HomeMy WebLinkAbout07 - Donation for Back Bay Science Center Teaching LabCITY OF NEWPORT BEACH
CITY COUNCIL STAFF REPORT
Agenda Item No. 7
March 25, 2008
TO: HONORABLE MAYOR AND MEMBERS OF THE CITY COUNCIL
FROM: City Manager's Office
Dave Kiff, Assistant City Manager
949/644 -3002 or dkiff@city.newport-beach.ca.us
SUBJECT: Resolution 2008 -_ Authorization to Accept Donations for the Back Bay
Science Center's Teaching Lab Interior Improvements and Furnishing
ISSUE:
Should the City accept donations from various public and private sources to assist in funding the
interior improvements and furnishing /equipping the Back Bay Science Center's teaching lab?
RECOMMENDATION:
Adopt Resolution 2008 -_ authorizing the City Manager to accept, invest, and expend funds in
accordance with the City's investment policy which are donated from various sources (private
individuals, corporations, non - profits, and state agencies) for the interior of the Back Bay
Science Center's teaching lab.
DISCUSSION:
The City is one of four major funding partners for the Back Bay Science Center (BBSC), a
13,900 square foot educational and research facility on Shellmaker Island in the Upper Newport
Bay Ecological Reserve. For more information about the BBSC, see the City's website
(www. city. newport-beach.ca. us) and a February 28, 2006 staff report authorizing the
construction of the BBSC.
The last part of the BBSC that remains incomplete is the interior to the "Teaching Lab" wing of
the facility. About $530,000 is needed to finish up the recommended tenant improvements and
to furnish and equip the facility. The City and our other funding partners will be working the
attached Funding Proposal (see Attachment B) through various grant agencies, non - profits, and
others to seek the full funding of the Tls and FF &E for the Teaching Lab.
The attached resolution (see Attachment A) authorizes the City to accept any donations, to
invest them appropriately, and to expend them on the Tis and FF &E for the BBSC Teaching
Lab.
Environmental Review: The City Council's approval of this Agenda Item does not require
environmental review.
Public Notice: This agenda item may be noticed according to the Brown Act (72 hours in
advance of the public meeting at which the City Council considers the item).
Back Bay Science Center
Funding Proposal
Page 2
Submitted by:
(~
5a- Ive iff
Assistant City Manager
Attachments: A — Resolution 2008-
_
B — BBSC Funding Proposal
FA
Bads Bay Science Center
Funding Proposal
Page 3
Attachment A
RESOLUTION 2008-
A RESOLUTION OF THE CITY COUNCIL
OF THE CITY OF NEWPORT BEACH
RELATING TO THE ACCEPTANCE OF GRANTS AND
DONATIONS FOR THE INTERIOR OF THE TEACHING
LAB OF THE BACK BAY SCIENCE CENTER
WHEREAS, the City of Newport Beach and three other major partners (the California
Department of Fish and Game, the University of California, Irvine, and the County of Orange)
have jointly funded the construction of the Back Bay Science Center (BBSC) on Shellmaker
Island; and
WHEREAS, the BBSC has long been envisioned to have a Teaching Lab from which
research and education will be brought forth regarding Upper Newport Bay, water quality, and
estuarine habitat generally; and
WHEREAS, the Teaching Lab is today a shell, but with detailed plans developed to fill the
shell with equipment, wet tables, aquaria, aquaria life support systems, lab tables, and lab
equipment and more; and
WHEREAS, several entities have expressed an interest in donating to the Tenant
Improvements (Tis) and Furniture, Fixtures, and Equipment (FF &E) of the Teaching Lab; and
WHEREAS, the City desires to accommodate these donations or grants by serving as the
entity that can accept donations and grants, invest them, and expend them on approved Tls and
FF &E for the Teaching Lab; now, therefore be it
RESOLVED by the City Council of the City of Newport Beach that it hereby authorizes the
City Manager to accept donations and grants on behalf of the Tenant Improvements and
FF &E for the Back Bay Science Center.
ADOPTED this 25'h day of March, 2008.
