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ASSESSING SHORT-TERM SEDIMENT ACCRETION RATES AND
HYDROLOGICAL INFLUENCES ON A MICROTIDAL ESTUARINE WETLAND:
MUSTANG ISLAND, TX
By
Melinda Martinez
November 2015
A Thesis Paper Submitted
In Partial Fulfillment of the
Requirements for the Degree of
MASTER OF SCIENCE
Texas A&M University-Corpus Christi
Environmental Science Program
Corpus Christi, Texas
Approved: ___________________________________ Date: ___________
Dr. James C. Gibeaut, Chair of Committee
___________________________________
Dr. Mark Besonen, Member
___________________________________
Dr. Michael Starek, Member
___________________________________
Dr. Richard Coffin, Department Chair
Chairperson, Department of Physical and Environmental Sciences
Format: Estuaries and Coasts
ii
Abstract As sea level rises there has been a growing concern whether salt marsh wetlands
can withstand an accelerated rise in sea level by vertically accreting. Sediment accretion
is a natural process that changes the elevation of the marsh surface relative to sea level.
For a wetland to persist in the long-term, its accretion rate must at least match the rate of
relative sea level rise. This study describes sedimentation rates in the estuarine wetlands
located on Mustang Island, TX, a sandy barrier island. Sedimentation rates were
measured bi-weekly from June 2014 to July 2015 using sediment plates and erosion pins,
and over periods of 2.4 to 3.3 years (2012-2014/2015) using horizon marker techniques.
Water level loggers were used to assess hydrological controls on bi-weekly sedimentation
patterns. Shallow cores (~15 cm) were collected from the horizon marker plots in August
2014 and July 2015. Vertical accretion rates were compared across different timescales
including decadal rates determined using 137
Cs from a previous study on Mustang Island,
TX.
Results indicated sediment accretion across the study area was not significantly
influenced by hydrological patterns, with the exception of low marsh environments near
tidal creeks (r2=0.52, p < 0.1). The most important factor in determining sediment
deposition on sediment plates located near the main tidal creek was the number of
flooding events, suggesting that deposition increases as frequency of flooding events
increases. The total accumulation deposited on plates was dominated by inorganic
sediments, suggesting there is a limit of detrital organic matter contribution for this area.
Average vertical accretion using horizon markers was 8.15 ± 5.21 mm yr-1
in
upland environments; 4.51 ± 5.21 mm yr-1
in high marsh environments; 3.36 ± 3.57 mm
yr-1
in high flat environments; 11.92 ± 9.73 mm yr-1
in low marsh environments; and 1.88
iii
± 2.54 mm yr-1
in low flat environments. There was a significant difference in vertical
accretion rates between both horizon markers and erosion pins, which provide annual-
scale accretion rates, when compared to 137
Cs, which provide decadal-scale accretion
rates (p < 0.1). On average annual vertical accretion rates were 2.8 times higher than
decadal rates. Differences between annual and decadal accretion rates are mostly
attributed to shallow sediment compaction within the top 3 cm of the wetland surface.
Variation in wetland vertical accretion rates increased significantly going from decadal (±
0.41 mm) to annual (± 2.87 mm) to annualized biweekly rates (± 9.60 mm).
Annual-scale accretion rates measured using horizon markers in low marsh and
upland environments appear to be keeping up with relative sea level rise (RSLR), which
is 5.27 ± 0.48 mm yr-1
as measured since the 1950’s at a nearby tide gauge. However
horizon marker vertical accretion rates in tidal flats and high marsh environments are not
sufficient to overcome sea level rise. Vertical accretion rates were positively correlated
with organic and inorganic accretion for all horizon markers (p < 0.1); however, the
relative contribution of organic matter decreases as inorganic matter increases. Our
findings anticipate environmental shifts in habitats with accretion rates below RSLR.
Furthermore, vertical accretion was dominated by inorganic matter, making the wetlands
reliant on constant wind and episodic storms to transport sediment to the area.
Importantly, these data suggest that storm-induced sedimentation acts to stabilize coastal
wetlands and helps certain environments cope with RSLR, but is not sufficient to prevent
shifts in the relative composition of the wetland.
