Oceanography
THE OFFICIAL MAGAZINE OF THE OCEANOGRAPHY SOCIETY
VOL.30, NO.3, SEPTEMBER 2017
Special Issue on
Sedimentary Processes Building a
Tropical Delta Yesterday, Today, and Tomorrow:
The Mekong System
THE OFFICIAL MAGAZINE OF THE OCEANOGRAPHY SOCIETY
VOL.30, NO.3, SEPTEMBER 2017
THE OFFICIAL MAGAZINE OF THE OCEANOGRAPHY SOCIETY
VOL.30, NO.3, SEPTEMBER 2017
22
34
72
contents
VOL. 30, NO. 3, SEPTEMBER 2017
84
10
FROM THE GUEST EDITORS. Introduction to the Special Issue on
Sedimentary Processes Building a Tropical Delta Yesterday, Today, and
Tomorrow: The Mekong System
By C.A. Nittrouer, J.C. Mullarney, M.A. Allison, and A.S. Ogston
22
How Tidal Processes Impact the Transfer of Sediment from Source to Sink:
Mekong River Collaborative Studies
By A.S. Ogston, M.A. Allison, R.L. McLachlan, D.J. Nowacki, and J.D. Stephens
34
A Question of Scale: How Turbulence Around Aerial Roots Shapes the
Seabed Morphology in Mangrove Forests of the Mekong Delta
By J.C. Mullarney, S.M. Henderson, B.K. Norris, K.R. Bryan, A.T. Fricke,
D.R. Sandwell, and D.P. Culling
48
Buried Alive or Washed Away: The Challenging Life of Mangroves in
the Mekong Delta
By S. Fagherazzi, K.R. Bryan, and W. Nardin
60
The Mekong Continental Shelf: The Primary Sink for Deltaic Sediment
Particles and Their Passengers
By C.A. Nittrouer, D.J. DeMaster, E.F. Eidam, T.T. Nguyen, J.P. Liu, A.S. Ogston,
and P.V. Phung
71
Challenges of Observational Oceanography in the Modern Coastal Ocean
By C.A. Nittrouer
72
Stratigraphic Formation of the Mekong River Delta and Its Recent
Shoreline Changes
By J.P. Liu, D.J. DeMaster, T.T. Nguyen, Y. Saito, V.L. Nguyen, T.K.O. Ta, and X. Li
84
Modeling the Process Response of Coastal and Deltaic Systems to Human
and Global Changes: Focus on the Mekong System
By E. Meselhe, D. Roelvink, C. Wackerman, F. Xing, and V.Q. Thanh
98
Sedimentation and Survival of the Mekong Delta: A Case Study of Decreased
Sediment Supply and Accelerating Rates of Relative Sea Level Rise
By M.A. Allison, C.A. Nittrouer, A.S. Ogston, J.C. Mullarney, and T.T. Nguyen
SPECIAL ISSUE ON
Sedimentary Processes Building a Tropical Delta Yesterday,
Today, and Tomorrow: The Mekong System
Oceanography | September 2017
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SPECIAL ISSUE SPONSORS
Production of this issue of Oceanography was
supported by the Office of Naval Research
through grant N00014-17-1-2888 to the
University of Washington, Seattle.
SPECIAL ISSUE GUEST EDITORS
• CHARLES NITTROUER, University of
Washington
• JULIA MULLARNEY, University of Waikato
• MEAD ALLISON, Tulane University
• ANDREA OGSTON, University of
Washington
ON THE COVER
Landsat image of the Mekong Delta and adjacent
ocean on September 18, 2014, during period of intense
fieldwork described in the special issue section. Shown
are the turbid distributary channels, complex mangrove
shorelines, and surface plumes extending into the East
Sea. Image was processed by MDA Information Systems,
and is oriented so north is up on the page.