EDWARD D. SELICH
Mayor of Newport Beach
ATTEST:
LAVONNE HARKLESS
City Clerk
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Back Bay Science Center
Funding Proposal
Page 4'
Attachment
Back Bay Science Center (BBSC) Teaching Lab
Funding Request
PROJECT: The Back Bay Science Center- TEACHING LAB
LOCATION: 600A Shellmaker Road, Newport Beach, California 92660
Upper Newport Bay Ecological Reserve (Reserve)
Newport Beach, California (Orange County)
OWNER: California Department of Fish and Game
DESCRIPTION: The Back Bay Science Center is a near - completed building of about 13,900
square feet on Shellmaker Island within the Upper Newport Bay Ecological Reserve. The facility
houses:
(a) The Orange County Health Care Agency's water quality testing lab that tests all recreational water
samples from Newport Beach to San Clemente;
(b) A Teaching Lab that will be a base for educators to teach students of all ages (but with a focus on CA
State Science Standards -based curriculum for Grades 7 -12, for community college, and for university)
about the importance of good water quality and the value of the Reserve's habitat;
(c) Permanent offices for DFG as it manages the Ecological Reserve and for volunteers who help with
the education programs and restoration efforts; and
(d) Public restrooms and storage bays for DFG equipment and oil spill response gear.
The project included the conversion .
of degraded uplands on the south
side of Shellmaker Island into a
wetlands demonstration area that
serves as an outdoor laboratory for
scientists and researchers as well as
an outdoor classroom for educators
and students (marsh project funded
by the Wildlife Conservation Board).
A later phase will rehabilitate, extend
and add teaching stations to an
existing interpretive trail to enable
students and the public to better
understand the importance of
preserving the Reserve's habitat.
The project included the
improvement of the existing parking area in a manner that eliminates water quality problems (via
swales, pervious surfaces, and a subterranean catch -basin system). It also created landscaped
buffers of native vegetation (planted and overseen by volunteers and the California Coastal
Commission's local staff) to protect adjacent wetlands form impacts related to light and glare.
PROJECT & FUNDING PARTNERS:
The California Department of Fish and Game (lead agency);
4
The City of Newport Beach;
• The County of Orange's 'Health Care
Agency and its Water Quality Lab;
• The California Coastal Commission
(habitat restoration and the CCC's
Community -based Education &
Curriculum Development);
• The Newport Bay Naturalists and Friends
(docent & restoration teams);
• The University of California, Irvine (UCI
Rowing Center + students doing research
and assisting in the K -14 education
programs); and
• The State Coastal Conservancy, the Irvine
Company, Miocean, and Pacific Life (funding partners).
Back Bay Science Center
Funding Proposal
Page 5
'ROJECT STATUS:
he Project is complete, except for
enant Improvements in the Teaching
ab and the Water Quality Lab. The
3tter improvements are funded, the
xmer are not. The Partners are
eeking funding for the Tls for the
.eaching Lab now.
)VERALL PROJECT COST:
-he Project cost roughly $7.8 million to
onstruct. See Table 1 on Page 3.
tBOUT THE BBSC TEACHING LAB:
-he Teaching Lab is one wing of the
3B'SC. The operating partners propose
i series of science -based activities for
tudents in grades 7 -14 (and community
ollege and university) for the BBSC
eaching Lab. Half of the lab's 2,132
square foot ',interior will be flexible (the
A" side - 1,054 S.F.), allowing chairs and
ables to be moved around depending
m instruction need. The other half (the
B" side - 1,06 8 S.F.) will generally be
ixed in place, equipped like a high
;chool biology lab.
Bay watershed who visit the Teaching
Lab have many projects to work on at the BBSC, including:
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Bads Bay Science Center
Funding Proposal
Page 6
• Up to 30 different labs (Field work and lab work) - Grades 7 -12 (see Attachment A). These
labs are aligned to the California State Science Standards.
• Other California State standards -based activities relevant to estuaries & watersheds, such
as Project WILD, GEMS, Our Ocean/Our World.
• DF &G's monthly Marine Life Inventories (all grades)
• Restoration activities (all grades)
• Research and study of eel grass (zosfera marina), to be grown on -site (all grades)
• Other water quality monitoring & testing of the Upper Bay & indoor aquaria (all grades)
• Learning about the flora & fauna that inhabit the Upper Bay.
Here is a diagram of the current plans for the Teaching Lab's interior:
BBSC Teaching Lab Sketch
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TEACHING LAB REQUEST:
See Table 2 on Page 5. The total amount needed is about $531,000. We do not expect any
one entity to fund the entire amount. We believe that commitments from a number of sources
will be necessary to accomplish the tenant improvements and FF &E for the Teaching Lab.