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Table of Contents
Abstract ............................................................................................................................... ii
Table of Contents ............................................................................................................... iv
List of Figures .................................................................................................................... vi
List of Tables ................................................................................................................... viii
Acknowledgments.............................................................................................................. ix
Chapter 1: Introduction ........................................................................................................1
Importance of Texas Estuarine Wetlands ........................................................................1
Wetland Sedimentation: General Overview ....................................................................2
Wetlands Response to Sea Level Rise .............................................................................4
Study Area .......................................................................................................................9
Environments .............................................................................................................12
General Purpose .............................................................................................................15
Chapter 2: Assessing Sediment Accretion Rates ...............................................................18
Introduction ....................................................................................................................18
Material and Methods ....................................................................................................20
Sedimentation measurements.....................................................................................20
Sediment Characterization .........................................................................................23
Results ............................................................................................................................25
Vertical Accretion Rates ............................................................................................25
Grain Size Analysis....................................................................................................39
Organic Matter Analysis ............................................................................................41
Discussion ......................................................................................................................47
Comparing Vertical Accretion Rates .........................................................................47
Focusing on Erosion Pins...........................................................................................52
Comparing Short-Term Accretion Rates ...................................................................52
Correlation to Elevation .............................................................................................53
Relative Contribution of Organic and Inorganic Matter ............................................54
Grain Size...................................................................................................................59
Implications for Sea-Level Rise and Marsh Loss ......................................................59
Conclusion .....................................................................................................................62
Chapter 3: Assessing Hydrological Influences ..................................................................63
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Introduction ....................................................................................................................63
Materials and Methods ...................................................................................................64
Water Level Loggers..................................................................................................64
Sediment Plates ..........................................................................................................72
Sediment Characterization .........................................................................................74
Results ............................................................................................................................74
Hydroperiod ...............................................................................................................74
Grain Size Analysis....................................................................................................82
Discussion ......................................................................................................................85
Influence of Hydroperiod on Deposition ...................................................................86
Contribution of Organic and Inorganic Matter Associated with Hydroperiod ..........88
Grain Size...................................................................................................................90
Sediment Plate Technique ..........................................................................................93
Conclusion .....................................................................................................................94
References ..........................................................................................................................95
vi
List of Figures Fig. 1 Conceptual model of salt marsh responses to sea level rise in terms of sediment supply and
terrestrial slope after Brinson et al. (1995). __________________________________________ 7
Fig. 2 Environmental state changes from upland to open water after Brinson et al. (1995)._____ 8
Fig. 3 Regional map of study area (a), aerial imagery of study site (b). ____________________ 9
Fig. 4 High marsh environment dominated by Monanthochloe litoralis with sparse Salicornia
spp. ________________________________________________________________________ 13
Fig. 5 Transition of environments from high marsh to upland dominated by Spartina patens. _ 14
Fig. 6 Less frequently inundated low marsh environment dominated by Avicennia germinans and
Batis maritima. _______________________________________________________________ 14
Fig. 7 Tidal flats consisting mostly of algal mats in low tidal flat environments. ____________ 15
Fig. 8 Conceptual diagram showing distribution of field methods used in this study. ________ 17
Fig. 9 Creating a horizon marker with a mixture of kaolinite and red brick dust in March 2012. 21
Fig. 10 Horizon marker distribution created in March 2012. ___________________________ 21
Fig. 11 Aerial imagery showing the distribution of horizon marker plots cored in August 2014
and July 2015. _______________________________________________________________ 25
Fig. 12 Sample core from a horizon marker plot in a high marsh area showing sediment accretion
accumulated from March 2012 to August 2014. Photos from left to right taken from different
angles. _____________________________________________________________________ 26
Fig. 13 Plot showing Accretion Rate for each Environment separated by Time Scale. ________ 28
Fig. 14 Results from ANOVA comparing different Time Scales within specific levels of
Environment. a) High Marsh, b) High Flat, c) Low Marsh, d) Low Flat. Different number of
asterisks between levels indicate significance (p < 0.1). Same number of asterisks between levels
indicate no significance (p > 0.1). ________________________________________________ 30
Fig. 15 Results from ANOVA comparing different Environments within specific Time Scales
using Horizon Markers only; a) Vertical accretion rates for the period of March 2012-August
2014, b) Vertical accretion rates for the period of March 2012-July 2015. Different number of
asterisks between levels indicate significance (p < 0.1). Same number of asterisks between levels
indicate no significance (p > 0.1). ________________________________________________ 31
Fig. 16 Erosion pin heights in all environments throughout the study. ____________________ 33
Fig. 17 Scatterplot showing relationship between accretion and elevation using horizon markers