REGULAR ISSUE FEATURE
110
Internal Waves Along the Malvinas Current: Evidence of Transcritical
Generation in Satellite Imagery
By J.M. Magalhães and J.C.B. da Silva
DEPARTMENTS
03 QUARTERDECK. The Garden of Science
By E.S. Kappel
05 FROM THE PRESIDENT. Planning the Future of Ocean Sciences
By A.C. Mix
06 RIPPLE MARKS. The Jumbo Carbon Footprint of a Surf-and-Turf Dinner
By C.L. Dybas
120 HANDS-ON OCEANOGRAPHY. Assessing Cross-Shore and Alongshore
Variation in Beach Morphology Due to Wave Climate: Storms to Decades
By S.L. Gallop, M.D. Harley, R.W. Brander, J.A. Simmons, K.D. Splinter,
and I.L. Turner
126 THE OCEANOGRAPHY CLASSROOM. Inspiration: The Source and the Drive
By S. Boxall
128 BOOK REVIEW: The Oceanographer’s Companion: Essential Nautical Skills
for Seagoing Scientists and Engineers by G.A. Maul
Reviewed by C.L. Van Dover
129 CAREER PROFILES. Sara Bender, Program Officer, Gordon and Betty Moore
Foundation • Danny Richter, Legislative Director and Director of Research,
Citizens’ Climate Lobby
132 AWARDS. The 2017 Walter Munk Award: Andone C. Lavery
06
110
Oceanography | Vol.30, No.3
QUARTERDECK
The Garden of Science
It’s summertime, and I’ve been thinking a lot about gardens. Nearly
30 years ago, when my husband and I bought our home, the small
back yard was a strange mixture of a grass lawn, a day lily patch that
bloomed for one glorious week per year, azaleas, oak trees—some
healthy, some nearly dead—and crumbling terraces for smaller plants.
During the next phase of life, the dead trees came down, the lily patch
was replaced by a swing set, and the highest spot on the lawn became
my son’s pitching mound. Today, there’s no lawn at all, trees that were
planted when my children were young stretch far into the sky, and a
winding path runs through what is now a shade garden. Nothing stays
the same for very long. The acidic contributions of three large dogs cre-
ate additional challenges to keeping the garden lush. If the past is any
indication of the future, the new young raspberry bush I just planted in
the male dog’s favorite spot doesn’t have a chance. But, I remain hope-
ful, and will do my best to see that it survives whatever may come.
Reading the newspaper each morning can make it difficult to be
optimistic about the current direction of US science. Day after day, we
read about possible significant budget cuts to science agencies, while
at the same time learning about the enormous chunk of Antarctica’s
Larsen C ice shelf that just broke free, the mass bleaching of corals,
and the many wildfires that are burning vast acreage in the western
United States and elsewhere around the globe. Confronted with these
disheartening developments, it may be helpful to think about the
US scientific enterprise as a garden that thrives with the proper amounts
of sun and rain, and at other times suffers from drought or neglect.
The scientific landscape has changed many times over the years with
shifting personnel, policies, and priorities. It’s not new for Congress to
cut science budgets, nor for an Administration to challenge scientific
research. It’s not new for politically appointed agency heads to recon-
sider science-based regulations. It’s not new for an Administration
to weigh (or ignore) science based on economic or political inter-
ests. In times like these, it is more import-
ant than ever that we not neglect the scien-
tific garden, that we continue to nurture
it as best as possible, so that when the
time is right, it will come into full
bloom once again.
Ellen S. Kappel, Editor
December 2017
Celebrating 30 Years of Ocean Science
and Technology at the Monterey Bay
Aquarium Research Institute
March 2018
Ocean Observatories Initiative
June 2018
Ocean Warming
September 2018
Mathematical Aspects of Physical
Oceanography
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hands-on laboratory exercises, career
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Cheryl Lyn Dybas
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Oceanography
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Oceanography | Vol.30, No.3
In my previous column (June 2017) I
wrote about the history of ocean sciences
funding, focusing on the Ocean Sciences
Division at the US National Science
Foundation (NSF) as an example. It notes
long-term budget erosion, and suggests
that if we are going to reverse this trend,
we need to create a viable implementa-
tion plan that demonstrates the real value
of oceanography.
I firmly believe that ocean science and
technology are more important than ever.
We need to address ocean issues that
have worldwide consequence, including
the ocean’s role in climate change, sus-
tainability of environments and ecosys-
tems under human impacts, appropri-
ate long-term use of resources from the
sea, technology development and eco-
nomic opportunities related to the ocean,
the scientific basis for global security,
and other ocean-related issues that tran-
scend specific fields, agencies, or national
boundaries. It is time to put some ideas
on the table. It is time to make a plan.
