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 Gregory
W. Stone, Baozhu Liu, and Felix Jose, Winter Storm and Tropical Cyclone
Impacts on the Shortterm Evolution of Beaches And Barriers Along The
Northeastern Gulf of Mexico, ASCE, 2007.
Abstract: Here
we present data indicating the complexity and highly
variable response of barrier islands and beaches to the impacts of tropical
cyclones and winter storms along the northern Gulf of Mexico. Data
indicate that (1) barrier islands can conserve mass during catastrophic
hurricanes; (2) less severe hurricanes and tropical storms can promote
rapid dune aggradation and contribute sediment to the entire barrier
system; (3) cold fronts play a critical role in the post-storm adjustment
of
the barrier by deflating the subaerial portion of the overwash terrace
and
eroding its marginal lobe along the bayside beach through locally
generated, high frequency, steep waves; and (4) barrier systems along
the
northern Gulf do not necessarily enter an immediate post-storm recovery
phase, although nested in sediment-rich nearshore environments. The
fluid mud environment off west Louisiana coast plays a significant role
in damping wave energy associated with tropical cyclones. However, no
significant surge attenuation appears apparent. It is anticipated that
these
findings will have important implications for the longer-term evolution
of
coastal systems in the northern Gulf of Mexico.
Felix
Jose, Daijiro
Kobashi, Gregory W. Stone, Spectral Wave Transformation
over an Elongated Sand Shoal off South-Central
Louisiana, U.S.A.,Journal of Coastal Research, Special Issue 50, 2007.
Abstract: Ship
Shoal is an elongated sand shoal located along the 10 m isobath in south-central
Louisiana adjacent to a
rapidly eroding barrier island complex, Isles Dernieres. High quality
sand resources from this shoal are
considered as a viable source for the long term maintenance of the adjacent
barrier islands. Previous wave
modelling studies suggest that the shoal acts as a submerged barrier
and mitigates storm waves. The present
investigation employs a fully spectral finite element model to estimate
the wave transformation over the shoal during a cold front generated
storm event in April, 2005. MIKE 21, a spectral wave model, was implemented
for
the eastern Ship Shoal area at a high resolution scale, to estimate wave
attenuation over the shoal and to better
understand the directional spectrum when the storm–generated waves
cross the shoal. The fine resolution coastal
model was nested within a regional wave model for the Gulf of Mexico.
NCEP re-analysed wind data were used
as input and the spatial distribution of bottom sediments were also included
in the model to select an appropriate
friction factor. It was found that southerly storm waves could lose as
much as 22% of their offshore wave height
while propagating over the shoal. This level of wave energy reduction
also points to the effectiveness of the
shoal in shielding the already vulnerable coast against the frequent
cold fronts and hurricanes. The model results
were validated with time series data collected from in situ measurements
on the shoal as well as using data from
an observation site CSI 6. The dissipating wave energy over the shoal
helps in resuspension and transport of
shoal material during storm events.
Daijiro
Kobashi, Felix Jose, Gregory W. Stone, Impacts of Fluvial Fine Sediments
and Winter Storms on a Transgressive Shoal,
off South-Central Louisiana, U.S.A., Journal of Coastal Research, Special
Issue 50, 2007.
Abstract: Ship
Shoal, a transgressive sand shoal off South-Central Louisiana and one
of the potential sand resources that
will likely be used to restore rapidly eroding barrier islands in coastal
Louisiana, has a unique, complex sediment
exchange with fluvially introduced sediments during high river discharge
and a high energy wave climate
associated with frequent winter storms. The result of a recent field
survey, undertaken from April 4th to May 25th,
2006 showed that the bottom sediment distribution was strongly affected
by fine-grained sediment outputs from
Atchafalaya River and the prevailing wind and wave conditions, changing
from mud to fine sand for roughly two
months, which was also supported by satellite imagery and river discharge
data. The data from the pulsecoherent
Doppler profiler (PCADP) showed the existence of a fluid mud layer during
the deployment, which was
associated with the interaction of waves and the fluvial sediments. An
observed fluid mud layer of 10-15 cm in
thickness was conspicuously influenced during a storm in late April,
in which a maximum wind speed of 17 m/s
and significant wave height of 2.3 m were recorded. Waves strongly reworked
bottom sediment during the prefrontal
phase, vertical mixing occurred due to strong vertical velocity and finally,
after the storm passed, the resuspended
and the mixed sediments settled out and the fluid mud layer was re-established
during the waning
phase of the storm. The above results show the influence of fluvial fine
sediments and winter storms on Ship
Shoal sediments and its feedback relationship with hydrodynamic processes,
which is likely to affect benthic
habitat of the shoal and future sand mining.
Daijiro
Kobashi, Felix Jose, Gregory W. Stone, Heterogeneity and Dynamics on
a Shoal during Spring-Winter Storm Season, South-Central Louisiana, USA,
ASCE, 2007.
Abstract: Ship
Shoal, a shore-parallel elongate sand shoal and a remnant
of a late Holocene active delta has a unique heterogeneous sedimentary
feature strongly affected by winter storms and fluvial sediment input
from
the Atchafalaya River. The interaction between fluvially derived sediment
and subsequent deposition on the shoal has not been quantified;
implications for hydrodynamic modeling are profound given that the
shoal surface vacillates between sand and fluid mud. Thus, attenuation
effects on waves and currents vary greatly. The results of a field survey
undertaken during spring flood and winter storm periods showed that
during fair weather, river-borne sediments transported to the shoal,
forms
a distinct fluid mud layer. Bottom sediments were re-suspended and
transported by storm-induced waves and prevailing northerly/southerly
trends of currents over the shoal during the period. Data presented here
suggest that the high sediment transport during the storms and the
ephemeral deposition of fine-grained sediments could form transient
sediment distribution on the shoal without leaving any modern
sedimentary records, as reported by recent core surveys.
Walter
S. Guidroz, Gregory W. Stone, Dane Dartez, Sediment Transport Along
The Southwestern Louisiana
Shoreline: Impact From Hurricane Rita, 2005, ASCE, 2007.
Abstract: The
landfall of Hurricane Rita in 2005 significantly altered physical and
morphological characteristics along the southwestern Louisiana
coastline and interior marshes. An excessive storm surge event linked
to Rita resulted in widespread, storm-induced overwash deposits in Cameron
and Vermilion Parishes, Louisiana. These deposits superseded prior deposits
and were aligned parallel to predominant flow patterns associated
with the storm’s counter-clockwise circulation. These responses
became more pronounced farther west and culminating at eyewall impact. Excessive
salinity levels resulting from salt-water intrusion severely impacted
local
vegetation several kilometers inland and over the longer term may
exacerbate the loss of vegetation that retards coastal erosion and attenuates
waves and storm surge during high-energy events. Massive water levels
introduced onshore by surge remained locally ponded several weeks after
the hurricane; however, morphological patterns along the coastline had
begun facilitating the return flow of water and sediment to the Gulf
of
Mexico. Julie
Dean Rosati, Gregory W. Stone, Critical Width of Barrier Islands and
Implications For Engineering Design, ASCE, 2007.
Abstract: The
critical width of a barrier island is defined as the smallest
cross-shore dimension that minimizes net loss of sediment from the island
over periods from decades to centuries. This concept is of importance
for
large-scale restoration of barrier islands which involves rebuilding
these
islands to a specified geometry. Within constraints of coastal forcing
and
geologic and regional characteristics at the site, islands having critical
width
will capture deposition of washover sediment onto the subaerial beach
over
the project lifetime. This study reviews previous investigations of barrier
island critical width and applies a newly-developed model of barrier
island
migration, consolidation, and overwash to assist engineering design.
Gregory
W. Stone, Tropical Cyclone and Winter Storm Impacts
on the Short-Term Evolution of Barriers
along the Northeastern Gulf of Mexico,
GCAGS, 2006.
Abstract: Recent
data suggest that the north-central Gulf of Mexico coast has undergone
an increase in the number of tropical cyclone landfalls over the past
decade. Louisiana
State University and the U.S. Geological Survey have monitored the Florida
panhandle
and Alabama coasts since the mid 1990s using airborne LIDAR and field
surveys. The
resultant data sets provide a unique time series capturing morphological
change and
post-storm adjustment due to three powerful events (Hurricanes Opal [1995],
Ivan,
[2004], and Katrina [2005]), weaker hurricanes and numerous tropical
storms. In this
paper we document a unique response of this coast to storm surge/wave
inundation and
present the concept of “barrier mass conservation.” In several
events, erosiondeposition
couplets were delineated where sediment eroded from the nearshore-beachdune
system was deposited across the barriers as large, expansive overwash
deposits
(Fig. 1). Pre-and post-storm bathymetric/topographic comparisons indicate
negligible
sediment loss to the barrier system. ...
Julie
Dean Rosati, Gregory W. Stone, Robert G. Dean, and Nicholas C. Kraus,
Restoration of Barrier Islands Overlying
Poorly-Consolidated Sediments, South-Central Louisiana,
GCAGS, 2006.
Abstract: Late
Holocene barrier islands along south-central Louisiana comprise primarily
very fine sand overlying poorly-consolidated, organic-rich, fine silts
and clays. These
barriers experience high rates of relative sea level rise largely due
to subsidence. Lowering
of a barrier island by subsidence is compounded as barrier sand is transported
onto
previously non-loaded sediments, e.g., into the bay via overwash during
storms or alongshore
due to sediment transport. The existing barrier elevation and width may
thereby
be reduced, making future overwash and inlet breaching more likely, and
the new deposit
begins to load the previously poorly-consolidated substrate. Over century
to millennial
time scales, these barriers may become subaqueous and abandoned on the
inner
shelf (e.g., Ship, Tiger, and Trinity shoals, Louisiana).