for the period of Marsh 2012 to August 2014. Plot on the left shows accretions from all
environments. Plot on the right shows accretion data for salt marsh only, low marsh and high
marsh environments. Error bars indicate standard error. _______________________________ 36
Fig. 18 Scatterplot showing relationship between accretion and elevation using horizon markers
for the period of Marsh 2012 to August 2015. Plot on the left shows accretions from all
environments. Plot on the right shows accretion data for salt marsh only, low marsh and high
marsh environments. Error bars indicate standard error. _______________________________ 37
Fig. 19 Scatterplot showing relationship between accretion and elevation using 137
Cs
(Radosavljevic 2011). Plot on the left shows accretions from all environments. Plot on the right
shows accretion data for salt marsh only, low marsh and high marsh environments. Error bars
indicate standard deviation. _____________________________________________________ 38
Fig. 20 Textural classification of sediment samples from horizon markers. a) Horizon markers
cored in August 2014, b) Horizon markers cored in July 2015. _________________________ 40
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Fig. 21 Relationship between percent organic matter and Environment for both Time Scales using
horizon markers. _____________________________________________________________ 41
Fig. 22 Relative contributions of organic and inorganic matter to accretion from horizon markers
cored in August 2014 for the period of March 2012 to August 2014. Organic matter contributions
include porosity and water content. Rate of sea level rise at Rockport, TX is also shown by the
light grey area. _______________________________________________________________ 43
Fig. 23 Relative contributions of organic and inorganic matter to accretion from horizon markers
cored in July 2015 for the period of March 2012 to July 2015. Organic matter contributions
include porosity and water content. Rate of sea level rise at Rockport, TX is also shown by the
light grey area. _______________________________________________________________ 44
Fig. 24 Relative contributions of organic and inorganic matter to accretion from 137
Cs cores from
previous study (Radosavljevic 2011). Organic matter contributions includes porosity and water
content. Rate of sea level rise at Rockport, TX is also shown by the light grey area. _________ 45
Fig. 25 Relationship between vertical accretion rates and both organic and inorganic accretion
rates from combined (HM2014 and HM2015) horizon markers (annual time scale) and 137
Cs
(decadal time scale). a) organic accretion b) inorganic accretion c) organic versus inorganic d)
legend for all three graphs. Note: These graphs do not take into account porosity and water
content. _____________________________________________________________________ 46
Fig. 26 Organic and inorganic contributions of HM2014 (top) and HM2015 (bottom) excluding
pore and water space. __________________________________________________________ 51
Fig. 27 Comparison of the relationship of vertical accretion with organic and inorganic accretion
in the present (MUI Horizon Marker) and previous study (MUI 137
Cs) for this area as well as
other localities a) organic accretion, b) inorganic accretion, c) organic versus inorganic accretion,
d) legend for all plots indicating locations. Data of other studies are from Turner et al. (2002) for
Upper Texas coast, Louisiana, and Rhode Island, and data for Texas (Aransas National Wildlife
Refuge), San Bernard, Mississippi, and Florida Keys are from Callaway et al. (1997). _______ 56
Fig. 28 A comparison of the relationship between organic accretion and inorganic accretion. a)
This study combined with Radosavljevic (2011), b) Louisiana studies from Fig. 20. Shaded
regions indicate 95% confidence interval. This figure is the similar to Fig. 20c except the
geographic localities are plotted separately for visualization. ___________________________ 58
Fig. 29 Range of elevations for each environment. Low flat elevations vary in this area, but are
generally considered to be at lower elevations than low marsh environments. ______________ 60
Fig. 30 Map showing wetland transitions from 1950’s, 1979, and 2002-04 for Mustang Island and
Harbor Island (White et al. 2006). Study area in Mustang Island is highlighted by the red box. 61
Fig. 31 Distribution of water levels loggers on Mustang Island, TX. _____________________ 65
Fig. 32 OTT Orpheus mini water level logger suspension diagram (Source: OTT Orpheus Mini
2015). ______________________________________________________________________ 66
Fig. 33 HOBO Onset water level logger deployment diagram (Source: HOBO Onset 2015). __ 67
Fig. 34 Schematic of hydroperiod measurements at sediment plates using nearest water level
logger. _____________________________________________________________________ 71
Fig. 35 Example of how number of flooding events were counted. F1 indicates 1st count of
flooding event, and continues to F4, so in this example Number of Flooding Events = 4 (number
of time sediment plate was exposed after initial flooding event). ________________________ 71
viii
Fig. 36 Circular sediment plate modeled after Kleiss (1993). Diagram of sediment plate (left),
sediment plate example from low marsh environment after flooding event (right). __________ 72
Fig. 37 Sediment plate distribution on Mustang Island, TX. ____________________________ 73
Fig. 38 Relationship of sediment plate deposition with flooding duration in time and depth. a) all
sediment plates, b) only sediment plates that were flooded, c) all sediment plates with y-axis log
scaled, d) only flooded sediment plates with y-axis log-scaled. _________________________ 77
Fig. 39 Relationship of sediment plate deposition with number of flooding events (a) and duration
in time and depth (b) for plates in low marsh environments near the main tidal creek only. ___ 78
Fig. 40 Relationship between accumulation of both organic and inorganic matter with duration in
time and depth. Accumulation of matter does not take into account sediment porosity, density or
water content. ________________________________________________________________ 80
Fig. 41 Water level referenced to NAVD88 near main tidal creek, including sediment plate
elevations. Horizontal lines represent elevation of sediment plates on the marsh surface. _____ 81
Fig. 42 Sediment grain size for all sediment plates, excludes plates with bioturbation. a) grain size
classified by vegetation type, b) grain size classified by range of elevation. _______________ 83
Fig. 43 Sediment grain size for plates near the main tidal creek, excludes plates with bioturbation.
a) grain size classified by sediment plate ID, b) grain size classified by vegetation type. _____ 84
Fig. 44 Precipitation and wind direction and magnitude throughout the study period. Y-axis
represents precipitation in centimeters. Stick plot shows wind direction and magnitude (scaled
relatively to each other). Winds pointing north (90˚) indicate winds are coming from the south
headed north _________________________________________________________________ 87
Fig. 45 A comparison of the relationship between accumulation of both organic and inorganic
matter and duration of flooding (log10 scaled x-axis) in the present study, using sediment plates
near the main tidal creek, and in a study in Louisiana. ________________________________ 89
Fig. 46 Mean grain size analysis and skewness from Simms et al., (2006) and Radosavljevic,
(2011). _____________________________________________________________________ 92
Fig. 47 Mean grain size analysis and skewness for this study. __________________________ 93
List of Tables Table 1 Comparison of accretion rates using different time scales averaged by wetland
classifications. ................................................................................................................................ 27
Table 2 Average sediment accretion rates for P2014 and P2015 after removing poor quality
cores. .............................................................................................................................................. 35
Table 3 List of hurricanes, tropical storms depression since 1963 within 200 km of Mustang
Island (NOAA, 2014b)................................................................................................................... 49
ix
Acknowledgments
First and foremost, I would like to thank my committee members: Dr. James C.