So what should we do? First, we need
to start talking. I envision this conver-
sation as an expanded collaboration
between the United States and non-US
communities; there are ocean sciences
research assets in many countries. Just
as the high-energy physics community
leverages infrastructure among nations,
ocean sciences could, too (e.g., sharing
expensive assets like ships).
To be sure, ocean scientists have
worked across national boundaries for
decades—in this regard, scientists are
mostly apolitical and go where the inter-
esting problems lead them. We have
some good examples of large shared
efforts. These are mostly parallel fund-
ing efforts with trans-national coordina-
tion (e.g., Joint Global Ocean Flux Study,
World Ocean Circulation Experiment),
but there are some that have comingled
funds and co-supported facilities and
science implementation (International
Ocean Discovery Program). Nevertheless,
for the most part, national funds pay for
national programs, and these programs
are sometimes at least partially redun-
dant in various countries. Some redun-
dancy can be a good thing—replication of
results confirms significance of findings.
But we might think about how much
duplication of effort is really needed.
An implementation planning pro-
cess could encourage community build-
ing; support the development of early
career scientists; enhance interdisciplin-
ary, interagency, and international col-
laborations; and provide vehicles for con-
nections between government, academic,
and private-sector ocean sciences. We
need diversity of thought as we plan, and
this requires diversity of people; scien-
tists and stakeholders of all kinds in both
developed and developing nations must
be involved. An inclusive process will
increase access and effectiveness of ocean
science and technology on a global scale.
We already have a start at planning,
at least at the strategic level. For exam-
ple, the US National Research Council’s
Sea Change: 2015–2025 Decadal Survey
of Ocean Sciences (NRC, 2015) was com-
missioned by NSF in 2013 to review the
changing nature of ocean sciences and its
funding structures and to propose prom-
ising themes worth addressing in the
coming decade. Other nations have pub-
lished similar framework documents,
for example, in the UK, Scanning the
Horizon (Kennedy and Liss, 2013), and in
Europe, Eurocean 2020 (McDonough and
Calewaert, 2010). In order to implement
community goals, we must engage the
whole of the ocean science community
in an open, inclusive, bottom-up process.
My hope is that the global ocean sci-
ences community will not retreat in the
face of political and budget pressure
but instead will join together to craft a
synthesis of current knowledge and to
shape a productive future agenda with a
specific action plan. I hope we can encour-
age transdisciplinary innovation, with an
eye toward incorporating rapidly evolv-
ing technologies into rigorous scientific
frameworks. We need concrete mecha-
nisms for retaining early career scientists
and empowering them to envision the
future of the field. Universities can step
up to some extent in this area, acknowl-
edging the difficulty of starting careers on
“soft” (grant-funded) money. With a goal
of helping to encourage young scientists,
The Oceanography Society is putting its
policies where its mouth is, and now pro-
vides free membership to students and
reduced-cost membership to early career
scientists within three years of receiving
their PhD degrees.
Accomplishing bottom-up planning
demands time commitment. It requires
volunteers to step up and funding agen-
cies to cover costs. TOS is willing to part-
ner in facilitating a planning process—
as a first step, perhaps we can engage in
spirited discussion at this year’s upcom-
ing professional meetings worldwide.
Let’s get started!
REFERENCES
Kennedy, H., and P. Liss. 2013. Scanning the
Horizon: The Future Role of Research Ships and
Autonomous Measurement Systems in Marine and
Earth Sciences. The Challenger Society for Marine
Science and the National Oceanography Centre
(NOC) Association, UK, 31 pp, http://noc.ac.uk/files/
documents/about/2013_Scanning the Horizon.pdf.
McDonough, N., and J.-B. Calewaert, eds. 2010.
EurOcean 2010: Grand Challenges for Marine
Research in the Next Decade. Conference
Report and Ostend Declaration. Thermae
Palace, Oostende, Belgium, October 12–13,
2010. Belgian Science Policy Office (BELSPO),
Brussels. VLIZ Special Publication 49 Flanders
Marine Institute (VLIZ), Oostende, Belgium, 57 pp,
http://www.belspo.be/ belspo/northsea/publ/
EurOCEAN2010_report_declaration.pdf.