One means of abating barrier island loss is large-scale island restoration
through infusion of sediment. Because barrier islands can protect fragile
wetlands, infrastructure,
and mainland shores, large-scale island restoration is being considered
as part of
the Louisiana Coastal Area Study. However, for those barriers overlying
poorlyconsolidated
sediments, the additional loading due to island restoration will increase
the
magnitude and rate of local subsidence. Present design procedure does
not account for
time-dependent consolidation due to loading by initial placement of sediment
on these
islands and possible future maintenance renourishment. A newly-developed
twodimensional
(cross-shore) mathematical model was applied to investigate the dependence
of beach nourishment on barrier island morphologic change within a poorlyconsolidated
setting. Initial results indicate that, to minimize barrier island migration
and maintain dune height, it is advantageous to construct one large nourishment
project, rather than smaller projects that are renourished incrementally.
Felix
Jose and Gregory W. Stone, Forecast of Nearshore Wave Parameters
Using MIKE-21 Spectral Wave Model, GCAGS,
2006.
Abstract: Shallow-water
wave transformation strongly depends upon coastal geomorphology and bottom
sediment characteristics. Accurate prediction of wave parameters is vital
for the coastal infrastructure developments and other activities. MIKE
21 SW is a new
generation spectral wind wave model based on unstructured meshes. The
model simulates
the growth, decay and transformation of wind generated waves and swell
in offshore
and coastal areas. The entire Gulf of Mexico was selected for the present
modeling
study. Along the northern Gulf Coast the grid resolution used was ~2
km while for the
rest of the boundary a coarser grid of 30 km was used. Fine-scale bathymetry
data
(6 arc-second resolution) were used for the northern Gulf and coarse
bathymetry for the
rest of the basin. The data used were compiled and distributed by the
National Geophysical
Data Center (NGDC) of the National Oceanic and Atmospheric Administration
(NOAA). The input for the model, forecast wind data, was downloaded from
the National
Centers for Environmental Prediction (NCEP) of NOAA database daily (36-hr
forecast). A fully spectral approach was used for the computation of
the wave parameters.
The model computed the wave parameters using the forecast wind input.
Synoptic
maps of significant wave height (Hs), wave period, wave direction, etc.
were generated.
For calibration purposes, output was also generated for the NDBC buoy
locations and
Wave-Current-Surge Information System (WAVCIS) stations located off the
Louisiana coast. During fair weather conditions the predicted wave parameters
show a strong correlation
with measured wave parameters. During extreme weather conditions
(hurricanes and tropical storms) predicted values typically were lower
than observations.
This discrepancy can be attributed to the scale and accuracy of the input
wind
data.
Baozhu
Liu and Gregory W. Stone, Short-Term Performance of
Segmented Breakwaters along Raccoon Island, Louisiana, GCAGS,
2006.
Abstract: The
Isles Dernieres barrier island chain (Fig. 1) is experiencing some of
the highest rates of erosion of any coastal region in the world. As part
of a comprehensive barrier
island restoration plan along the Isles Dernieres, the Raccoon Island
Breakwaters Demonstration (TE-29) project consisted of eight segmented
breakwaters constructed in June
and July 1997, to reduce the rate of shoreline retreat and protect the
bird habitat of the
Louisiana State Bird, the Brown Pelican. In order to monitor the short-term
performance
of these breakwaters, topographic/bathymetric surveys have been conducted
at
biannual intervals along the island from November 2000 to July 2005...
Daijiro
Kobashi, Felix Jose, and Gregory Stone, Wave and Bottom Sediment
Interactions over a Submerged Sand
Bank during the Winter Cold-Front Season, Western Louisiana, GCAGS,
2006.
Abstract: The
Louisiana coast is experiencing severe coastal land losses due to geological
processes
and human intervention. Replenishing the eroded beaches and the barrier
islands
with sand from offshore borrow sites is a plausible way to restore them.
To assess the
potential effects of sand mining from these offshore banks, in terms
of physical processes,
a field survey was conducted on March 2004 at Sabine Bank, 15 km offshore
in
western Louisiana. Some of the data from the survey are presented here.
The results
show that waves strongly affect the bottom sediment re-suspension rather
than currents,
during cold front and post-frontal phases that occurred during the deployment.
Shear
velocity and turbidity have a positive correlation, although the linear
coefficient of determination
(R2) was 0.43. Maximum normalized cross-correlation coefficient between
the
two parameters was 0.82. The above results suggest that the waves greatly
affect the
bottom sediment and both parameters have some degree of positive correlation,
which is
not necessarily linear. The non-linear correlation may be associated
with bottom roughness
and sediment type as well as wave parameters. A simplification of the
relationship
using a stability parameter is also examined.
Walter
S. Guidroz, Gregory W. Stone, and Dane Dartez, Hurricane Rita, 2005:
Assessment of a Storm-Induced Geological Event
along the Southwestern Louisiana Coast and Adjacent Interior Marsh, GCAGS,
2006.
Abstract: The
landfall of Hurricane Rita on September 24, 2005 significantly altered
physical and morphological characteristics along the western Louisiana
coast as well as marshes approximately 25 km inland. Storm-surge measurements
show super elevated water
levels around 15 ft (4.6 m) were measured in the Cameron area to the
east. A helicopter
overflight of central and southwestern Louisiana, undertaken by the Coastal
Studies
Institute of Louisiana State University about three weeks after Hurricane
Rita’s landfall,
revealed major storm-induced sedimentologic phenomena directly attributable
to the
passage of this Category 3 storm. Overwash deposits (predominantly fine
sand) and
evidence of excessive storm surge and salt-water intrusion were clearly
evident in Cameron
and Vermilion parishes, Louisiana. These responses became progressively
more
pronounced farther west, culminating at the point of eyewall impact near
Sabine Pass on
the border between Texas and Louisiana. Widespread damage to physical
infrastructure
was also noted within several communities located on or near the coast,
particularly
in Cameron and Holly Beach, Louisiana. Excessive salinity levels resulting
from saltwater
intrusion severely impacted local vegetation several kilometers inland
and, over the longer term, may exacerbate existing problems linked to
coastal erosion through the
loss of vegetation that retards coastal erosion and attenuates waves
and storm surge during
high-energy events. However, initial post-storm beach recovery was also
noted early
post-storm landfall. Bar welding to the lower shoreface was evident as
sediment was
being reworked onshore by waves. Follow-up observations will focus on
documenting
continued post-storm recovery as well as the potential effects of future
tropical cyclones
that may impact the area.
B. Prasad
Kumar and Gregory W. Stone, Numerical Simulation of Typhoon Wind Forcing
in the Korean Seas Using a Spectral Wave Model, Journal of Coastal Research,
in Press.
Abstract: This
study investigates the application of the wave model (WAM) to simulate
the generation and propagation of typhoon waves in Korean seas. The model
solves the energy balance equation for wave growth based on wind energy
input, and simulates spatial and time evolution of wave spectra. Although
WAM has been extensively validated and used in various global and regional
wave forecasts, its application to the simulation of typhoon waves has
not been investigated thoroughly.
Crucial to the application of WAM in typhoon wave modeling is the specification
of accurate wind input data and adequate resolution of the wind structure.
This study compares and analyzes two different wind fields for the same
event, viz., simulated wind field from a storm model and blended global
QSCAT/NCEP winds. The simulation experiment was run for 4 days as Typhoon
Olga (1999) approached the west coast of Korea. The results are compared
with shallow water buoy observations as the typhoon was approaching landfall.
The simulated significant wave heights in the open ocean were approximately
8.6 m, which gradually decreased as the typhoon approached shore. Olga
was an intense typhoon, and its compact wind structure provides a unique
test case to examine the required directional, frequency, and spatial
resolution in WAM for modeling typhoon generated waves.
John
Ellis and Gregory W. Stone, Numerical simulation of net longshore sediment
transport and granulometry of surficial sediments along Chandeleur
Island, Louisiana, USA, Marine Geology, Vol. 232, Issues 3-4 , pp.
115-129, 7 November 2006.
Abstract: The
formation and spatial evolution of Chandeleur Island, Louisiana, has
been investigated extensively during the past several decades. No significant
evaluation of the longshore sediment system, which is instrumental in
the island's evolution and morphodynamic maintenance, has been completed.
This paper provides the first quantitative description of the longshore
transport system that operates along this transgressive, overwash-dominated
barrier island system.
The net longshore sediment transport system was investigated via the
wave refraction model, WAVENRG, which provided estimates of the transport
volumes and drift directions alongshore. Surficial samples were collected
from the foredune, midtide and step environments in an effort to characterize
the sediments along the island and determine if textural or compositional
trends have developed in response to a predicted longshore sediment transport
system. Data obtained during this research indicate that the longshore
transport system along Chandeleur Island is characterized by a bidirectional
drift
system, with drift directed both north and south from a nodal point located
in the south-central portion of the barrier island. Analysis of the predicted
transport volumes indicates that the degree of wave refraction, and therefore
the breaker angle, is more instrumental in controlling the alongshore
volume rate of sediment transport than the breaker wave heights. Additionally,
a larger magnitude of sediment transport is predicted in the southern
portion of the barrier, which is in a greater state of deterioration
than the north and central portion of the island. This apparent contradiction
indicates that factors such as a variable subsidence rate along the island
are contributing to the alongshore geomorphology. No significant textural
or compositional trends were identified alongshore. This absence of granulometric
trends is attributed to the lack of variability of the sediments that
comprise the barrier and the frequency of overwash events which occur
on this low-profile island.