Gibeaut, Dr. Michael Starek, and Dr. Mark Besonen for their insight and expertise
throughout my thesis project, especially my advisor, Dr. Gibeaut for providing me the
opportunity to work in the Coastal and Marine Geospatial Lab (CMGL). I would like to
thank everyone in the CMGL for their help and guidance, especially a huge thank you to
Marissa Dotson for helping me out in the field. I would also like to thank everyone who
helped me install water level loggers and carry heavy fence posts during the Texas heat in
July 2014, as part of the National Oceanic and Atmospheric Administration
Environmental Cooperative Science Center (NOAA ECSC) Field Campaign. I would like
to thank the NOAA ECSC, for not only supporting this project (NA11SEC4810001), but
providing me with several opportunities for training, networking, and travel to
conferences and working offshore on the E/V Nautilus. I would also like to thank Alan
Downey-Wall for all of his support throughout my graduate career and for going into the
field with me when no one else could, especially for his help in retrieving water level
loggers during the coldest times of the year. I would also like to thank Harte Research
Institute, especially Gail Sutton for allowing me to borrow the truck every other week,
and Mike Grubbs for helping me schedule vehicle use, and teaching me how to use power
tools. Lastly but not least, I would like to thank the many friends I have made here, and
my family for all of their never-ending support, inspiration, and encouragement. I have
learned so much as a graduate student and plan on building on the skills I have acquired
here throughout my career. Thank you!
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“There is no other case in nature, save in the coral reefs, where the adjustment of
organic relations to physical conditions is seen in such as beautiful way as the balance
between the growing marshes and the tidal streams by which they are at once nourished
and worn away.” (Shaler 1886)
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Chapter 1: Introduction
Importance of Texas Estuarine Wetlands
Wetlands areas are known to have high biological productivity and diversity, but
recently there has been an increase in awareness of the critical role coastal wetlands play
and the need to monitor the status and trend as sea level rises (White et al. 2006).
Effective management of the structure and functions of coastal wetlands is necessary to
protect wetlands’ many contributions to ecosystem goods and services. According to
Costanza et al. (1997) the value of tidal marsh wetlands worldwide is estimated around
$1.6 trillion per year from waste treatment, habitat and refuge, food production, raw
materials, and recreation values. Aesthetic appreciation and spiritual values are often
strong motivators for action, but the most difficult to assign monetary values. Salt
marshes also serve to maintain fisheries by boosting the production of economically
important fishery species such as shrimp, oysters, clams, and various commercial fish. In
the Gulf of Mexico, salt marshes account for as much as 66% of the shrimp and 25% of
the nation’s blue crab production (Barbier et al. 2010). In 2012, U.S. commercial and
recreational fishing industries in Texas generated about $4.2 billion in sales, employing
about 40,000 coastal residents (NOAA 2012). Salt marshes provide nursery grounds for
juvenile fish, shrimp, and shellfish because of the complex packed plant structure
inaccessible to larger fish. Salt marshes sequester millions of carbon annually generated
by biochemical activity, sedimentation, and biological productivity. Other benefits from
salt marshes include erosion control by providing sediment stabilization and soil retention
in vegetation root structure; water purification by providing nutrient uptake, retention,
and deposition; raw materials and foods generated by biological productivity and
2
diversity; and tourism, recreation, education, and research by providing a unique and
aesthetic landscape, and a suitable habitat for diverse fauna and flora (Costanza et al.
1997; Barbier et al. 2010).
The loss and degradation of wetlands can be attributed to indirect influences such
as population growth and economic development, and direct influences such as
infrastructure development, land conversion, water withdrawal, pollution, overharvesting
and overexploitation, and introduction of invasive species (Finlayson et al. 2005). The
effects of climate change, such as sea level rise as well as changes in hydrology and
temperature, will lead to reduction in services provided by wetlands which could result in
erosion of shores and habitat, altered tidal ranges in rivers and bays, changes in sediment
and nutrient transport, and increased coastal flooding (Finlayson et al. 2005). Wetlands
are highly valued due to their ability to protect the coast by providing a buffer against
these climate change impacts.
Wetland Sedimentation: General Overview
There is growing concern as to whether salt marsh wetlands can withstand the
accelerated rise in sea level by vertically accreting. There are two ways in which marshes
may be submerged, either sea level rises or the land subsides, or a combination of both.
Subsidence measurements focus on changing land surface elevation relative to a specific
datum. The term shallow subsidence, which is calculated as the difference between
vertical accretion and elevation change, is often differentiated from the term deep
subsidence, which includes additional compaction and biostatic processes (D.R. Cahoon
et al. 1995; Donald R. Cahoon et al. 2006). Shallow subsidence consists of subsurface
processes near the marsh surface, such as compaction, decomposition, and dewatering
3
(Donald R. Cahoon and Lynch 1997). Deep subsidence occurs in all marshes from
sinking of soil due to compaction and other geological processes, but can vary greatly
between different locations due to human influences. This is the case for marshes along
the Texas coast with higher deep subsidence rates near Galveston, TX (White et al.