CONTACT INFORMATION:
Dave Kiff, Assistant City Manager
City of Newport Beach
(949) 644 -3002
dkiffOcity.newoort- beach.ca us
Robin Madrid, Education Program Coordinator
California Department of Fish & Game
949 - 640 -9956
rmadrld0dfg.ca.gov
6 (0
Back Bay Science Center
Funding Proposal
Page 7
Table 7
BBSC Overall Project Funding (for Construction)
California Dept. of Fish & Game (WRCP)
Fdig
Wildlife Conservation and Restoration Act Grant (BBSC Planning /Design)
$
369,600
Wildlife Conservation and Restoration Act Grant (BBSC Construction)
$
615,400
Aquatic Life Support System (pledged, pending)
$
50,000
Administration Wing
$
900,000
American Trader Oil Spill Funds (early planning)
$
112,000
Subtotal, Fish and Game
$
2,047,000
26.1%
City of Newport Beach
American Trader Oil Spill Funds (visitor - related, marine- related projects only)
$
500,000
6.4%
Newport Bay Restoration Fund (Newport Bay environmental projects only)
$
311,000
4.0%
Feb 2006 GF Contribution
$
1,661,164
21.2%
Jan 07 GF Osprey Contribution (pending)
$
34,438
0.4%
Subtotal, City of Newport Beach
$
2,506,602
32.0%
Wildlife Conservation Board (CA Wildlife Foundation - Demonstration Marsh)
$
69,000
0.9%
Co. of Orange, Health Care Agency (Water Quality Lab Wing + Change Orders)
Water Quality Lab Wing
$
1,230,000
15.7%
Change Orders
$
124,775
1.6%
Osprey Contribution (pending)
$
34,438
0.4%
NBNF Donor (for wet tables - interior of Teaching Lab)
$
25,000
0.3%
University of California, Irvine (Site Improvements, esp parldng lot)
$
308,000
3.9%
The Irvine Company (site and traithead improvements)
$
600,000
76%
State Coastal Conservancy (for exteriodoonsevction of Teaching Lab)
$
400,000
5.1%
MiOcean & Pacific Life Foundation
$
500,000
6.4%
Subtotal, Other Funders
$
3,291,213
42.0%
Total Funding, ARSources
$
7,844,815
100.0%
Back Bay Science Center
Funding Proposal
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Table 2
Teaching Lab Request
Estimated Budget (DRAFT) - March 13, 2008
Qty
Dimension or
PdcelEach
Total
Type
Type
Furniture, Fixtures
Wet Table System (west wall)
1
S 25,000
$ 25,000
Aquaria Life Support System
1
S 150,000
$ 150.000
Chairs ( "A" Side)
50
300 Series
S 60
S 3,000
Tables ( "A' Side)
17
24' x 54"
$ 450
$ 7,650
Plumbed Counters ( "B" Side)
2
S 30,000
$ 60,000
Moveable Counter ( "B" Side)
1
$ 30,000
S 30.000
Chairs ( "B" Side)
36
LBLN1
S 200
S 7,200
Magnetic white boards
2
16'x 4'
$ 600
S 1,200
Smart board
1
$ 3,500
$ 3,500
Deionizer (and prep room faucet)
1
$ 1,500
$ 1,500
Fume hood (south prep room)
1
$ 1,500
S 1.500
Shelving (both sides)
$ 5,000
S 5,000
Subtotal FF
$ 295,550
Equipment
Projection screen
2
84" x 84'
S 200
$ 400
Projectors (hanging)
2
$ 600
$ 1,200
Lab Equipment
- Glassware /Nalgene at each lab station
18
sets
$ 175
$ 3,150
- non - glassware supplies at each lab station
18
sets
$ 275
$ 4,950
- Microscopes (compound)
18
compound
$ 1,000
$ 16,000
- Microscopes (stereo)
18
stereo
$ 900
$ 16,200
- microscope slides (plain and prepared)
1
set
$ 1,500
$ 1,500
- microscope slide cabinet
1
$ 1,200
$ 1,200
- DNA electrophoresis/PCR
1
set
$ 30.000
$ 30,000
- electronic balances
6
$ '400
$ 2,400
- goggle sterilizer
1
$ 450
S 450
- autoclave
1
$ 2,500
$ 2,500
- incubator
1
$ 500
$ 500
- goggles/aprons/gloves
40
$ 50
$ 2.000
- Misc.safety items (fire blankettextinguisher)
1
set
$ 500
$ 500
- spectrophotometer
3
$ 1,500
$ 4,500
- prep room materials
1
$ 4,500
$ 4,500
- carts
2
$ 400
$ 800
- water quality test kits
12
kits
$ 300
$ 3,600
- Ecology equipment
1
set
$ 9,000
$ 9,000
- Marine Biology equipment
1
set
$ 15,000
$ 15,000
- wireless laptops
18
$ 1.000
$ 18,000
-- Vernier computer probeware (pH. temp. etc)
1
set
S 15,000
$ 15,000
Subtotal Equipment
$ 155.350
Labor
-- Floor Cutting
1
3 cuts
s 50,000
$ 50,000
-- Other Installations
1
varies
S 30,000
S 30,000
Subtotal Labor