Gregory
W. Stone and Robert A. Muller, Meteorological Effects
on Coasts, in Press.
Abstract: The
most dramatic and long-lasting meteorological impact on many coasts is
in response to storms. Virtually, every continent on earth is variously
impacted by storms, the degree to which being a function of many factors
including storm intensity, duration and path, as well as antecedent geology
of the inner shelf and coast. Cyclones that exert important controls
on coasts are generally categorized as hurricanes, tropical, and extratropical
storms. Land- and sea-breezes are observed along many coasts and are
in response to differential temperatures during day and night; onshore
winds during the day develop nearshore sea state, whereas offshore flow
in the evening causes wave decay close to shore. Neither effect can equal
the impacts of waves, currents, and winds generated during cyclones.
The low latitudes are dominated by tropical storms and hurricanes, whereas
the mid- and higher-latitudes experience extratropical storms and weather
fronts. Frontal systems are associated with extratropical cyclone: development...
Ping Wang
and Gregory W. Stone, Nearshore Wave Measurement, in Press.
Abstract: Generally,
water waves are described by two length parameters, wave height and wavelength,
and one temporal parameter, wave period. Wave height is the vertical
distance between the wave crest and trough. Wavelength is the horizontal
distance between two successive wave crests or alternatively, wave troughs.
Wave period is the time needed for two successive crests or troughs to
pass a spatial reference point. Direction of wave propagation is also
an important parameter and critical when computing wave-induced sediment
transport vectors. Scientific convention describes the wave direction
as "direction to which it propagates" measured clockwise from
the x-axis. In practice, however, wave direction is often reported as "direction
from which the waves propagate," similar to the description of wind
direction. It is necessary to specify the wave direction convention to
avoid confusion. Depth over which the waves propagate is also important
and is necessary in linking wave height and length to other parameters
such as wave-induced water particle velocities and accelerations...
Gregory
W. Stone, Xiongping Zhang, and Alexandru Sheremet, The Role of Barrier
Islands, Muddy Shelf and Reefs in Mitigating the Wave Field Along Coastal
Louisiana, Journal of Coastal Research, Special issue No. 44, 2005.
Abstract: Rapid deterioration of the harrier coast in coastal Louisiana is resulting
in a transf{)rmation of low-energy, semiprotected hays into high-energj',
open marine environments. Numerical models lADCIRC and SWAN) are used
to hindcast, nowcast, and forecast wave conditions along south-central
coastal Louisiana. Measurements from across the shelf, nearshore, and
hays are also used to shed light on the mitigative ahility of harriers
on the wave and .surge field during tropical cyclones. Along western
Louisiana the coast is fronted hy a muddy shelf, supplied hy sediment
from the Atchafalaya River. The cohesive nature ofthis material results
in significant damping of waves, particularly during storm events. East
ofthis area the coast is characterized hy shell reefs that have historically
been dredged for commercial use. Numerical modeling demonstrates that
with the reduction in reefs over time, wave energy in the adjacent Acadiana
Bays has increased considerahly and is likely responsihle in part for
erosion along marshes fringing the hays.
G.W.
Stone, N.D. Walker, S.A. Hsu, A.Babin, B. Liu, B. D. Keim, W.Teague,
D. Mitchell, And R. Leben, Hurricane Ivan’s Impact Along The Northern
Gulf Of Mexico, Eos, Vol. 86, No. 48, pp. 497–508, 29 November 2005.
Abstract: Just
over a year after the landfall of Hurricane Ivan, scientists have now
had an opportunity to evaluate a variety of oceanographic and geologic
responses to this storm. Hurricanes Ivan, Katrina, and Rita are among
the most powerful hurricanes recently to enter the Gulf of Mexico. Although
it weakened from a very powerful Category 5 hurricane to a Category 3
before making landfall along the Alabama coast, Hurricane Ivan devastated
the coasts of northwestern Florida and Alabama on 16 September 2004.This
article summarizes what researchers have learned about Hurricane Ivan
as it moved into the Gulf and made landfall along the northeastern Gulf
of Mexico coast. The article focuses on storm meteorology, sea state,
shelf circulation, and sediment transport on the shelf and along the
coast.
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Gregory W. Stone, Baozhu Liu,
Offshore Hydrodynamics and Geological Impacts of Hurricane Ivan along the Northeastern Gulf of Mexico.
Abstract: In this paper we present the hydrodynamics and coastal impacts associated with Hurricane
Ivan. In mid-September Hurricane Ivan entered the southern Gulf of Mexico over the Yucatan
Channel as a category 5 storm (winds in excess of 155 mph). The hurricane moved generally
north across the central Gulf generating waves that were between 21 m (70 ft) and 27 m (90 ft)
high causing severe damage to numerous oil and gas platforms offshore. East of the mouth of the
Mississippi River, an National Data Bouy Center buoy measured 16.8 m (52.5 ft) waves, the highest
ever recorded during a hurricane. East of the Chandeleur Islands along southeastern
Louisiana, waves approximating 7.6 m (25 ft) were recorded as Ivan veered to the north-northeast
prior to landfall. Although downgraded to a category 3 hurricane at landfall east of Gulf
Shores, Alabama, storm surge along the open coast in excess of 3m (10 ft) was measured and
breaking waves of 3.7 m (12 ft) were modeled. Beach erosion along the Louisiana (Chandeleur
Island), Alabama and northwest Florida coast was severe. Barrier islands were overwashed and
breached extensively, and foredunes with pre-storm elevations of 3.5 m (12 ft) were reduced to sea
level. Beach erosion approximating 50 m (~150 ft) was measured along the Florida Panhandle
near Pensacola Beach. Remarkably, however, many of the barrier islands did not loose considerable
amounts of sand since beach and dune sediment was transported across the island as large
overwash deposits whose marginal lobes prograded the backbarrier beach over 100 m (~325 ft)
into the adjacent bay. This phenomenon, referred to as conservation of barrier mass, was also
measured after Hurricane Opal, a powerful hurricane that impacted the Florida Panhandle in
1995. Considerable structural damage occurred to beach homes and condominiums along the
coast as well as to road, bridge and highway infrastructure connecting the mainland to the outer
coast.
Baozhu
Liu, Gregory W. Stone, Short-Term Performance of Segmented Breakwaters
along
Raccoon Island, Louisiana.
Abstract: The Isles Dernieres barrier island chain along the Louisiana coast is experiencing some of
the highest rates of erosion of any coastal region in the world. In order to protect the nesting habitat
of the State Bird Brown Pelican, eight segmented breakwaters were constructed in June and
July of 1997 off the southeastern shore of Raccoon Island, Louisiana, one of four barrier islands
comprising Isles Dernieres. Beach surveys have been conducted at biannual intervals along the
island from November 2000 to July 2004 to monitor the response of the barrier to post-breakwater
construction. Since the November 2000 survey, sediment volume in the area landward of the
breakwaters increased by 2.3% whereas seaward of the structures sediment volume decreased by
7.05%, and west of breakwaters sand volume decreased by 22.59%. During the high energy conditions
associated with Hurricane Lili in October 2002, areas landward of the breakwaters lost
0.24% of sediment, areas seaward of the breakwaters lost 5.38% in volume, while areas west of
the structures lost 26.88%. Over a one year period (June 2003 through July 2004), areas west of
the breakwaters lost approximately 12.33% of its sediment volume, however, areas landward of
the breakwaters a volume increase of 2.04% was measured. These data strongly suggest that during
the period of study that the segmented breakwaters have resulted in a net sediment gain
behind the structures.
Xiongping
Zhang , Gregory W. Stone, DeWitt Braud and Yuliang Chen, An Improved
Ocean Observing System for Coastal Louisiana:
WAVE-CURRENT-SURGE Information System.
Abstract: WAVE-CURRENT-SURGE Information System (WAVCIS) is a regional ocean observing
and forecasting system. It was designed to automatically measure, process, forecast, and distribute
oceanographic and meteorological information. WAVCIS was developed and is maintained
by the Coastal Studies Institute at Louisiana State University. The in-situ observing stations are
distributed along the central Louisiana and Mississippi coast. The forecast region covers the
entire Gulf of Mexico with emphasis on offshore Louisiana. By using state-of-the-art instrumentation,
WAVCIS provides data on waves, currents, temperature, water level, visibility, humidity,
turbidity, and salinity. Through satellite communication links, measured data are transmitted to
the WAVCIS laboratory. After processing, they are available to the public via the internet on a
near real-time basis. WAVCIS also includes a forecasting capability. Waves, currents, and winds
are forecast every day for up to 84 hours in advance.
There are a number of numerical wave and surge models that can be used for forecasts.
Two third generation wave models, WAM (Wave Model) and SWAN (Simulating Waves Nearshore),
have been selected for operational purposes to forecast waves. The final choice of
operational surge models will be decided by comprehensive spatial testing. Interpolated winds
from the ETA wind model operated by NOAA’s National Center of Environmental Prediction
(NCEP) are used as input forcing for waves. Both in-situ and forecast information are available
online to the users through World Wide Web. Interactive GIS web mapping is implemented on
the WAVCIS webpage to visualize the model output and in-situ observing data. WAVCIS data
can be queried, retrieved, downloaded, and analyzed through the web page. Near real-time
numerical model skill assessment can also be performed by using the data from in-situ observing
stations.
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Ioannis
Y. Georgiou, Duncan M. FitzGerald, and Gregory W. Stone, The Impact
of Physical Processes along the Louisiana Coast, Journal of Coastal
Research. Special Issue No. 44, 72-89, 2005.