2001). Deep subsidence rates have been measured as high as 70 mm yr-1
over the Saxet
Oil and Gas field in Corpus Christi, TX and 75 mm yr-1
in the Houston, TX area near the
heart of the “subsidence bowl” (Pulich et al. 1997). Natural compaction processes have
been accelerated in many areas due to withdrawal of subsurface fluids, such as water, oil,
and gas (White et al. 2001).
Subsidence can occur in conjunction with accretion. Although a marsh with high
sedimentation rates may build vertically, high rates of subsidence can create an accretion
deficit. The deficit is calculated by comparing measures of accretion or accumulation
with estimates of sea level rise or land subsidence (Reed and Cahoon 1993). Marshes can
build vertically to overcome the effects of sea level rise by mineral sediment deposition
and accumulation of plant roots and decaying plant material (organic matter), which are
controlled by hydrological processes (Reed and Cahoon 1992). Flooding patterns control
the delivery of sediment and oxygen content of the soil which influences the rate of
growth and decay of plants (Reed and Cahoon 1992; D.R. Cahoon 1997). Vegetation also
enhances sediment deposition by slowing down the current and trapping suspended
sediment. Accretion in marshes remote from riverine sources of sediment may occur
through resuspension of sediment from bay bottoms and deposition on adjacent marshes
(D. R. Cahoon and Reed 1995). Key factors affecting sedimentation include bioturbation,
4
current intensity, channel migration, vegetation cover, and location. Organic matter
accumulation is often more important than inorganic matter in deteriorating marshes.
Seasonal sedimentation patterns are associated with the passage of winter cold fronts
along the northwestern Gulf of Mexico coast (Reed 1989). Inorganic sediment can be
deposited when the marsh is flooded due to storm surge, but the amount of sediment
contribution varies (Reed 1989). During storms, washover fans serve as a source of
sediment, transporting sediments from the ocean side for eventual deposition in the
marshes.
Strong winds preceding a cold front also plays an important role across the marsh
causing water levels to rise by wave action, which in turn floods the marsh mobilizing the
sediment and depositing it on the surface. Winds after the cold front depress water levels
which allows the newly deposited sediments to drain and begin to consolidate (Reed
1989). Storms (cold fronts) and summer tropical cyclones (hurricanes) are often the main
mechanism for mobilizing sediment for marshes that are remote from a riverine sediment
source and help maintain marshes stable against sea-level rise effects (Stumpf 1983; Reed
1989; D. R. Cahoon and Reed 1995).
Wetlands Response to Sea Level Rise
The interaction between hydrodynamics and elevation create a shore-parallel
zonation of vegetation, which becomes increasingly complex due to the
micromorphology of the marsh surface. The salinity of the water controls the
composition of the vegetation and fauna, which help to characterize the marsh. Previous
studies have shown that species competition is also critically important in controlling the
salt marsh plant communities (Bertness 1991). The existence and type of estuarine
5
wetlands are closely controlled by their position in the tidal frame. In absence of human
development as sea level rises and the tidal frame shifts, wetlands generally follow a
pattern of either migrating over land or stalling at the terrestrial-marsh margin and either
prograding or eroding at the seaward margin as shown by Fig. 1 (Brinson et al. 1995).
These patterns are strongly influenced by the amount of sediment brought into the
system, the steepness of the slope from upland to open water, and the relative sea level
rise rate, which includes eustatic sea level rise plus subsidence rates (Fig. 1). Migration
overland can sometimes be halted by a steep slope or human infrastructure.
Brinson et al. (1995) described how disturbances to wetlands, such as sea level rise,
can alter the ecosystem and cause a change in state depending on the frequency and
degree of the disturbance (Fig. 2). The chronic and gradual change of sea level leads to
higher frequency and pulsing that ultimately changes ecosystem states (Brinson et al.
1995). Ecosystem states transform from one class to another if the hydrology and
sediments have been changed drastically. If not, the vegetation proceeding the
disturbance remains the same, as conceptualized by Fig. 2 (Brinson et al. 1995).
Brinson’s state changes can follow the transitions from upland to high marsh, high
marsh to low marsh, low marsh to subtidal environment, or subtidal environment to open
water. Each state is characterized by inundation frequency, sediment dynamics, pore
water salinities, plant communities, and species composition (Brinson et al. 1995). The
lower limit of the marsh, which is defined as the seaward margin, is regularly inundated
by salt water and consists of pioneer species such as Spartina alterniflora. At higher
elevations - mid-level salt marsh - the hydroperiod is less frequent, therefore a greater
diversity of plant species are able to colonize. Salt tolerant plant species do not occur in
6
non-saline environments because they are unable to compete with non-salt tolerant plant
species.
If the rise in sea level is not equivalent to vertical accretion of marsh sediments,
then there will be a gradual disintegration of coastal marshes due to increased inundation,
erosion, and saltwater intrusion (Mitsch and Gosselink 2000). Disturbance in the higher
elevated areas, such as the upland and high marsh areas, are mostly caused by saltwater
intrusion for prolonged periods of time causing non-salt tolerant plant species to die off
(Fig. 2). Disturbance in the lower elevation areas is mostly caused by redistribution of
sediments. The transition of a state could also be reversed for continuously prograding
marshes. The reversal of a state is the difference between prograding and eroding at the
seaward margin (Brinson et al. 1995).