NRC (National Research Council). 2015. Sea Change:
2015–2025 Decadal Survey of Ocean Sciences.
The National Academies Press, Washington, DC,
98 pp., https://doi.org/10.17226/21655.
Planning the Future of Ocean Sciences
Alan C. Mix, TOS President
FROM THE PRESIDENT
Oceanography | September 2017
By Cheryl Lyn Dybas
The Jumbo
Carbon Footprint of a
Surf-and-Turf Dinner
RIPPLE MARKS: THE STORY BEHIND THE STORY
What’s the carbon footprint of an average
shrimp-and-steak dinner?
If it comes from the conversion of man-
grove forests to aquaculture and agri-
culture, it’s 1,795 pounds of carbon diox-
ide. That’s about the same amount of
greenhouse gases produced by driving
a fuel-efficient car from Los Angeles to
New York City.
Clearcutting of tropical mangrove for-
ests to create shrimp ponds and cat-
tle pastures contributes significantly to
greenhouse gases and global warming,
according to findings reported in the May
2017 issue of Frontiers in Ecology and
the Environment.
“The results mean that 1,603 pounds
of carbon dioxide are released for every
pound of shrimp, and 1,440 pounds of
carbon dioxide for each pound of beef”
from mangrove forest conversion, says
J. Boone Kauffman, an ecologist at Oregon
State University who led the project.
NEW MEASUREMENT: THE LAND-USE
CARBON FOOTPRINT
Those numbers were obtained with a
new measurement called the land-use
carbon footprint. It records the amount of
carbon stored in an intact mangrove for-
est, the greenhouse gas emissions from
conversion of that forest to aquaculture
or agriculture, and the quantity of the
shrimp or beef produced over the life of
the land’s use.
“What we found was astounding,”
Kauffman says. “When you convert man-
grove forests to shrimp ponds or cattle
pastures, a remarkable amount of car-
bon is being emitted into the atmosphere.
And the food productivity of these sites
is not very high.”
Scientists have the difficult task of clearly
conveying the ecological consequences
of forest and wetland losses to the pub-
lic, state Kauffman and coauthors in their
Oceanography | Vol.30, No.3
Frontiers in Ecology and the Environment
paper. “To address this challenge, we
scaled the atmospheric carbon emissions
from mangrove deforestation down to the
level of an individual consumer.”
The study was conducted on 30 rela-
tively undisturbed mangrove forests and
21 adjacent shrimp ponds or cattle pas-
tures. The sites were in Costa Rica, the
Dominican Republic, Honduras, Indonesia,
and Mexico. Shrimp ponds were sampled
in all countries except Mexico, where the
predominant land use was conversion to
cattle pastures.
On the basis of measurements from
these locations, “we determined that
mangrove conversion results in GHG
[greenhouse
gas]
emissions
ranging
between 1,067 and 3,003 megagrams of
carbon dioxide equivalent per hectare,”
says Kauffman.
The decline in carbon storage from man-
grove conversion to shrimp ponds or cat-
tle pastures exceeded the researchers’
original estimates.
Mangroves represent less than 1% of
the world’s tropical forests, scientists have
found, but their degradation accounts
for as much as 12% of the greenhouse
gas emissions that come from tropical
deforestation.
INSIDE A MANGROVE FOREST
Enter a mangrove forest. In this dark
water world, trees with twisted limbs live
double lives—one foot on land, the other
in the sea.
Some
80
species
of
mangroves,
also called mangals, thrive in saline
coastal habitats in the tropics and sub-
tropics. All take root in waterlogged
soils where slow-moving currents allow
sediment to accumulate.
Red, black, and white mangrove trees,
along with buttonwoods, may grow along
the same shoreline. Where these species
are found together, each stakes out a spot.
Red mangroves are closest to the sea’s
edge; their prop roots extend into the
water from branches above. The roots
capture sediment, stabilizing the shore.
Farther inland are black mangroves with
pneumatophores pointing upward from
the soil. Pneumatophores supply oxygen
in otherwise anaerobic sediments.
White mangroves, with no special root
adaptations, are found in the interior man-
grove forest, followed by buttonwoods in
the upland transition area.