Abstract: GEORGIOU,
I.Y.; FITZGERALD. D.M.. and STONE. G.W., 2005. The Impact of Physical
Processes alonf; the Louisiana Coast. Journal of Coastal Research. SI(44i,
72-89. West Palm Beach (Florida). ISSN 0749-0208.
The present-day coast of Louisiana is undergoing unprecedented change
when compared with other coastal regions of the United States, Whereas
most of its shoreline is retreating and its coastal hays expanding at
the expense of wetlands, the Wax Lake and Atchafaiaya deltas are prograding
and forming new delta plains. Coastal processes responsihle for reworking
the lower delta plain and modifying the coast are modest, including very
low-wave energy and a microtidal regime. However, occasional hurricanes
and more frequent frontal systems produce elevated water levels and large
waves (heights >1 to 2 nietersl, which produce erosion, overwash,
and barrier hreaching. High subsidence rates coupled with custatic sea-level
rise and wave erosion are converting wetlands to open-water bays. Along
harrier shorelines, this process is increasing tidal exchange, which
is enlarging tidal inlets and the volume of sand captured in ebb-tidal
deltas. Sequestration of sand in offshore ebb shoals depletes sand resources
to the barrier chain. The segmentation, landward migration, and overall
decrease in size of the barriers are a product of relative sea-level
rise and the lack of contribution of new sediment to the system. Restoration
uf the barriers should be planned with an understanding that the Louisiana
coast is evolving in a transgression.
Mead
A. Allison, Alexandru Sheremet, Miguel A. Gonc, Gregory W. Stone, Storm
layer deposition on the Mississippi–Atchafalaya subaqueous delta generated
by Hurricane Lili in 2002,Continental Shelf Research 25 (2005) 2213–2232.
Abstract: The
Atchafalaya inner continental shelf, located along the north-central
Gulf of Mexico offshore of Louisiana, is an area of rapid mud accumulation
associated with the progradation of a subaqueous delta originating from
this Mississippi River distributary. In September–October 2002, this
region was impacted by two tropical cyclones (Tropical Storm Isidore
and Hurricane Lili) separated by only 7 days. Water-column and hydrodynamic
records from coastal observation platforms (WAVCIS network) are combined
with seabed sampling 4–7 days after passage of Lili, to examine the impact
of these events on the Atchafalaya inner shelf. Wind speeds at the CSI-3
platform on the delta (located in 4.5m of water) peaked at 20 m/s during
Isidore, and more than 30 m/s during the closer, and stronger, Lili event.
Significant wave heights during Lili peaked at more than 2m at the CSI-3
platform, coincident with a storm surge of about 2m. Water-column flow
structure during both storms was closely tied to the storm surge (coastal
setup–setdown) cycle despite variations in wind direction with storm
passage. Flow was onshore throughout the water column during the waxing
phase (1.5 days in Lili, 4 days in Isidore), with a rapid (1–2 h) reversal
to offshore flow after storm passage (�12 h waning phase). Flow velocities
remained above 1 m/s throughout the ADCP-measured water column (465 cm
above the bottom) for more than 2 days during the Lili event. Sediment
cores reveal the presence of a basal erosional surface, hypothesized
to represent seabed deflation from the combined resuspension attributable
to both storms, overlain by a silty clay storm deposit 2–19 cm thick.
Comparison with 7Be seabed profiles and X-radiographs taken at two delta
stations (5m water depth) prior to and following the storm suggests erosional
deflation of 3–13 and 7–17 cm occurred at these stations. The overlying,
physically stratified storm deposit contains radioisotopic inventories
( 7Be, 234Th, 137Cs, 210Pb) that are consistent with an origin primarily
from redeposition of particles resuspended in the waxing phase of the
storm. X-radiography and granulometry suggest two-phase re-deposition:
an initial, normally graded basal deposit 1–2 cm thick containing sand
that likely was deposited from normal settling, and a slightly normally
graded, sand-poor unit hypothesized to be deposited from consolidation
of a fluid mud (410 g/l), hindered settling suspension later in the waning
phase. Macrofaunal burrows in the storm deposit suggest rapid (days)
settlement of surviving fauna, likely due to high abundance in the sediments
at this time of year when burial rates (from Atchafalaya River sediment
supply) and energies sufficient for bottom resuspension are normally
low. r 2005 Elsevier Ltd. All rights reserved.
Frank
W. Stapor, Gregory W. Stone, Reply to comment "Validity of sea-level
indicators" by E.G. tvos, Marine Geology 217 (2005) 189– 191.
Otvos (in
press) has raised a number of interesting comments concerning our interpretation
of the origin of the buried, Holocene New Orleans Barrier. These comments
address (1) the proposed disconformable rather than gradational/conformable
relationship between the Barrier Complex and the underlying Nearshore
Shelf Deposit, (2) the significance of onshore sediment transport rather
than longshore transport, and (3) the nature of the Holocene sea-level
curve for the northern Gulf of Mexico: a Shepard (1963, 1964)-type that
describes a continually, but not uniformly, rising, non-fluctuating,
sea-level that asymptotically approaches the present-day position versus
a Fairbridge (1961, 1976)-type that describes a series of fluctuations,
which have exceeded presentday level by perhaps up to several meters,
and that decrease in both amplitude and duration toward the
present-day position. ......
Yixin
Luo, Doris L. Carver, Increasing the Difficulty of Reverse Engineering
Object-Oriented Code.
Industry
loses billions of dollars annually through software theft. The illegal
use of software through unauthorized use or duplication of software poses
a major threat to companies who invest heavily in software. The loss
is not only in the loss of proprietary code but also the loss of information
about the business rules that are embedded in the code. Obsuscation aimed
at protecting software against malicious host attacks. Malicious host
attacks are related to attacks to a benign client by a malicious host
by pirating, malicious reverse engineering, or tampering with code.
Baozhu
Liu, Yoshiki Saito, Toshitsugu Yamazaki, Abdelaziz Abdeldayem, Hirokuni
Oda, Kazuaki Hori, and Quanhong Zhao, Anisotropy of Magnetic Susceptibility
(AMS) Characteristics of Tide-Influenced Sediments in the Late Pleistocene-
Holocene Changjiang Incised-Valley Fill, China, Journal of Coastal
Research, Vol. 21, No. 5, 1031–1041, 2005
Abstract:Magnetic
Susceptibility (AMS) Characteristics of Tide-Influenced Sediments in
the Late Pleistocene-Holocene Changjiang Incised-Valley Fill, China.
Journal of Coastal Research, 21(5), 1031–1041. West Palm Beach
(Florida). ISSN 0749-0208.12
In order to probe anisotropy of magnetic susceptibility (AMS) characteristics
of tide-influenced sediments, AMS analyses and primary sedimentary structure
observation and description were conducted on the borehole CM-97 samples
from Changjiang delta, China. Primary sedimentary structure (cross-laminations)
observation and description were based on a detailed examination of X-ray
photographs of samples. Primary cross-laminations were found on 19 of
35 subcores, among which five subcores, A6, A7, B17, B30, and B38, have
bidirectional cross-laminations. We found a total of 35 cross-laminations
on the subcore sections of tide-influenced sediments, of which 14 were
distributed on the five subcores with bidirectional cross-laminations.
By their bidirectional dipping foreset laminae, the primary crosslaminations
clearly showed bidirectional flow features of the environments in which
these sediments formed. Comparing the paleocurrent directions shown by
these cross-laminations with those indicated by the in situ AMS data,
we found that more than 64% exhibited similar current directions, demonstrating
that AMS can supply us with the true paleocurrent directions for such
sediments. From the downhole paleocurrent changes inferred from the in
situ AMS data, it was also clear that there were bidirectional flows
during the deposition of these sediments and that sediments deposited
in different environments had different change characteristics with respect
to downhole paleocurrents. These differences among the muddy intertidal-
to subtidal-flat sediments (unit 5), the Changjiang estuary central basin
sediments (unit 6), and the delta front sediments (unit 8) may have resulted
from the different hydrodynamic conditions of these sedimentary environments.
Furthermore, stratigraphic unit 5 was subdivided into three parts based
on downhole AMS characteristics, which may correlate with those subdivided
according to downhole paleocurrent changes. Therefore, besides its long
recognized role in paleocurrent determination, AMS can also be used to
determine stratigraphic divisions and to reconstruct sedimentary paleoenvironments
in detail.
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A.
Sheremet, A.J. Mehta, B. Liu, G.W. Stone, Wave–sediment interaction
on a muddy inner shelf
during Hurricane Claudette, Estuarine, Coastal and Shelf Science 63 (2005)
225–233
Abstract:Measurements
of wave and suspended sediment concentration (SSC) were conducted near
the 5-m isobath on the muddy inner shelf fronting Atchafalaya Bay, Louisiana,
during Hurricane Claudette. The data show that wave and current activity
resuspended large quantities of sediment, with SSC R 0.5 kg/m3 throughout
the water column. In the waning phase of the storm, settling generated
a suspension layer, with concentrations over 1.7 kg/m3 measured as high
as 1 m above the bottom. Numerical simulations of post-storm sediment
settling showed that observations are consistent with a high-density
fluid mud layer (SSC between 10 and 20 kg/m3), and separated from the
upper water column by a lutocline located at about 1 m above the bottom.
The formation of the fluid-mud layer is correlated with strong, broad-spectrum
wave dissipation, consistent with the hypothesis that surface–interface
wave interaction plays an important part in the energy transfer from
the surface to the soft bottom.
A.
Sheremet, G. W. Stone, and X. Zhang, Wave-Induced Sediment Resuspension
on A
Muddy Inner Shelf During Hurricane
Claudette.
