alabama, and Gulfport, Mississippi were hardest hit. Much of the damage was caused by the storm surge and levee breaks between New Orleans and Lake Pontchartrain.
1995 was the start of a more active period for hurricanes. In 2005 alone there were a record 27 named storms, of which 15 became hurricanes. The previous record (21) was in 1933. 2005 also had the largest number (4) of Category 5 storms. National Climatic Data Center, Climate of 2005: Atlantic Hurricane Season—http://www.ncdc.noaa.gov/oa/climate/research/2005/hurricanes05.html
Over the past 35 years the number of Category 4 and 5 hurricanes worldwide has nearly doubled. Global sea-surface temperatures have also increased over the same period. National Science Foundation— http://www.nsf.gov/news/news_summ.jsp?cntn_id=104428
Are recent increases in the number and strength of hurricanes a result of an increased greenhouse effect and a warmer climate? Or are they the result of a natural cycle? Scientists continue to research what is causing this trend. However, there is no doubt that these storms have a huge impact on coastal communities.
Hurricane Katrina A Problem-Based Learning Module
ESSEAEarth System Science Education Alliance
March 2010 l http://essea.strategies.org
Hurricane Katrina A Problem-Based Learning Module
March 2010 2
What Is an Earth System Science Analysis?
Earth is a system. The system can be divided into four major parts called “spheres.” These are the atmosphere (air), biosphere (all living things, including people), lithosphere (land) and hydrosphere (water in all forms, including liquid, frozen and vapor).
Earth’s spheres interact. An event—such as a hurricane—can cause changes or impacts to one or more of Earth’s four spheres; it can also be the result of such changes. The two-way, cause-and-effect relationship between an event and a sphere is called an interaction. Interactions also occur between the spheres; for example, a change in the atmosphere can cause a change or impact in the hydrosphere, and vice versa.
Your Earth system science analysis (ESS) should include a description of the impacts and interactions between and among Hurricane Katrina and the Earth’s spheres.
An ESS analysis is done in three steps, which include looking at:• How the event affects each of the spheres (E>S);• How the spheres affect the event (S>E); and• How the spheres affect each other (S>S).
A very simple example: L>E = impact of the lithosphere (L) on the hurricane (E). As the hurricane passes over land, the energy source (warm ocean water) is removed and the hurricane starts to weaken.
Causal Chains: In a system, nothing occurs in isolation. The interactions that occur within Earth’s system actually occur as a series of chain reactions and complex interactions. Make sure that your analysis includes the systemic relationships, called causal chains, where multiple spheres and/or the event are involved in complex and interrelated changes. Each causal chain should include at least three interactions (e.g., E>S>S or S>S>S).
n YOUR TASKU.S. coastal areas are critically important to the nation’s economy. For that reason, NASA and the National Ocean Service have formed a joint task force that is studying the trends and impacts of hurricanes on coastal regions. They have invited your group to participate.
You are tasked with conducting an Earth system science analysis of Hurricane Katrina. Your report should also examine the question: “How could future climate change impact the frequency and intensity of hurricanes?”
n RESOURCESHere are some resources to get you started. You will need to find additional, high-quality resources to complete your task.
Arlene to Zeta: 27 Storms of the 2005 Season http://svs.gsfc.nasa.gov/goto?3354
Hurricane-Biosphere Connection http://www.nasa.gov/centers/goddard/news/topstory/2004/0602hurricane bloom.html
NASA Hurricane Resource Page http://www.nasa.gov/mission_pages/hurricanes/main/index.html
National Hurricane Center http://www.nhc.noaa.gov
Stronger Hurricanes: Is Global Warming Making Hurricanes More Intense?
http://www.pbs.org/wgbh/nova/sciencenow/3302/07.html
March 2010 3
n ASSIGNMENTWorking with your group, use the following problem solving model to do your project.
1. Read and analyze the scenario and task on pages 1–2:• Discuss the scenario with your team.• Don’t be tempted to start thinking about potential
solutions or to start looking for information.
2. List initial hypotheses, ideas, or hunches:• Based on what you have read, what do you think?• List your ideas, hunches, or hypotheses.
3. List what you already know:• Begin your list with the information contained
in the scenario.• Add knowledge shared by other group members.• Record this information under the heading:
“What do we know?”
4. List what is unknown:• Prepare a list of questions your group thinks need
to be answered to do your analysis.• Record them under the heading: “What do we
need to know?”
5. List what needs to be done:• Develop a plan. List actions such as questioning an
expert, getting online data, or visiting a library to find answers to the questions developed in Step 4.