$ 80,000
Total
S 530,900
a g
Back Bay Science Center
Funding Proposal
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Attachment 1
Thirty (30) Field and Lab Activities at the BBSC (Draft)
Water chemistry: Measurement of dissolved oxygen content, salinity levels, water
temperatures, and water clarity (Secchi disk), etc. (FIELD WORK and LAB): Some of this
activity is done in the field and involves the use of a Secchi disk to discern water clarity,
measurement of water temperature, salinity level, and water color. Water samples are collected
and brought into the laboratory for analysis of dissolved oxygen, dissolved carbon dioxide, and
dissolved nitrate levels. Specific locations, date, tidal level, amount of time since the last significant
rain, etc. could allow for comparisons to be made. An obvious advantage to having a laboratory
nearby is that water samples can be analyzed quickly after collection. Discussion: How do the
results compare at various times of the year and associated with flood situations?
2. Crime scene investigation (FIELD WORK and LAB): A staged and completely violence-free
crime scene will be provided (it could be something like the illegal catching of "undersize" fish).
Several suspects would be identified and evidence to which they are tied would be noted.
Evidence will include clothing samples and simulated blood. Students will use the "evidence"
(collected around the bay) in get electrophoresis techniques to compare the banding pattern of
DNA fragments. PCR (Polymerase Chain Reaction) techniques could be used in this lab, with a
thermocycler. Discussion: What is the effect of poaching on the food chain? How is DNA
technology used in scientific investigations?
3. Net Productivity: Fertilizers, eutrophication (LAB): Using a water quality test kit, students
measure the dissolved oxygen (DO) in various areas of the estuary. Variables which can be
measured, include: The effect of: changes of tides, depth of water, salinity, pH, and temperature
on DO. Discussion: What is the relationship between dissolved oxygen and photosynthesis? How
does photosynthesis and cell respiration relate to net productivity in the estuary?
4. Plankton identification and assessment of relative abundance (some FIELD, mostly LAB):
Done at various times of the year for comparisons. Also could compare samples from different
location. An efficient way to collect a large amount of plankton is by towing a plankton net from a
boat. Notations should include date, water temperature, specific location of the tow, and length of
time since the last significant rain. In the laboratory, samples are placed on slides and viewed with
microscopes. Illustrations are provided to assist in identification. Students could make their own
scientific drawings. One assignment could be to sketch the species that appears the most
abundant, second most abundant, etc. observations regarding the activities of the living organisms
could be recorded. Discussion: A compellation of the observed data could be done. Such data
should become part of a permanent database.
5. What grows on Docks and Pilings — #1 (FIELD and LAB): Thirty days before bringing a class
to the bay, the teacher anchors a rope, which has been tied to a floating dock. During that month,
many organisms will attach to the rope. On the day of the class visit, the rope and anchor is put
into a large container with water and brought into the laboratory where it is laid out in a long series
of porcelain trays containing salt water. Students are assigned to measured sections of the rope
and asked to remove the organisms, which are counted, identified, and weighed. Discussion: The
data collected are related to rope depth, date, water temperature, and location in the bay.
Calculations can be made as to percent abundance of each organism.