Abstract:The
evolution of suspended sediment concentration was monitored during Hurricane
Claudette near the 5-m isobath on the muddy inner shelf fronting Atchafalaya
Bay, Louisiana. Relatively strong wave and current activity resuspended
large quantities of sediment. In the waning phase of the storm, settling
generated a high turbidity layer, consistent with the formation of a
fluid mud layer (concentrations higher that 10 kg/m3) with a thickness
of over 1 m above the bottom. The formation of the fluid-mud layer is
correlated with strong, broad-spectrum wave dissipation, suggesting that
wave-suspended sediment interaction plays an important part in the energy
transfer from the surface to the soft bottom. Virginie
Lafon, Felix Jose, et al. Summertime Morphodynamics of
Two Beaches Presenting Different Wave Exposure - Fatal Island,
Azores, Portugal
Abstract:This
contribution presents the results of intensive field surveys executed
during late spring and summer 2004 along two pocket beaches located in
the northwestern and eastern coast of the Faial island (Azores archipelago,
Portugal). The main purpose of this study was to characterize the morphodynamics
of these two beaches by associating the short-term evolution of a couple
of beach profiles, monitored on a fortnight basis, with the wave climate
and wave refraction model output. Study shows that both these beaches
are undergoing rapid and significant phases of accretion/erosion during
summer time in relation with growing sea state. Also, fast beach rotation
has been noted. Although these two beaches are located to the west and
to the east of the island and despite the prominence of westward waves
and winds, their evolution appears simultaneous. This manuscript constitutes
the first step towards achieving a comprehensive understanding of beach
morphodynamics in the Azores. Gabrielle
Allen, Philip Bogdan, Gerry Creager, Chirag Dekate, Carola Jeschl,Hartmut
Kaiser, Jon MacLaren, Greg Stone, Xiongping Zhang, GIS and integrated
coastal ocean forecasting, Concurrency and Computation: Practice
and Experience, in Press
Abstract:The
SURA Coastal Ocean Observing and Prediction (SCOOP) program is implementing
a GIS driven visualization system to integrate distributed data sources
across the United States and Canada. Hydrodynamic models are run at different
sites on a developing distributed computational grid. Some simulations
are triggered by tropical and subtropical cyclones in the Atlantic coastal
area and the Gulf of Mexico. Model outputs along with data from observational
entities need to be visualized in a geospatial context to enable relevant
analyses. A data archive at LSU aggregates data from these different
resources, and an automated workflow leads to remote data conversion
from model output formats to georeferenced data sets and delivers them
to a Web Map Server located at Texas A&M University. This paper describes
the current use of GIS within the SCOOP program, along with details of
the automated distributed dataflow and workflow which results in geospatial
products. We also discuss future plans related to the use of GIS and
Grid technologies, through which we hope to provide a wider range of
tools that can enhance the capabilities of general Earth Science researchers.
^
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Philip
Bogden, Greg Stone, et al. The Southeastern University Research Association
Coastal Ocean Observing and Prediction Program:
Integrating Marine Science and Information Technology
Abstract:The
Southeastern University Research Association
(SURA) Coastal Ocean Observing and Prediction (SCOOP)
program includes university, government, and private sector
partners working together to implement Information
Technology solutions. The SCOOP program goal is a modular
and distributed system for predicting and visualizing the coastal
response to extreme atmospheric events, including the
damaging and catastrophic effects of storm surge, inundation
and wind waves. SCOOP program partners are creating the “
IT glue” for this interoperable system of systems by
modularizing critical components and standardizing the
interfaces between the modules. SCOOP emphasizes the
transition of “pre-operational” research activities to operational
status, and uses the real-time prediction system as an innovative
research tool. SCOOP partners are turning environmental
measurement and prediction into a community effort and a
real-time collaboration between research institutions and
operational agencies.
Yoshihiro
Mazda, Daijiro Kobashi and Satoshi Okada, Tidal-scale hydrodynamics
within mangrove swamps, Wetlands Ecology and Management (2005) 13:647–655
Abstract:Both
the drag force and the horizontal eddy viscosity play a dominant role
in the tidal-scale hydrodynamics in mangrove wetlands. Using field observations
and basic fluid mechanics laws, the drag coefficient and the coefficient
of dynamic eddy viscosity are found to be predictable as a function of
the Reynolds Number based on the characteristic length scale of the vegetation.
The characteristic length scale of the vegetation varies greatly with
vegetation species, vegetation density and tidal elevation. Both these
coefficients decrease with increasing values of the Reynolds Number.
At the low range of the Reynolds Number both these coefficients reach
much higher values than those typical of vegetation-poor estuaries and
rivers. Consequently, the tidal flow within mangrove areas depends to
a large degree upon the submerged vegetation density that varies with
the tidal stage. These findings may be applied also in other vegetated
tidal wetlands, including salt marshes.
Daijiro
Kobashi, and Yoshihiro Mazda, Tidal flow in riverine-type mangroves,
Wetlands Ecology and Management (2005) 13:615–619
Abstract:The
behavior of tidal flow in the riverine-forest type is investigated in
the Aira-River mangrove area in Iriomote Island, Japan. In the mangrove
swamp near the bank of the creek, a velocity component parallel to a
tidal creek reduces greatly in the direction perpendicular to the creek.
Based on this finding, it is theoretically suggested that the eddy viscosity
in the mangrove swamp, which is caused by the interaction between mangrove
vegetation and the shear stress resulting from the tidal flow in the
creek, plays an important role in the hydrodynamics of the mangrove swamp.
Daijiro
Kobashi, Felix Jose, and Gregory W. Stone, Hydrodynamics and sedimentary
responses within the bottom boundary layer: Sabine bank, western Louisiana,
Transactions, Gulf Coast Association of Geological Society (2005) 55
Abstract:To
determine the wave-current interactions and bottom boundary layer characteristics
of eastern Sabine Bank, off the southwestern Louisiana coast, an extensive
array of bottom mounted equipment was deployed for a period of 44 days
(11 March - 23 April, 2004). The instrument array mainly consisted of
Acoustic Doppler Velocimeters (ADV’s), Electromagnetic current
meters (ECM’s), Optical Backscatters (OBS’s) and pressure
sensors deployed at three locations (on the crest along the eastern flank
of the bank, offshore and onshore of the bank). The results show that
waves were generally from south-east with a mean peak period of 5.2 s.
The highest significant wave height obtained was 1.8 m. Velocities parallel
to the coast prevailed during fair-weather wave conditions. However,
during cold fronts and strong wind regimes, cross-shore velocity components
dominated. The significant wave height and the corresponding shear stress
and shear velocity, all show higher values associated with the passage
of cold fronts and during strong southerly/southeasterly wind regimes,
when larger than the threshold for sediment re-suspension velocities
were estimated from grain-size data. Hence it is inferred that waves
during fair weather are too weak to re-suspend bottom sediments. However,
waves during the cold fronts can effectively re-suspend and re-distribute
sediments along the bank. It is also suggested that the strong wind regimes
which usually occur during this period of the year can strongly affect
sediment transport as effectively as the cold fronts do.
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Martin
White, Christian Mohn, Igor Bashmachnikov, Felix Jose and Jose-Luis
Pelegrí, Dynamics at an elongated, intermediate depth seamount in the north Atlantic
(Sedlo
Seamount, 40 20’N, 27 50’W)
Abstract:Observations from a large mooring array over a 4 month period, together with supporting
hydrographic and underway ADCP measurements, in the vicinity of Sedlo seamount are
described. Sedlo seamount is an elongated, intermediate depth, seamount with 3 separate
peaks, rising from 2200m water depth to summit peaks between 950-750 m depth,
located at 40.3oN, 26.8oW. Currents measured between 850-950m depth - the layer close
to the summit depth of the shallowest SE peak, showed a mean anti-cyclonic flow pattern
around the seamount, with mean currents of 2-5 cm s-1. Significant mesoscale variability
was present at this level, however, coherent between moorings and partly attributed to the
weak and variable background impinging flow. Stronger, more persistent currents were
found at the summit mooring as a result of tidal rectification and some weak
amplification. Below 1300m, currents were extremely weak, even close to the seabed.
Measurements of relative vorticity indicated a mean of -0.06f, where f was the local
Coriolis frequency and the timeseries showed persistent anti-cyclonic vorticity except for
two periods of cyclonic vorticity, probably generated by, and perturbation by, the
advection of Mediterranean Water into the region. Modelling results confirmed that the
anti-cyclonic circulation over the seamount was likely due to Taylor Cone generation and
a positive density anomaly was found over the seamount extending ~150m above the
summit level, consistent with simple idealised theory and the supporting hydrographic
observations. The model also predicted the generation of a cyclonic vortex at a depth
level above the anti-cyclonic circulation cell. This pairing of vortex cells over the
seamount was also indicated by underway ADCP measurements made during one
hydrographic survey of the seamount. The generation mechanism of the vortex pair was
not identified but highlighted the fact that flow perturbation generated around an
intermediate depth seamount might extend into the biologically important surface layers.
It may also be the depth level where interior flow may be advected over the seamount to
compensate that postulated to be advected off seamount at a level near the summit rim.
Possible impacts of the dynamics on the biological functioning at Sedlo seamount are
discussed.