• Prioritize the questions you are trying to answer, then divide up the questions among your team.
6. Develop a problem statement:• A problem statement is a one- or two-sentence idea
that clearly identifies what your team is trying to solve, produce, respond to, test, or find out.
• Record your statement.
7. Gather information:• Record your information and resources.• You and your team will gather, organize, analyze,
and interpret information from multiple sources.• Exchange ideas; think about solutions; weigh
alternatives; and consider the pros and cons of potential courses of action.
8. Present findings:• Prepare a report or presentation in which you and
your group make recommendations, predictions, inferences, or other appropriate resolutions of the problem.
• Be prepared to support your positions. If appropriate, consider a multimedia presentation using images, graphics, and/or sound.
The steps in this model may need to be completed several times. Steps 2 through 6 may be conducted at the same time, as new information becomes available. As more information is gathered, the problem statement may be refined or altered.
Hurricane Katrina A Problem-Based Learning Module
All satellite images courtesy of NASA and NOAA.
Summer 2005 was winding down when a monster storm was just beginning to brew. Hurricane Katrina started as a tropical storm in the Bahamas on Aug. 24. It began moving slowly to the northwest, then west, gaining strength as it moved through the warm Atlantic waters. Just a few hours before hitting the Florida coast on Aug. 25, Katrina became a Category 1 hurricane—wind speeds over 119 km/hr (74 miles per hour) or more. The storm’s winds slowed only slightly as it moved across the tip of the Florida peninsula in seven hours.
Then the storm hit the warm waters of the Gulf of Mexico and quickly picked up speed. It moved across the Gulf where conditions in the atmosphere and sea surface were perfect for fueling the storm. Katrina exploded into a Category 5 hurricane on Aug. 28, with winds peaking at 282 km/hr (175 mph). Before making landfall on Aug. 29, the storm was at the top end of Category 3 intensity, with estimated sustained winds of 110 knots (127 mph).NASA—http://disc.gsfc.nasa.gov/hurricane/HurricaneKatrina2005.shtml
Katrina was one of the deadliest and costliest hurricanes to hit the United States. It killed over 1,500 and caused an estimated $80–$100 billion in damages. The storm’s destruction spread along the U.S. central Gulf
Coast, from central Florida to Texas. Coastal cities such as New Orleans, Louisiana, Mobile, Alabama, and Gulfport, Mississippi were hardest hit. Much of the damage was caused by the storm surge and levee breaks between New Orleans and Lake Pontchartrain.
1995 was the start of a more active period for hurricanes. In 2005 alone there were a record 27 named storms, of which 15 became hurricanes. The previous record (21) was in 1933. 2005 also had the largest number (4) of Category 5 storms. National Climatic Data Center, Climate of 2005: Atlantic Hurricane Season—http://www.ncdc.noaa.gov/oa/climate/research/2005/hurricanes05.html
Over the past 35 years the number of Category 4 and 5 hurricanes worldwide has nearly doubled. Global sea-surface temperatures have also increased over the same period. National Science Foundation— http://www.nsf.gov/news/news_summ.jsp?cntn_id=104428
Are recent increases in the number and strength of hurricanes a result of an increased greenhouse effect and a warmer climate? Or are they the result of a natural cycle? Scientists continue to research what is causing this trend. However, there is no doubt that these storms have a huge impact on coastal communities.
Hurricane Katrina A Problem-Based Learning Module
March 2010 1
n SCENARIO
FOR THE STUDENT
Hurricane Katrina A Problem-Based Learning Module
March 2010 2
What Is an Earth System Science Analysis?
Earth is a system. The system can be divided into four major parts called “spheres.” These are the atmosphere (air), biosphere (all living things, including people), lithosphere (land) and hydrosphere (water in all forms, including liquid, frozen and vapor).
Earth’s spheres interact. An event—such as a hurricane—can cause changes or impacts to one or more of Earth’s four spheres; it can also be the result of such changes. The two-way, cause-and-effect relationship between an event and a sphere is called an interaction. Interactions also occur between the spheres; for example, a change in the atmosphere can cause a change or impact in the hydrosphere, and vice versa.
Your Earth system science analysis (ESS) should include a description of the impacts and interactions between and among Hurricane Katrina and the Earth’s spheres.
An ESS analysis is done in three steps, which include looking at:• How the event affects each of the spheres (E>S);• How the spheres affect the event (S>E); and• How the spheres affect each other (S>S).
A very simple example: L>E = impact of the lithosphere (L) on the hurricane (E). As the hurricane passes over land, the energy source (warm ocean water) is removed and the hurricane starts to weaken.