Each state has self-maintained processes that resists change by accumulation of
organic and inorganic matter as a way to increase elevation to overcome relative sea-level
rise (Brinson et al. 1995). As the elevation increases by sediment accretion, the
hydroperiod and net sediment accretion are reduced, thus causing a change in state.
Changes in elevation can be due to vertical accretion or changes in the volume of soil
related to subsurface processes (D.R. Cahoon et al. 1995). Erosion and accretion can be
significant in some areas, therefore, vertical accretion rates on wetland surfaces may
offset sea level rise in areas of high accretion rates while in other areas erosion may
exacerbate wetland loss as sea level rises (Gibeaut et al. 2010). Wetland migration is
critical for areas where vertical and horizontal accretion rates are not sufficient to offset
sea level rise. A marsh is considered healthy if the marsh elevation increases at the same
rate as the sea-level rises and flooding patterns remain unchanged (D.R. Cahoon 1997).
7
In a deteriorating marsh, plant growth is reduced because of excessive flooding, and soil
volume cannot keep up causing the elevation to lag further from relative sea-level rise
which further increases plant stress and eventually the marsh becomes submerged (D.R.
Cahoon 1997).
Fig. 1 Conceptual model of salt marsh responses to sea level rise in terms of sediment supply and terrestrial
slope after Brinson et al. (1995).
10
This study seeks to investigate accretion rates at short, medium, and long-term
scales to determine the status of the marsh relative to local sea level rise. This study was
conducted on the bay side of the Texas barrier island known as Mustang Island (Fig. 3).
There have been many studies conducted on Mustang Island including the assessment of
medium-term vertical accretion rates determined from radiometric dating methods
(Radosavljevic 2011). Radosavljevic (2011) determined vertical accretion rates from 13
shallow sediment cores taken in high marsh, high flat, low marsh, and low flat
environments. The area is also near a deep set survey benchmark to reference elevation,
and has a continuously monitored elevation transect that runs from the middle of the
barrier island to the bay shoreline surveyed by a Trimble Total Station and Real Time
Kinematic Global Positioning System (RTK GPS). The location is considered the
Mustang Island Wetland Observatory by the Harte Research Institute for Gulf of Mexico
Studies due to the extensive research of the area.
Mustang Island is a bay mouth barrier island located along the southern portion of
the Texas Gulf Coast bound by Corpus Christi Bay, the Laguna Madre, and the Gulf of
Mexico. Mustang Island lies above the ancestral Nueces River valley and its tributaries,
and the Pleistocene surface beneath reaches depths as great as 38 m (Simms et al. 2006).
This suggests that sea level transgressed the area earlier than other Texas coastal
locations, thus making Mustang Island older than other modern barrier islands on the
Texas coast (Simms et al. 2006). The rise and fall of sea level during the Pleistocene
Epoch resulted in the formation of large sand bars along the coastline that developed into
barrier islands over time (Moulton and Jacob 2000). The Texas mainland shore, coastal
plain, beaches, barrier islands and peninsulas, river deltas, and bays and estuaries are all
11
products of alluvial sediments deposited during the Holocene, the last 10,000 years
(Moulton and Jacob 2000).
Texas barrier beaches are generally composed of well-sorted fine to very fine sand
(Morton 1988). Estuarine wetland soils can range from clay to sand, but fine sand
dominates most barrier island salt marshes in Texas. Winds strongly influence coastal
geoenvironments along the semi-arid Texas coast. Onshore southeasterly winds are
consistent during most of the year but are periodically directed offshore by strong
northerly winds associated with cold fronts during winter months (White et al. 1978;
Shideler 1984). Mustang Island is considered a high-profile barrier generally considered
older and more stable, which results in less material delivered to the backbarrier
environment due to the high amount of sediment trapped by the dunes (Simms et al.
2006).
Mustang Island lies in the Texas Coastal Bend at the approximate boundary where
precipitation exceeds evaporation to the north and evaporation exceeds precipitation to
the south (Montagna et al. 2007). Precipitation and evaporation are important for
sediment accretion and deposition due to their influence on vegetation and soil moisture.
There is a general climatic gradient southwestward along the Texas coast decreasing in
precipitation, sedimentation, distribution of wetlands, and subsidence, and increasing in
active dunes correlated with diminishing vegetation cover (White et al. 2001). The
arcuate shape of the Texas coast causes longshore current northeast to flow southwest
and longshore currents in the south to flow north, converging at the coastal bend.
Astronomical tides in this region of the Gulf of Mexico are generally considered
diurnal or mixed ranging from 45 to 60 cm; these tidal variations are even lower in the
12
bays (Morton and McGowen 1980). Tidal range on the Gulf side of Mustang Island is
0.60 m, while on the bay side of Mustang Island tidal range is about 0.10 m, although
tides in the bays can be wind-generated (White et al. 1978; Montagna et al. 2007). The
area is characterized as a microtidal wave-dominant coast subject to diurnal tides (Morton
1988). Mean significant wave height is 1.4 m while wave breaker heights along the Gulf
shore are generally less than 1.2 m with an average breaker height being slightly more
than 0.6 m (White et al. 1978; Gibeaut et al. 2008). Microtidal coasts are generally storm
dominant coasts because the energy and geological change during storms are far greater
than changes that occur by daily processes (Morton and McGowen 1980).