6. What grows on Docks or Pilings -- #2 (FIELD and LAB): Students are taken to a floating dock
which has not been cleaned of its underwater life for some period of time. Using putty knives, the
teacher (or students) removes sufficient organisms for the size of the group and puts them into a
large container along with bay water. All are then brought into the laboratory for analysis. Each
participant or participant group takes a sample and separates the organisms by species. They are
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Back Bay Science Center
Funding Proposal
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then identified and weighed. After all data are collected, the results for the entire class are totaled.
Discussion: How is it possible to determine each species percent abundance by weight?
7. Intertidal invertebrate animals: Animal behavior/feeding adaptations, shoreline zonation,
ecological niches, species competition (FIELD and LAB): Students will examine culture
dishes, which contain various species of marine animals such as a sea star, brittle star, sea
anemone, octopus, fish and others. Stereomicroscopes will be used to view the anatomical
structures of the animals. Various feeding techniques can be observed and discussed. Discussion
topics: How does a sea star open a mussel shell? How do sea anemone get their food? What is
the behavioral relationship between a black turban snail and a sea star?
8. Sea urchin fertilization and development (LAB): Students will use microscopes to observe
gametes released from sea urchins. Student observations will include fertilization of egg cells and
early stages of cell division and embryo development. Students will be able to make observations
and compare these stages of development to photographs illustrating sea urchin development. A
video microscope will be used for demonstration purposes. Discussion: How long does it take a
zygote to start to divide? What factors affect cell division? What is totipotency? Which of these
cells are totipotent? How many embryos will usually survive in nature? What if they all survived?
How does water quality affect the survival rates of newly developing organisms?
9. Bird behavior, Including: Flock behavior of shore birds (FIELD and LAB): In the field, birds
can be observed and identified. Methods of swimming, walking, flying, and feeding can be
considered. In the laboratory, a specimen collection would allow students to relate these activities
to the type of beak, feet, and wings possessed by various birds. In addition, a series of illustrations
of beaks and feet would assist in the analysis. This could be done at the home campus, but,
presumably, the BBSC will accumulate a collection of specimens that will be of greater variety than
found at most schools. Discussion: Species interaction. Methods of catching fish: Which species
use what method?
10. Sediment analysis: Comparisons of soils collected at various locations in the lands that
drain into the bay, as well as samples of dredged materials that were placed on lands
around the bay (i.e., North Star Beach and the southerly portion of Big Canyon near the
bluff) (LAB): Samples are collected from various locations within the Upper Bay itself. This is
similar to 'Beach in a Bottle" except that any laboratory work requiring dry samples cannot be
done. All work would be wet analysis and might include a study of settling time (whatever settles to
the bottom of a graduated cylinder in 40 seconds is sand, and whatever settles after one hour is
silt). Discussion: What is the percolation rate (how much water goes through a measured sample
in 45 minutes), and soil texture (done by feeling a mud sample and using descriptions of several
soil types) analysis?
11. Sea shells of North Star Beach (or Shellmaker Island) (FIELD then LAB): North Star Beach,
as well as Shellmaker Island, is composed of materials dredged from the channels of Upper Bay.
Students collect whole shells (actually half shells if they are clams) for half an hour, attempting to
find as great a variety as possible. The contest is to see who can find the most kinds. An additional
contest includes an "award" for the smallest complete shell. The shells are brought back to the
BBSC and each student displays his/her collection. The teacher checks each display, helping to be
certain the shells are separated correctly by species and counts the total number of kinds. After
"winners' are determined, shells can then be identified using a master collection, which is labeled
with common names. Discussion: How is diversity related to habitat? Is there a correlation
between the number of dead shells and shell structure?
12. Sampling Life in the Mud #1 (FIELD and LAB): What types of organisms live in the sediment at
the estuary? Students use the mud grab technique to obtain the mud samples. With the use of
microscopes, students identify species of animals, plants and algae. Discussion: Which larvae
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Back Bay Science Center
Funding Proposal
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develop here in the UNB estuary? How does the estuary provide a "nursery" environment for
developing organisms? Other topics for discussion include the food chain, the food web, and the
impact of water quality.
13. Sampling Life in the mud #2 (FIELD and LAB): Mud samples are collected after noting where
the samples are collected and their relationship to the tide, should they be intertidal. If a Petersen
Grab is available, samples can be taken from subtidal locations, in which case the depth should be
recorded. The mud is placed in a sieve -series (largest mesh on top, smallest at the bottom) and
washed with salt water to separate organisms from the mud. The collected organisms are
identified with microscopes in the laboratory and counted in order to determine relative abundance.