These forests-of-the-tide collectively
cover a worldwide area of 53,190 km2
in 118 nations—about 0.6% of all tropical
forests. And that number is dropping.
Rates of mangrove deforestation over
the past three decades have been dra-
matic, says Kauffman. “Mangroves are
disappearing at the rate of about 1% per
year.” In places such as Southeast Asia,
mangrove conversion to shrimp ponds
is the greatest cause of these intertidal
forests’ decline.
MANGROVES: TOP ECOSYSTEM
SERVICES PROVIDERS
Mangroves provide ecosystem services
worth up to $57,000 USD per hectare
per year and collectively sustain more
than 100 million people, according to the
United Nations Environment Programme
report The Importance of Mangroves:
A Call to Action.
The report estimates that deforestation
of the world’s mangroves results in annual
economic damages of up to $42 billion.
From top to bottom: (1) Denuded mangrove forest in Madagascar. (2) Shrimp harvested from
an Indonesian shrimp farm. (3) Shrimp pond in Brazil. Courtesy of J. Boone Kauffman, Oregon
State University
Oceanography | September 2017
Oceanography | September 2017
Mangroves’ most important ecosystem
service, scientists say, may be mitigating
climate change by removing greenhouse
gases from the atmosphere. Like other
plants, mangroves capture carbon diox-
ide and store it in their leaves, roots, and
trunks (biomass) and in the soil. But unlike
most other forests, mangroves do not
have a maximum storage capacity. They
continuously amass carbon in soil, where
it can remain for millennia.
Mangroves are extremely productive
ecosystems that can increase their bio-
mass relatively quickly, trapping more car-
bon than other forest types. The upper
meters of mangrove soils are primarily
anaerobic—missing the organisms that
decompose organic material and release
carbon into the environment.
How much “blue carbon”—carbon cap-
tured by the world’s coastal and ocean eco-
systems—is stored in mangrove forests?
Researchers mapped mangroves and
identified which ones contain the most
blue carbon: mangals in Sumatra, Borneo,
and New Guinea, and along the coasts of
Colombia and northern Ecuador.
The findings were published in 2013
in the journal Conservation Letters. The
results can help guide decisions about pri-
ority areas for mangrove conservation and
rehabilitation, scientists say.
When mangrove forests are converted
to agriculture or to aquaculture ponds,
the majority of the carbon in their bio-
mass and underlying soils is released into
the atmosphere, joining other sources of
greenhouse gases. Clearing even small
tracts of mangroves generates high vol-
umes of carbon dioxide.
“These forests have been absorbing
carbon for the last 4,000 or 5,000 years,
but now through deforestation they have
become significant sources of green-
house gas emissions,” Kauffman says.
“Because they store so much carbon,
they’re important sites for mitigating or
slowing climate change.”
HOW MUCH IS A MANGROVE
FOREST WORTH?
An important question, say Kauffman and
coauthors, is whether the value of the
shrimp or beef produced from a former
mangrove forest exceeds the value of the
ecosystem services lost as a result of man-
grove conversion. Those ecosystem ser-
vices include maintaining high biodiversity,
fisheries production, protection against
storms and erosion, and carbon storage.
“Addressing this trade-off is the respon-
sibility of governments and is the personal
choice of the consumer, who should have
access to information on the true costs
and impacts of food production,” the
researchers write.
“A better understanding of land-use
carbon footprints would provide context
to make informed decisions about how
our everyday lives affect land use and
climate change.”
And whether that surf-and-turf dinner is
worth the price—in mangrove currency.
Cheryl Lyn Dybas (cheryl.lyn.dybas@gmail.com), a Fellow of the International League of
Conservation Writers, is a contributing writer for Oceanography and a marine ecologist by training.
She also writes about science and the environment for National Geographic, BioScience, Ocean
Geographic, Canadian Geographic, National Wildlife, Yankee, and many other publications.
Background photo: Women in the Sundarbans
mangrove forest, Bangladesh. From top to
bottom on left: (1) Brazilian fisher with a man-
grove forest in the background. (2) Abandoned
fish pond showing mangrove devastation.
(3) Dried-up shrimp pond in Brazil. Courtesy of
J. Boone Kauffman, Oregon State University
Oceanography | Vol.30, No.3
Oceanography | Vol.30, No.3