Microtidal marshes are more vulnerable to rapid sea level rise because the amount
of rise is a larger percentage of the tide range to which marshes are adjusted compared to
meso or macrotidal range settings. A rise of just 0.1 m in relative sea level along the
Texas coast can cause conversion of fringing low marshes and flats to open water and sea
grass beds, and usually dry high marshes and flats to usually wet low marshes and flats
(Stevenson et al. 1985; Gibeaut et al. 2003). Tide gauge records from Rockport, TX,
located near Mustang Island, indicate a relative mean sea-level rise rate of 5.27 ± 0.48
mm from 1937 to 2014 (NOAA 2014a). Land subsidence rates on the south Texas barrier
islands were calculated to be approximately 1 to 5 mm yr-1
(Montagna et al. 2007). In
general, areas with thicker and rapidly deposited Holocene sediment have a higher
compaction rate. The sediment deficit and low-lying gently sloped shores of much of
south Texas coast will cause relative sea-level rise to have a profound effect on coastal
habitats (Montagna et al. 2007).
Environments
High Marsh and Upland
13
High marsh environments vary in range from 0.2 – 0.8 m (NAVD88) well above
the mean high tide line therefore are rarely inundated by tides (Paine, White, Gibeaut, et
al. 2004). At lower elevations within the high marsh range, Monanthochloe litoralis
(shoregrass) is the dominant species commonly found growing in mats (Fig. 4).
Occasionally there is sparse Salicornia spp. (glasswort), but presence varies seasonally.
Other species commonly found in high marsh environments include Batis maritima
(pickleweed), Salicornia spp. (glasswort), and Lycium carolinianum (Carolina
wolfberry). At higher elevations as high marsh transitions to upland environments
Borrichia frustescens (sea ox eye daisy) and Distichlis spicata (seashore saltgrass)
dominate. For this study environments containing Spartina patens (salt hay grass) and
Spartina spartinae (gulf cordgrass), which lie just above high marsh environments, were
classified as upland (Fig. 5). Upland environments range in elevation from 0.52 – 5.49 m
(NAVD88) (Paine, White, Smyth, et al. 2004).
Fig. 4 High marsh environment dominated by Monanthochloe litoralis with sparse Salicornia spp.
14
Fig. 5 Transition of environments from high marsh to upland dominated by Spartina patens.
Low Marsh
Low marsh areas are very high in biologic productivity usually ranging in
elevation from -0.1 – 0.3 m (NAVD88) (Paine, White, Gibeaut, et al. 2004). More
frequently inundated areas near tidal creeks are dominated by S. alterniflora (smooth
cordgrass), with Avicennia germinans (black mangrove) and B. maritima following,
whereas less frequently inundated low marsh environments are dominated by B. maritima
and A. germinans (Fig. 6). Historically A. germinans were restricted to the south by
winter freezes, but there has been noticeable expansion northward into S. alterniflora salt
marshes.
Fig. 6 Less frequently inundated low marsh environment dominated by Avicennia germinans and Batis
maritima.
15
Tidal Flats
Tidal flats are extensive on Mustang Island ranging in elevation from -0.05 to 0.5
m (NAVD88) (Paine, White, Gibeaut, et al. 2004). Low regularly flooded tidal/algal flats
are slightly more abundant than high flats (Fig. 7). Tidal flats in this area are designated
as wind-tidal flats because many of the flats are flooded only by wind-driven tides (White
et al. 2006). Blue-green algae flourish in low tidal flats after long periods of inundation,
producing thick mats which bind fine sediment. Some algal flats are characterized as
having a spongecake texture (White et al. 1978). In some areas salt marsh vegetation such
as M. litoralis, B. maritima, and Salicornia spp. can be found sparingly.
Fig. 7 Tidal flats consisting mostly of algal mats in low tidal flat environments.
General Purpose
It is important to quantify sedimentation rates to understand changes due to
hydrology and biologic processes and how the rates of sediment accretion affect the
ability of plants to adapt to the variation of water level. Previous sea level rise models
have shown an upland transition of wetlands while the low marsh environments decrease
drastically in the backbarrier estuarine wetlands of Mustang Island (Gibeaut 2007).
Marshes can potentially overcome sea level rise by accretion of organic and inorganic
16
matter or landward migration. Currently medium-term (50 years) accretion rates have
been calculated for Mustang Island (Radosavljevic 2011), but information on short-term
accretion rates has not been assessed.
Short-term studies generally highlight spatial and temporal variations with phases
of deposition interrupted by erosion, which can be useful in determining migration,
erosion and deposition rates in salt marshes (D.R. Cahoon and Turner 1989). Shorter term
perspective becomes increasingly relevant in an environment impacted by climate
change, change of land use, or other human activities (Blake et al. 1999). Examining
sedimentation rates over a range of time scales provides insight into the factors that
control marsh elevation and sedimentation processes (Neubauer et al. 2002). Because of
the relationship between elevation, vegetation, and tidal inundation, wetland accretion is
expected to vary for different wetland environments in the study area. Erosion processes
are more likely to occur in sparsely vegetated parts of the marsh, such as the pioneer zone
(Nolte et al. 2012). Thus, measuring short-term (1 to 3 years) accretion amounts could be
used to assess vegetation-sedimentation interactions. Additionally, water level loggers
were used in this study near sediment accretion measurement points as a way to assess
how hydrology influences sediment accretion rates on a short-term scale. An overview of
the methods used for this study is shown in Fig. 8.