Discussion: How can the number and diversity of organisms be related to location, time of year,
water temperature, salinity, etc.?
14. Salt water plants (Halophytes): Evolution of salt tolerant plants (LAB): How is it possible for
plants to live in a high salt environment? Examine salt tolerant plants under the microscope.
Special features will be noted. Discussion: Special adaptations enable these plants to live in salt
water. Ask students to discuss how and why plants have developed these characteristics. What is
the relevance of the existence of these plants in the estuary? Discuss the food chain and the
importance of water quality for the success of plants species in the estuary.
15. Water potential: Amount of solutes in estuary plants (LAB): What is the solute (salt) content
of the cells of estuary plants? Students will use dialysis tubing to measure percent gain /loss of
water. This lab activity could include the calculation of water potential in the cells of halophytes.
Discussion: What would happen to these plants if the salinity changed in the bay? Demonstration:
The use of raw eggs, without shells, in various molarities of solutes can simulate the effect of
changes in salinity on cells.
16. Nutrient Cycling: A number of nutrients and minerals could be analyzed (LAB): Water will be
collected from a variety of locations in the bay. Students will measure nutrients and ions found in
the UNB. Water quality test kits will be used to measure phosphates, nitrates, ammonia etc. What
is the source of nutrients in the bay? How do nutrients cycle? (C, N2) What causes eutrophication?
Data from water quality experiments can be recorded for future comparison. Discussion: What is
the relationship between WQ and the cycling of nutrients in the bay?
17. Cell sizes in estuary organisms (LAB): Students will observe cells from various organisms in
the estuary. Using a microscope, they will measure the sizes of various cell types. Students will
compare prokaryote, protists, plants, animal, and fungi cell sizes. Structure and function of cells
can be demonstrated. Phytoplankton and Zooplankton can be observed, measured, and counted.
Data will be recorded for future comparisons. Discussion: How is measurement accuracy
important in data collection for the estuary?
18. Photosynthesis in estuary plants: The basis for the food webs (LAB): Students will measure
the rate of photosynthesis in estuary plants. Several methods can be used to perform this activity.
A spectrometer can be used with a reducing dye or the use of buoyancy techniques in leaf discs.
Photosynthesis rates can be compared in various plant types such as halophytes and riparian
plants. The photosynthetic rates could be compared between plants in the estuary and algae,
which are not plants. Discussion: Photosynthesis is the basis for the energy pyramid. Discuss
the importance of plant and algae species in the estuary. How does water quality affect the energy
pyramid?
19. Cellular respiration using germinating seeds or marine isopods (LAB): Does cellular
respiration occur in the UNB estuary? Using organisms found in the estuary, and a respirometer,
students will measure respiration rate. How does cellular respiration affect water quality and
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Back Bay Science Center
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dissolved oxygen levels in the bay? Discussion: What is the relationship between photosynthesis,
cellular respiration, and the dissolved 02 content in the bay?
20. Food chemistry: Testing for carbohydrates, lipids, and proteins in bay foods (LAB): How
much energy is stored in seeds? Using a calorimeter, measure the energy that birds can acquire
from eating seeds. Discuss the importance of certain plants as food sources for the birds and
other wildlife. The content of various plants can be tested for type of starches, sugars, lipids, etc.
Discussion: How are plants important in the food web? Why should native plants be protected
and replanted where invasive species have grown?
21. Water Quality #1 (LAB): Students will use bacteria testing techniques used at OC HCA (Orange
County Health Care Agency) or basic Gram staining techniques to identify bacteria found in the
water of the bay. Vacuum lines will be used to filter bacteria from the water. Bacteria will be
identified and counted (requires gas jets— sterile techniques) Discussion: How can we identify
bacteria in the estuary? How does the presence of various species of bacteria affect the quality of
water in the estuary?
22. Water Quality #2 — Fecal Indicator Bacteria (LAB); What kinds of fecal bacteria reach the Bay,
and from what likely sources? In concert with the OC HCA lab, students will perform the same
sampling protocols done by OC HCA for statewide water quality testing and see the results a day
later. Why are "indicator bacteria" tested instead of human pathogens (viruses at al)? What are the
likely sources of bacteria (bird life, human activity, suspensions in sediment, urban runoff sources,
illegal discharges of boat toilets, regrowth)? Discussion: What are the merits to the current WQ
testing protocols, given that "we're swimming in yesterday's results ?"