David
A. Pepper, Gregory W. Stone, Hydrodynamic and sedimentary responses
to two contrasting winter storms on the inner shelf of the northern
Gulf of Mexico, Marine Geology 210 (2004) 43– 62
Abstract:Results
are presented from the deployment of three bottom-mounted instrumentation
systems in water depths of 6–9 m on the sandy inner shelf of Louisiana,
USA. The 61-day deployment included nine cold front passages that were
associated with large increases in wind speed. Two of the most energetic
cold front passages were characterized by distinct meteorological, hydrodynamic,
bottom boundary layer, and sedimentary responses and may potentially
be treated as end-member types on a continuum of regional cold front
passages. Arctic surges (AC storms) have a very weak pre-frontal phase
followed by a fairly powerful post-frontal phase, when northeasterly
winds dominate. Migrating cyclones (MC storms) are dominated by a strong
low-pressure cell and have fairly strong southerly winds prior to the
frontal passage, followed by strong northwesterly winds. On the basis
of measurements taken during this study, AC storms are expected to have
a lower average significant wave height than MC storms and are dominated
by short-period southerly waves subsequent to the frontal passage. Currents
are weak and northerly during the pre-frontal phase, but become very
strong and southwesterly following the passage. Sediment transport rate
during AS storms was not as high as during MC storms, and the mean and
overall direction tended to be southwesterly to westerly, with low-frequency
flows producing easterly transport, and wind-wave flows producing southeasterly
transport. MC storms had the most energetic waves of any storm type,
with peaks in significant wave height occurring during both the pre-
and post-frontal phases. The wave field during MC storms tended to be
more complex than during AS storms, with an energetic, northerly swell
band gradually giving way to a southerly sea band as the post-frontal
phase progressed. Currents during MC storms were moderate and northerly
during the pre-frontal phase, but became much stronger and southeasterly during
the post-frontal phase. Shear velocity was high during both the pre-
and post-frontal phases of the storm, although sediment transport was
highest following the frontal passage. Mean and overall sediment transport
was directed southeasterly during MC storms, with low-frequency and wind-wave
flows producing northerly transport. In summary, the data sets presented
here are unique and offer insight into the morphosedimentary dynamics
of mid-latitude, micro-tidal coasts during extratropical storms.
FrankW.
Stapor Jr., Gregory W. Stone, A new depositional model for the buried
4000 yr BP New Orleans barrier: implications for sea-level fluctuations
and onshore transport from a nearshore shelf source, Marine Geology
204 (2004) 215-234
Abstract:The
Holocene New Orleans Barrier Complex, now buried by the St. Bernard delta
of the Mississippi River, provides an excellent example of barrier deposition
fed by a nearshore sediment source. This reworking and onshore transport
was initiated by a sudden change in the shelf equilibrium profile caused
by a sea-level fall about 4100 yr BP. Here we present a new model of
barrier formation which does not invoke an Shepard-type Holocene sea-level
curve nor the supply of sediment from a longshore source. The Holocene
New Orleans Barrier Complex consists of finegrained, locally cross-bedded,
quartz sand that contains Ophiomorpha nodosa burrows and disarticulated
mollusks, primarily marine, buried beneath up to 4 m of silty mud of
the St. Bernard Lobe. This barrier island and shoal deposit overlies
interbedded, fine-grained sand and mud containing marine mollusks, some
articulated, that is interpreted to be a nearshore shelf deposit. Its
deposition tookplace between 5500 and 4200 yr BP (14C), based on individual
dates on seven articulated and seven disarticulated shells. The barrier
formation is effectively limited to a several-hundredyear window approximately
4000 yr BP by the 3800 yr BP Rangia sp. shells from the immediately overlying
St. Bernard Lobe delta-plain deposits and the buried 3900^3500 yr BP
Linsley archeological site, situated on a more gulfward distributary
levee. In this paper we present a new depositional model on the New Orleans
Barrier. The barrier complex contains an abundance of large molluskshells
that have been reworked to the extent that 14 individual shells yield
a 2500-year range, 6000^3500 yr BP. An older, nearby source is required.
The current model of a spit/shoal complex migrating westward from an
eroding eastern Pleistocene headland probably cannot account for the
deposition of large reworked shells given the effects of abrasion and
selective size sorting over approximately 50 km of longshore transport.
Furthermore, this model demands transport rates of millions of cubic
meters per year for the present northern Gulf coast which are at least
an order of magnitude higher than its highest known rates. We postulate
a nearby shell and sand source that is subjacent and offshore rather
than adjacent and littoral. We propose it to be the underlying nearshore
shelf deposit that could be mobilized by a brief fall of sea level and
carried landward. The barrier complex and the uppermost nearshore shelf
deposit have markedly different net deposition rates. The upper 25 cm
of the nearshore shelf deposit were deposited over 800 years, based on
ages of articulated marine pelecypods. A 20-km-long, 3-km-wide and 4-m-thick
segment of the barrier complex was deposited in less than 300 years.
A 10-cm-thicklag pavement of bryozoan- and oyster-encrusted molluskshells
that comprises the nearshore shelf deposit beneath the northern edge
of the barrier complex is evidence for an essentially zero net deposition
rate. The current interpretation of a conformable, progradational relationship
between these two units is rejected in favor of a disconformable contact.
The hiatus across this disconformity must be less than the several-hundred-year
duration of barrier complex deposition. The positioning of the shallower-water
barrier complex disconformably over the deeper-water nearshore shelf
deposits indicates a sea-level fall.
Gregory
W. Stone, Julian D. Orford, Storms and their significance in coastal
morpho-sedimentary dynamics, Marine Geology 210 (2004) 1–5.
Abstract:The
issue of storms as extreme events in coastal evolution and their variation
over the late Holocene is the theme of this special issue. There has
been no coherent attempt to address the theme of storms with respect
to their effect on coastal margins around the North Atlantic Ocean as
a whole. Although a number of authors have approached the issue of hurricanes
and tropical storms on the American seaboard (e.g. Simpson and Riehl,
1981), the effect of the westerly depressions leading to mid-latitude
storms along the western coast of Europe has not been described in a
coherent thematic way from storm inception to landfall. Apart from Lamb’s
(1991) seminal work on storm reconstruction and impact, there is no real
exposition of historical variations in storms, storminess and associated
coastal evolution in the face of such extreme events.
Barry D. Keim, Robert A. Muller, Gregory W. Stone,
Spatial and temporal variability of coastal storms in the North
Atlantic Basin, Marine Geology 210 (2004) 7– 15.
Abstract: Over the past three to four decades, there has been a growing awareness of the important controls exerted by large-scale
meteorological events on coastal systems. For example, definitive links are being established between short-term (timescales
of 5–10 years) beach dynamics and storm frequency. This paper assesses temporal variability of coastal storms (both tropical
and extratropical) and the wave climatology in the North Atlantic Basin (NAB), including the Gulf of Mexico. With both
storm types, the empirical record shows decadal scale variability, but neither demonstrates highly significant trends that can
be linked conclusively to natural or anthropogenic factors. Tropical storm frequencies have declined over the past two or
three decades, which is perhaps related to recent intense and prolonged El Nin˜os. Some forecasts predict higher frequencies
of tropical storms like that experienced from the 1920s to the 1960s to occur in coming decades. Results from general
circulation models (GCMs) suggest that overall frequencies of tropical storms could decrease slightly, but that there is
potential for the generation of more intense hurricanes. These data have important implications for the short-term evolution of
coastal systems.
There is strong suggestion that extratropical systems have declined overall over the past 50–100 years, but that there is an
increase in frequency of very powerful storms, especially at higher latitudes. Both ENSO and the North Atlantic Oscillation
(NAO) are shown to have associations with frequencies and tracking of these systems. These empirical results are in general
agreement with GCM forecasts under global warming scenarios. Analyses of wave climatology in the NAB show that the last
two to three decades have been rougher at high latitudes than several decades prior, but this more recent sea state is similar to
conditions from about 100 years ago. The recent roughness at sea seems to be related to high NAO index values, which are
also expected to increase with global warming. Thus, when coupled to an anticipated continued rise in global sea level, this
trend will likely result in increasing loss of sediment from the beach-nearshore system resulting in widespread coastal
erosion.
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Gregory
W. Stone, Baozhu Liu, David A. Pepper, Ping Wang, The importance of
extratropical and tropical cyclones on the short-term evolution of
barrier islands along the northern Gulf of Mexico, USA, Marine Geology
210 (2004) 63–78.
Abstract: STONE,
Data are presented indicating the complexity and highly variable response
of beaches to cold front passages along the northern Gulf of Mexico,
in addition to the impacts of tropical cyclones and winter storms. Within
the past decade, an increase in the frequency of tropical storms and
hurricanes impacting the northern Gulf has dramatically altered the long-term
equilibrium of a large portion of this coast. A time series of net sediment
flux for subaerial and nearshore environments has been established for
a section of this coast in Florida, and to a lesser extent, Mississippi.
The data incorporate the morphological signature of six tropical storms/hurricanes
and more than 200 frontal passages. Data indicate that (1) barrier islands
can conserve mass during catastrophic hurricanes (e.g., Hurricane Opal,
a strong category 4 hurricane near landfall); (2) less severe hurricanes
and tropical storms can promote rapid dune aggradation and can contribute
sediment to the entire barrier system; (3) cold fronts play a critical
role in the poststorm adjustment of the barrier by deflating the subaerial
portion of the overwash terrace and eroding its marginal lobe along the
bayside beach through locally generated, high frequency, steep waves;
and (4) barrier systems along the northern Gulf do not necessarily enter
an immediate poststorm recovery phase, although nested in sediment-rich
nearshore environments. While high wave energy conditions associated
with cold fronts play an integral role in the evolution and maintenance
of barriers along the northern Gulf, these events are more effective
in reworking sediment after the occurrence of extreme events such as
hurricanes. This relationship is even more apparent during the clustering
of tropical cyclones. It is anticipated that these findings will have
important implications for the longer term evolution of barrier systems
in midlatitude, microtidal settings where the clustering of storms is
apparent, and winter storms are significant in intensity and frequency
along the coast.