Causal Chains: In a system, nothing occurs in isolation. The interactions that occur within Earth’s system actually occur as a series of chain reactions and complex interactions. Make sure that your analysis includes the systemic relationships, called causal chains, where multiple spheres and/or the event are involved in complex and interrelated changes. Each causal chain should include at least three interactions (e.g., E>S>S or S>S>S).
n YOUR TASKU.S. coastal areas are critically important to the nation’s economy. For that reason, NASA and the National Ocean Service have formed a joint task force that is studying the trends and impacts of hurricanes on coastal regions. They have invited your group to participate.
You are tasked with conducting an Earth system science analysis of Hurricane Katrina. Your report should also examine the question: “How could future climate change impact the frequency and intensity of hurricanes?”
n RESOURCESHere are some resources to get you started. You will need to find additional, high-quality resources to complete your task.
Arlene to Zeta: 27 Storms of the 2005 Season http://svs.gsfc.nasa.gov/goto?3354
Hurricane-Biosphere Connection http://www.nasa.gov/centers/goddard/news/topstory/2004/0602hurricane bloom.html
NASA Hurricane Resource Page http://www.nasa.gov/mission_pages/hurricanes/main/index.html
National Hurricane Center http://www.nhc.noaa.gov
Stronger Hurricanes: Is Global Warming Making Hurricanes More Intense?
http://www.pbs.org/wgbh/nova/sciencenow/3302/07.html
March 2010 3
n ASSIGNMENTWorking with your group, use the following problem solving model to do your project.
1. Read and analyze the scenario and task on pages 1–2:• Discuss the scenario with your team.• Don’t be tempted to start thinking about potential
solutions or to start looking for information.
2. List initial hypotheses, ideas, or hunches:• Based on what you have read, what do you think?• List your ideas, hunches, or hypotheses.
3. List what you already know:• Begin your list with the information contained
in the scenario.• Add knowledge shared by other group members.• Record this information under the heading:
“What do we know?”
4. List what is unknown:• Prepare a list of questions your group thinks need
to be answered to do your analysis.• Record them under the heading: “What do we
need to know?”
5. List what needs to be done:• Develop a plan. List actions such as questioning an
expert, getting online data, or visiting a library to find answers to the questions developed in Step 4.
• Prioritize the questions you are trying to answer, then divide up the questions among your team.
6. Develop a problem statement:• A problem statement is a one- or two-sentence idea
that clearly identifies what your team is trying to solve, produce, respond to, test, or find out.
• Record your statement.
7. Gather information:• Record your information and resources.• You and your team will gather, organize, analyze,
and interpret information from multiple sources.• Exchange ideas; think about solutions; weigh
alternatives; and consider the pros and cons of potential courses of action.
8. Present findings:• Prepare a report or presentation in which you and
your group make recommendations, predictions, inferences, or other appropriate resolutions of the problem.
• Be prepared to support your positions. If appropriate, consider a multimedia presentation using images, graphics, and/or sound.
The steps in this model may need to be completed several times. Steps 2 through 6 may be conducted at the same time, as new information becomes available. As more information is gathered, the problem statement may be refined or altered.
Hurricane Katrina A Problem-Based Learning Module
All satellite images courtesy of NASA and NOAA.
QU
ALI
TY O
F U
ND
ERST
AN
DIN
G: A
ccur
acy
of id
eas,
fact
s and
stat
emen
ts (a
sser
tions
) abo
ut in
tera
ctio
ns a
nd ca
usal
cha
ins
4 Ra
ting
Resp
onse
is co
mpl
ete
and
corr
ect.
3 Ra
ting
Mos
tly co
rrec
t with
no
m
ajor
err
ors,
misc
once
ptio
ns
or o
miss
ions
. May
cont
ain
up
to 3
min
or in
accu
raci
es.
2 Ra
ting
Part
ially
corr
ect w
ith
one o
r tw
o sig
nific
ant
omiss
ions
, con
tent
er
rors
or m
ore
than
4
min
or e
rror
s.
1 Ra
ting
Incl
udes
misc
on-
cept
ions
abo
ut k
ey
cont
ent a
nd/o
r se
vera
l sig
nific
ant
cont
ent e
rror
s.
0 Ra
ting
Not
pr
esen
t.
Ratio
nale
*
DEP
TH O
F RE
ASO
NIN
G: C
larit
y an
d fo
cus o
f sup
port
able
idea
s, in
tera
ctio
ns a
nd sy
stem
ic re
latio
nshi
ps
4 Ra
ting
Expl
ains
com
plex
, int
erdi
scip
linar
y ca
usal
chai
ns (e
.g.,
E>S>
S>S>
E);
pred
icts
futu
re e
ffect
s, tr
ansf
ers
unde
rsta
ndin
g to
eva
luat
e ot
her
situa
tions
or t
o m
ake
reco
mm
en-
datio
ns.