23. Transpiration: #1 Relating water loss in plants to habitat (FIELD and LAB): Transpiration rate
can be measured with a potometer. Transpiration rates of salt water, brackish water, fresh water,
riparian, and terrestrial plants can be compared. Discussion: How can plants tolerate various
environments? Plant adaptation, and C3, C4 and CAM (Crassulacean Acid Metabolism)
photosynthesis can be discussed. The loss of water by transpiration varies in these plants.
24. Transpiration: #2 (FIELD and LAB): Data can be collected comparing salt marsh plants,
freshwater marsh plants, and various upland plants. Small plastic bags are placed tightly over the
leaves of the chosen plants and left for a period of time (i.e., an hour). The bags are then carefully
removed along with the portion of the plant inside, sealed to prevent moisture loss, and brought
into the laboratory. The seals are removed, then the leaves are carefully removed while attempting
to leave as much of their moisture as possible inside the bags, which are then weighed, as in an
unused empty bag. The leaf surfaces are outlined in actual size on graph paper so that total
surface size can be determined. Calculations can be done at the home campus, if desired.
Discussion: How can the amount of water transpired per square centimeter of leaf surface be
calculated? How can transpiration rate be compared to a plant's habitat?
25. Enzyme activity: How do enzymes aid in reactions in the estuary? (LAB): Enzymes can be
used to show how they affect reaction rates. Changes of pH and temperature can change the
effectiveness of an enzyme. Discussion: Why is water quality important? How does the impact of
water quality affect the chemical balance of reactions in the estuary?
26. Animal classification: Use of dichotomous keys to identify organisms (LAB): Students will
study the diversity of organisms. Students will learn how to use a classification key to identify
marine animals (or birds). Discussion: What is the relationship between the food web and the
diversity of organisms found in nature?
27. Beach in a Bottle #1 — Sand Study (FIELD and LAB): Collect sands from different areas of the
bay and beaches. Put them into test tubes. Using a microscope, magnet, HCl (hydrochloric acid),
and basic hardness kit, identify the minerals in these sands. What is the origin of the sands?
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Back Bay Science Center
Funding Proposal
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Which rocks have eroded to produce these sands? Where are these rocks located now? How did
the sediment get into the bay? What is the importance of erosion, dredging and the need to
prevent sedimentation of the bay? What if no dredging occurs? Discussion: What is the
relationship of erosion to succession, and its impact on the loss of habitat?
28. Beach in a Bottle #2 (FIELD and LAB): Soil samples can be collected in advance from locations
within the drainage into Upper Newport Bay. Locations could include the sands on North Star
Beach, the dredging stockpile in Big Canyon, a site in the San Joaquin Hills, and an agricultural
area inland of the bay (i.e. southern Irvine or Lake Forest). Using a series of sieves with a variation
in mesh sizes from about 5 /inch to 270 /inch and including a pan for the bottom, samples of dry
sand /soil collected from various locations around the bay and /or in locations that drain into the bay
are compared based on location and location history (i.e.,sand from North Star Beach was placed
there in 1955 and was formerly on the bottom of the nearby channel). A series of questions can
help students understand the particular soil composition of the chosen locations. The sand /soil can
be analyzed in a variety of ways. Discussion: Should the students be involved in collecting the
original samples, they have an opportunity through analysis at the BBSC in quickly relating to the
environment for each sample (samples must be completely dry).
29. Endangered species: Quadrat sampling /plot counts, estimating species abundance (FIELD
and LAB): With approval from the Department of Fish and Game (DF &G), mark quadrats around
the bay. Count and calculate the number of species living in the estuary. Discussion topics: What
is the relationship between the current number of endangered species, and the number of invasive
species? Have the numbers of endangered species changed over the last 10 years?
30. Plant anatomy: Plant structure and relationship to habitat; plant classification (FIELD and
LAB): Students will study various plant species in the estuary. Investigations will include basic
plant anatomy, plant identification, and their role in the ecosystem. Students will use dried,
pressed, and laminated plants for plant classification. Discussion: What is the Impact of invasive
plants, their competition for resources and the resulting loss of habitat? What is the overall
importance of plants?
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