Gregory
W. Stone, David A. Pepper, Jingping Xu and Xiongping Zhang, Ship Shoal
as a Prospective Borrow Site for Barrier Island Restoration, Coastal
South-Central Louisiana, USA: Numerical Wave Modeling and Field Measurements
of Hydrodynamics and Sediment Transport, Journal of Coastal Research,
Vol. 20, No. 1, 70–88, 2004.
Abstract: STONE,
G.W.; PEPPER, D.A.; XU, J., and ZHANG, X., 2004. Ship Shoal as a prospective
borrow site for barrier island restoration, coastal south-central Louisiana,
USA: numerical wave modeling and field measurements of hydrodynamics
and sediment transport. Journal of Coastal Research, 20(1), 70–89. West
Palm Beach (Florida), ISSN 0749- 0208. Ship Shoal, a transgressive sand
body located at the 10 m isobath off south-central Louisiana, is deemed
a potential sand source for restoration along the rapidly eroding Isles
Dernieres barrier chain and possibly other sites in Louisiana. Through
numerical wave modeling we evaluate the potential response of mining
Ship Shoal on the wave field. During severe and strong storms, waves
break seaward of the western flank of Ship Shoal. Therefore, removal
of Ship Shoal (approximately 1.1 billion m3) causes a maximum increase
of the significant wave height by 90%–100% and 40%–50% over the shoal
and directly adjacent to the lee of the complex for two strong storm
scenarios. During weak storms and fair weather conditions, waves do not
break over Ship Shoal. The degree of increase in significant wave height
due to shoal removal is considerably smaller, only 10%–20% on the west
part of the shoal. Within the context of increasing nearshore wave energy
levels, removal of the shoal is not significant enough to cause increased
erosion along the Isles Dernieres. Wave approach direction exerts significant
control on the wave climate leeward of Ship Shoal for stronger storms,
but not weak storms or fairweather. Instrumentation deployed at the shoal
allowed comparison of measured wave heights with numerically derived
wave heights using STWAVE. Correlation coefficients are high in virtually
all comparisons indicating the capability of the model to simulate wave
behavior satisfactorily at the shoal. Directional waves, currents and
sediment transport were measured during winter storms associated with
frontal passages using three bottom-mounted arrays deployed on the seaward
and landward sides of Ship Shoal (November, 1998–January, 1999). Episodic
increases in wave height, mean and oscillatory current speed, shear velocity,
and sediment transport rates, associated with recurrent cold front passages,
were measured. Dissipation mechanisms included both breaking and bottom
friction due to variable depths across the shoal crest and variable wave
amplitudes during storms and fair-weather. Arctic surge fronts were associated
with southerly storm waves, and southwesterly to westerly currents and
sediment transport. Migrating cyclonic fronts generated northerly swell
that transformed into southerly sea, and currents and sediment transport
that were southeasterly overall. Waves were 36% higher and 9% longer
on the seaward side of the shoal, whereas mean currents were 10% stronger
landward, where they were directed onshore, in contrast to the offshore
site, where seaward currents predominated. Sediment transport initiated
by cold fronts was generally directed southeasterly to southwesterly
at the offshore site, and southerly to westerly at the nearshore site.
The data suggest that both cold fronts and the shoal, exert significant
influences on regional hydrodynamics and sediment transport.
High
Resolution Morphodynamics and Sedimentary Evolution of Estuaries (Coastal
Systems and Continental Margins), Duncan M. FitzGerald (Editor), Jasper
Knight (Editor), Chapter 12, Chapter 13, ISBN: 1402032951.
Editorial
Reviews: Estuaries occur along many of the world’s coastlines
irrespective of geologic setting, energy regime, and depositional environment.
They represent the interface between fluvial, coastal and marine environments
and they contain the sedimentary record of geological changes among
these systems. However, detailed case studies on the morphodynamics
and sedimentary evolution of different estuarine environments are notably
lacking. This book focuses on the use of high-resolution geophysical
techniques, field observations and modeling to investigate the morphodynamics
of estuaries on both glaciated and non-glaciated coasts and on different
time scales. Papers in this book offer a new approach to nearshore
and estuary studies, with an emphasis on multidisciplinary techniques
and data integration. Results of these studies have important implications
for estuary resource management and shoreline stability. This book
will be of interest to sedimentologists, coastal and Quaternary geologists,
environmental scientists, and coastal managers.
Gregory W.
Stone, B. Prasad Kumar, A. Sheremet and Dana Watzke, Complex Morpho-Hydrodynamic
Response of Estuaries and Bays to Winter Storms: North-Central Gulf of
Mexico, USA, High Resolution Morphodynamics and Sedimentary Evolution
of Estuaries, 243-267.
Harry H. Roberts,
Nan D. Walker, Alexandru Sheremet and Gregory W. Stone, Effects of Cold
Fronts on Bayhead Delta Development: Atchafalaya Bay, Louisiana, USA.
High Resolution Morphodynamics and Sedimentary Evolution of Estuaries,
269-298.
A.
Sheremet, A. and G. W. Stone, Observations of nearshore wave dissipation
over
muddy sea beds, J. Geophys. Res., 108(C11), 3357, doi:10.1029/2003JC001885,
2003.
Abstract: Wave
Propagation on the Louisiana inner shelf is studied using concurrent
measurements at two shallow water ocean observatory sites, in sedimentary
environments dominated by mud at one site, and sand at the other. Contrary
to the widely accepted hypothesis that mud-induced wave dissipation is
important only for long waves, observations show significant damping
of high-frequency, short waves, which interact weakly with the bottom.
The mecanism of short wave dissipation is not understood. Numerical Simulations
show that other dissipative processes such as refraction, or depth-limited
breaking, do not account for the magnitude of the observed effects. Independent
observations of strong sediment re-working during storms suggest that
these effects are related to sediment resuspension.
A.
Sheremet, A., J. M. Kaihatu, G.W. Stone and X.P. Zhang, Wave Evolution
in Cohesive
Sedimentary Environments: Open Problems, GCAGS/GCSSEPM Transactions,
765-771, Volume 53, 2003.
Abstract: Wave-current
interaction with cohesive sediment is a complex and not fully resolved
problem. Contrary to the widely accepted hypothesis that mud-induced
wave dissipation is important only for long waves, observations show
significant damping of high frequency, short waves, which interact weakly
with the bottom. The mechanism of short wave dissipation is not understood.
Numerical simulations show that other dissipative processes such as refraction,
or depthlimited breaking, do not account for the magnitude of the observed
effects. Independent observations of strong sediment reworking during
storms suggest that these effects are related to sediment resuspension
processes.
New wave-current and turbidity measurements made using the WAVCIS (wavcis.csi.lsu.edu)
ocean observing array offshore coastal Louisiana in the northern Gulf
of Mexico suggest that sediment concentration distribution in the water
column responds fast and varies considerably as a function of wave energy.
Cohesive sediment is resuspended by waves, reaching an almost constant
concentration throughout the water column in high energy states, and
resettles to form thick bottom fluid mud layer (low energy states). This
effect has been observed before (Allison et al. 2000), but at a much
coarser time resolution. The formation of the high-turbidity bottom layer
is associated with a marked decrease in both swell and sea energy, suggesting
that it might play a role in observed short wave dissipation.
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Sheremet,
A. and G. W. Stone, Wave Dissipation Due to Heterogeneous Sediments
on the Inner Louisiana Shelf, Proceedings of Coastal Sediments'03,
Clearwater Beach, Florida, USA, 120-121, 2003.
Abstract: The
effects of cohesive sedimentary environments on nearshore wave evolution
are studied comparing parallel in situ observations at two locations
along the West Louisiana coast. The sites are located near the 5 m isobath,
and subject to nearly identical atmospheric and offshore sea conditions,
but are characterized by different sedimentary environments, one dominated
by sand, the other by mud.
Over the muddy seabed, wave dissipation is observed across the spectrum.
Strong damping of the high frequency sea band (which interacts weakly
with the bottom) suggests that a different dissipation mechanism than
bottom friction becomes active during a storm, possibly increased viscosity
due to resuspended sediment.
Existing wave models have largely been developed for sandy environments
and do not distinguish between the different sedimentary fabrics. Preliminary
numerical simulations reproduce wave evolution in the sandy environment
fairly well, but overestimate wave energy in the case of the muddy environment.
Stone,
G. W., A. Sheremet, X.P.Zhang, Q. He, B. Liu and B. Strong, Landfall
of Two Tropical System Seven Days Apart Along Southcentral Louisiana,
USA, Proceedings of Coastal Sediments'03, Clearwater Beach, Florida,
USA, 333-334, 2003.
Abstract: In
2002 and for the first time in recorded history, coastal Louisiana was
struck by two tropical cyclones only seven days apart. Tropical Storm
Isidore made landfall along the Caminada Moreau Headland on September
26 and Hurricane Lili came ashore near Marsh Island on October 3. Both
storms were unique in many ways; Isidore although loosely organized in
the Gulf, developed sea state that affected beaches all along the northern
Gulf of Mexico (GOM). The strength of Lili generated waves in excess
of ~14 m while a Category 4 storm in the central GOM. The storms' trajectories
brought both close to several ocean observing stations (WAVCIS---Wave-Current-Surge
Information System) that subsequently provided comprehensive and unique
data sets; one station (CSI 3) was located in the eye wall of Lili as
the hurricane approached landfall. Here we present selected aspects of
the wave and surge evolution with a focus on Hurricane Lili. The morphological
impacts along the coast are summarized. One particularly interesting
phenomenon observed during Hurricane Lili, was the important role played
by the muddy inner shelf off western Louisiana in dissipating wave energy
and inhibiting the development of the storm surge field on the shelf
and along the coast. Theoretical estimates of surge significantly over
predict surge when data are compared to in situ observations obtained
from the WAVCIS array.