3 Ra
ting
Expl
ains
the
proc
esse
s re
spon
sible
for c
ausa
l cha
ins
(e.g
., E>
S>S>
S or
S>S
>S)
from
a sc
ient
ific p
ersp
ectiv
e.
2 Ra
ting
Des
crib
es in
tera
c-tio
ns u
sing
caus
e an
d eff
ect c
onne
ctio
ns,
incl
udin
g se
cond
ary
effec
ts th
at u
nfol
d ov
er ti
me
(e
.g.,
E>S>
S).
1 Ra
ting
Des
crib
es w
hat i
s ha
ppen
ing
in th
e sy
stem
, inc
ludi
ng
char
acte
ristic
s an
d di
rect
effe
cts
of th
e ev
ent o
r co
ntex
t (e.g
., E>
S).
0 Ra
ting
Not
pr
esen
t.
Ratio
nale
*
EVID
ENCE
: Sco
pe, d
etai
l and
acc
urac
y of
the
evid
ence
supp
ortin
g th
e re
latio
nshi
p st
atem
ents
4 Ra
ting
All
asse
rtio
ns a
re su
ppor
ted
with
da
ta (q
uant
itativ
e an
d de
scrip
tive)
fr
om m
ultip
le, r
elia
ble
sour
ces;
uses
dat
a to
crea
te ch
arts
, gra
phs,
map
s, et
c., th
at su
ppor
t cla
ims o
r re
fute
opp
osin
g po
sitio
ns; d
iscus
ses
limita
tions
of t
he d
ata.
3 Ra
ting
All
asse
rtio
ns a
re su
ppor
ted
with
dat
a (q
uant
itativ
e or
de
scrip
tive)
cite
d fr
om re
liabl
e so
urce
s.
2 Ra
ting
Mos
t ass
ertio
ns a
re
supp
orte
d w
ith d
ata
(qua
ntita
tive
or
desc
riptiv
e) ci
ted
from
relia
ble
sour
ces.
1 Ra
ting
Use
s dat
a fro
m
sour
ces t
hat a
re
not c
redi
ble,
lack
s su
ppor
t for
som
e st
atem
ents
, or
lack
s cita
tions
for
som
e dat
a sou
rces
.
0 Ra
ting
Not
pr
esen
t.
Ratio
nale
*
PRES
ENTA
TIO
N: E
SS a
naly
sis i
s cle
arly
and
wel
l com
mun
icat
ed
4 Ra
ting
Exem
plar
y w
ritin
g st
yle
that
is p
ar-
ticul
arly
viv
id, c
ompe
lling
, and
/or
crea
tive.
Exce
llent
org
aniz
atio
n th
at
uses
mul
timed
ia (d
iagr
ams,
grap
hs,
pict
ures
, vid
eo, e
tc) e
ffect
ivel
y to
su
ppor
t the
text
. Tex
t is f
ree
from
gr
amm
atic
al e
rror
s and
typo
s.
3 Ra
ting
Wel
l-writ
ten
and
orga
nize
d te
xt. B
uild
s ide
as a
cros
s par
a-gr
aphs
and
sect
ions
to su
ppor
t th
e m
ain
idea
s. Te
xt is
gen
er-
ally
free
of g
ram
mat
ical
err
ors/
typo
s (no
mor
e th
an 1
–2 m
inor
gr
amm
atic
al e
rror
s and
typo
s).
2 Ra
ting
Text
supp
orts
the
mai
n id
eas.
Sent
ence
st
ruct
ure
som
etim
es
inte
rfer
es w
ith m
ean-
ing.
A fe
w (3
–4)
min
or g
ram
mat
ical
er
rors
and
typo
s.
1 Ra
ting
The
thes
is/m
ain
idea
s abo
ut th
e in
tera
ctio
ns a
re
clea
rly st
ated
. Se
vera
l (5+
) gr
amm
atic
al
erro
rs a
nd ty
pos.
0 Ra
ting
Not
pr
esen
t.
Ratio
nale
*
RU
BR
IC f
or E
valu
atin
g Ea
rth
Syst
em S
cien
ce A
naly
ses
* Ex
plai
n ra
ting w
ith sp
ecifi
c ref
eren
ces t
o th
e ESS
ana
lysis
as e
vide
nce.
Nam
e (S
tude
nt or
Team
)