Stone,
G.W., X.P. Zhang, W. Gibson and R.A. Fredericks, New Wave-current Online
Information System for Oil Spill Contingency Planning (WAVCIS), Proceedings
of 24th Arctic and Marine Oilspill Program Technical Seminar 2001,
Edmonton, Alberta, CANADA, 401-425, 2001.
Abstract: An
online oceanographic and meteorological observing system has been developed
and is being implemented off the Louisiana coast to provide critical
information during offshore emergencies including oil spills. The program,
WAVCIS (WAVe Current Information System), provides wave information (sea
state) including wave height, period, direction of propagation, water
level, surge, water column velocity profiles, and meteorological conditions
on a near real time basis. Information of this sort does not exist for
an area approximating 135,000 km2 off Louisiana’s coast. WAVCIS
involves offshore deployment of instrumentation around the entire state
in order to provide near real time data describing sea state, current
velocity and meteorological conditions. Information from each station
is transmitted via cellular satellite telephone to a base station at
Louisiana State University where it undergoes quality control, post-processing
and archiving in an online database. The information is then made available
on the World Wide Web and is accessible to computers with an Internet
connection and web browser. Various data displays are available for the
near real time information, as well as a specified time history for archived
data.
Stone,
G. W., X.P. Zhang, J. Li and A. Sheremet, Coastal Observing Systems:
Key to the Future of Coastal Dynamics Investigations, GCAGS/GCSSEPM
Transactions, 783-799, Volume 53, 2003.
Abstract: Several
new local, regional and national initiatives involving distributed coastal
ocean observing systems are being implemented around the U.S. The primary
goal of these efforts is to raise, to a new plateau, the understanding
of, and the ability to predict, critical processes that operate in the
coastal seas and estuaries of the southeast. Improved models of these
physical, chemical and biologic phenomena will permit more accurate prediction
of coastal hazards, threats to human health, and short and long term
changes in coastal ecosystems. These predictions will guide coastal stewardship,
enable planning for extreme events, facilitate safe and efficient maritime
operations, and support coastal military security and homeland security.
Here we present a new observing system, WAVCIS, developed off the Louisiana
coast and present unique data sets measured during two tropical cyclones,
TS Isidore and H Lili, both of which made landfall along coastal Louisiana
in 2002. Implementation and maintenance of these coastal observatories
is providing unique opportunities for scientists working on the coast
to investigate new phenomena pertaining to high energy events and resultant
hydrodynamic and geological response.
Strong,
B., B. Brumley, E.A. Terray and G.W. Stone, The Performance of ADCP-Derived
Directional Wave Spectra and comparison with Other Independent Measurements,
Proceedings of 2000 MTS/IEEE Oceans Conference, Providence, RI, USA,1195-1203,
2000.
Abstract: The
measurement of waves, and in particular their direction, has been one
of the more difficult problems in observational coastal engineering and
oceanography. The need also to measure currents frequently confronts
the practitioner with the necessity of deploying two instrument systems,
such as a buoy and an ADCP. Because, in principle, ADCPs combine the
required functionality to measure both waves and currents in a single
compact package, there has been considerable interest in exploring their
efficacy as a wave sensor. The pioneering work of Pinkel and Smith [1]
and Krogstad et al. [2] demonstrated that a Doppler sonar using horizontally-projected
beams could provide a high quality measurement of wave direction (see
also [3]). However, because this approach does not yield the depth distribution
of currents, we have pursued the use of upward-looking ADCPs employing
a conventional “Janus” 4-beam configuration to measure both
waves and currents. (Terray et al., [4,5,7], and Gordon et al., [6]).
While these earlier contributions reported on various aspects of the
problem, they were not comprehensive, and contained little comparison
data to assess the performance of the ADCP against commonly used wave
direction sensors, such as heave-pitch-roll buoys and pressurevelocity
(PUV) triplets.
Over the past two years we have undertaken, in collaboration with a number
of investigators worldwide, an aggressive program to validate the performance
of conventional upward-looking ADCPs for measuring waves by means of
field comparisons with traditional wave sensors. This article is a progress
report on these efforts.
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Strong,
B., B. Brumley, G.W. Stone and X.P. Zhang, The Application of the Doppler
Shifted Dispersion Relationship to Hurricane Wave Data from an ADCP
Directional Wave Gauge and Co-Located Pressure Sensor, Proceedings
of IEEE 7th Working Conference on Current Measurement Technology 2003,
San Diego, CA, USA.
Abstract: Waves
from hurricanes Lili and Isidore were measured using an ADCP directional
wave gauge and an independent pressure sensor. The array is part of Louisiana
State University’s WAVCIS ocean observing system located in the
northern Gulf of Mexico. Data demonstrate the effects of strong storm
surge induced currents on wavenumber. We investigate the effect of Doppler
shifting of wavenumber to wave height estimates and wave direction. Comparison
data are used from direct surface measurement and a co-located PUV sensor
to show the extent of errors introduced by currents. The importance of
accurately measuring wave heights during extreme events underscores the
value of addressing significant error sources associated with storm surge.
Velardo,
B.M., S.J. Bentley and G. W. Stone, Impacts of Tropical Systems on
the Sedimentary Fabric of the Mississippi Sound, GCAGS/GCSSEPM Transactions,
820-827, Volume 53, 2003.
Abstract: A
geologic investigation was conducted in Mississippi Sound to determine
patterns of estuarine sedimentation during the late Holocene. Major sources
of sediment include the Pearl River, Mobile River, and transgressive
barrier island sands. This sediment is delivered and reworked by episodic
tropical systems and winter storms. Below fair-weather wave base, major
storm events are recorded as sandy event layers in a muddy matrix.
Gravity and box cores were analyzed using radioisotope geochronology
(210Pb, 7Be, and 137Cs), x-radiography, granulometry, and a multi-sensor
core logger. Gravity core analysis reveals 5-8 event layers in ~3 m gravity
cores. Our 210Pb/137Cs observations indicate accumulation rates of 0.3-0.5
cm y-1. Wave data collected from Tropical Storm Isidore and Hurricane
Lili indicate intense reworking of sediment on the shelf and moderate
reworking of sediment in the Sound. Higher near-bottom orbital velocities
were calculated for Tropical Storm Isidore than Hurricane Lili. Box cores
collected after the storms contained a variable muddy event layer up
to ~10 cm thick on the shelf and < 5 cm thick within the Sound. In
contrast, event layers produced by major hurricanes (such as Camille,
1969), reach thicknesses exceeding 10 cm. Because of post depositional
mixing, only event layers thicker than 5 cm in the Sound and ~10 cm on
the shelf have significant preservation potential. Thus, data indicate
that only major hurricanes create preservable event layers in the Mississippi
Sound and represent 8-26% of the sediment column deposited in the last
600-1000 years.
Zhang,
X.P., Design and Implementation of an Ocean Observing System: WAVCIS
(Wave-Current-Surge Information System and its Application to the Louisiana
Coast, A Dissertation Submitted to the Graduate Faculty of the Louisiana
State University and Agricultural and Mechanical College in partial
fulfillment of the requirements for the degree of Doctor of Philosophy
in The Department of Geography and Anthropology , 2003 .
Abstract: WAVCIS
(Wave-Current-Surge Information System for Coastal Louisiana) was designed
to measure meteorological and hydrodynamic phenomena along the Louisiana
coast. The information measured includes waves, currents, water depth,
surge, turbidity, salinity and meteorological conditions. WAVCIS collects
data and transfers it back to the data processing laboratory at LSU through
wireless communication. The data undergo post-processing and archiving.
Users can access the real-time or archived information through the World
Wide Web.
This dissertation utilized the information provided by WAVCIS stations
and NDBC buoys during Hurricane Lili and Tropical Storm to examine temporal
and spatial variations of storm induced meteorological and oceanographic
dynamics. The results show that waves during Hurricane Lili ranged from
1.8 meters in Terrebonne Bay, 6.2 meters offshore at a depth of 20 meters
and 12 meters in Central Gulf of Mexico. The track of Hurricane Lili
passed over CSI 3 where the peak in significant wave height reached 2.7
meters. The maximum current speeds near sea surface and near bottom generated
by Hurricane Lili were 1.8 m/s and 1.1 m/s respectively. During the peak
of the storm the water column was dominated by a northwest current. Currents
were initially impacted by the storms when they encountered the continental
shelf. Within approximately twice the radius of maximum wind (Rw) during
Hurricane Lili, the current measured by an ADCP (Acoustic Doppler Current
Profiler) exhibited an almost perfect logarithmic profile extending to
near the sea surface from the bottom. The range of the estimated shear
velocity during the passage of Hurricane Lili was 5-12.5 cm/s. Storm
wave energy dumping occurred along the muddy shelf in western Louisiana.
Waves generated by Hurricane Lili and Tropical Storm Isidore showed considerable
difference in both time and space domains. Wave spectra for Tropical
Storm Isidore showed distinct peaks for both swell and wind-driven waves.
The wave spectra for Hurricane Lili demonstrated complicated multiple
peaks throughout the entire frequency domain. Swells with longer periods
tended to survive longer in the space domain and shorter in the time
domain. Hurricane Lili generated 1.4 meters of storm surge at CSI 3.
The surges appeared lower than modeled estimates.
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