Using this approach, we are able to learn more about current processes affecting
sedimentation rates and determine how accretion rates affect modern wetland
sustainability. Results from this project will help determine the relative importance of
elevation, inundation, vegetation type, and other geospatial and biophysical influences on
sediment accretion. There is a fundamental need to understand vertical accretion, and the
17
associated sediment dynamics in salt marsh ecosystems. This research seeks to contribute
to the fields of coastal research by providing modern accretion rates and assess the major
influences that could possibly be used to improve models used to help predict
evolutionary changes of coastal wetlands, such as the Sea-Level Affecting Marshes
Model (SLAMM).
Fig. 8 Conceptual diagram showing distribution of field methods used in this study.
18
Chapter 2: Assessing Sediment Accretion Rates
Introduction
As sea level rises there is a growing concern about the ability of wetland
environments to survive. Vertical accretion of sediment in salt marshes is one of the
fundamental processes determining a wetlands ability to overcome accelerating sea level
rise rates. Wetlands can either migrate landward or accrete vertically as sea level rises
depending on the amount of sediment supply and slope to upland regions (Brinson et al.
1995). Vertical accretion is influenced by many factors such as availability of organic and
inorganic matter, vegetation, species composition, flooding patterns, elevation, storm
activity, sediment compaction, wind speed and direction, and relative sea-level rise
(Cahoon and Turner, 1989; Goodman et al., 2007; Gosselink and Turner, 1978). Vertical
accretion rates are commonly compared to relative sea-level rise rates to determine future
wetland stability.
Many methods measuring vertical accretion for different time scales have been
used throughout the scientific community (Thomas and Ridd 2004; Nolte et al. 2012).
The purpose of this thesis is to determine the nature of sedimentation on the coastal
fringing salt marsh of Mustang Island, TX by a combination of erosion pins, kaolinite
marker horizons, and Cs-137 measurements acquired by Radosavljevic (2011). Cesium-
137 profiles yield accretion rates on the decadal scale, whereas as marker horizons
determine annual accretion rates, and erosion pins determine biweekly rates. A
combination of methods across different time scales has been known to reduce error
19
(Nolte et al. 2012). Short-term sediment monitoring involves taking repeated measures
with the potential to be very accurate, depending on the frequency of measurements
taken. An assessment of short-term and long-term accretion rates is critical to
understanding the processes affecting surface elevation, and wetland loss and transition
as sea level rises. Determining the potential for submergence is a critical first step for
management of these valuable coastal habitats within the next century as the rate of sea
level rise accelerates (D.R. Cahoon 1997). Awareness of the processes driving and
affecting change is important for both the public and coastal managers and planners.
The objective of this study is to assess short-term sediment accretion in high and
low marshes, and tidal flats over a short-term period (annual) and compare with the
medium-term (decadal) accretion rates that were determined in a previous study
(Radosavljevic 2011). In prior studies there have been significant differences between
short-term and medium-term accretion rates in salt marsh environments (Parkinson et al.
1994). The differences between the two time scales have been attributed to a combination
of factors such as organic decomposition and sediment compaction (Parkinson et al.
1994). Reed (1989) also noted that sedimentation is not a continuous process and can be
associated with certain tidal and meteorological conditions. This indicates that
sedimentation measured during a given time period may not be the same for another time
period due to the events that occurred. This study aims to answer the following questions:
1) How does the mean and variance of accretion rates vary over decadal, annual, and
monthly time scales?
2) How do rates vary with elevation and geoenvironmental setting?
20
3) How much organic and inorganic matter is associated with the accreted
sediments?
Ultimately, this information will contribute to our understanding of sedimentation in a
sandy, semiarid, microtidal environment.
Material and Methods
A combination of different methods was used to measure sedimentation rates in a
barrier island, brackish salt marsh (Fig. 8).
Sedimentation measurements
(1) Horizon Marker: In March 2012, 166 sites within Mustang Island were
selected for emplacement of kaolinite and red brick dust. The kaolinite and brick dust
mix material was spread out on the marsh floor within a 44 x 44 cm quadrant (Fig. 9).
RTK GPS measuring x, y, z coordinates were taken at each marker as well as two PVC
stakes placed at opposite corners of the quadrant to facilitate finding the plots. Plots were
spatially distributed across the study area in different patterns (Fig. 10). Some plots
followed a transect perpendicular to the barrier island to analyze how accretion varied
with distance to water ways, while other plots were grouped to surround a specific
environment for detailed monitoring. The grouped plots consisted mostly of low marsh
environments since in those settings there was difficulty assessing accretion rates using
the 137
Cs technique previously (Radosavljevic 2011).
21
Fig. 9 Creating a horizon marker with a mixture of kaolinite and red brick dust in March 2012.
Fig. 10 Horizon marker distribution created in March 2012.
22
In August 2014 and July 2015, small, clear tubes 2.5 cm in diameter and 1.5 mm
thin were used to core each horizon marker plot. The driving ends of the tubes were
beveled to reduce friction. The area cored within the plot was replaced by sediment
adjacent to the area and was recorded for future investigation. Two additional cores of the
top 2 cm were taken adjacent to the horizon marker plot for grain size analysis, and
analysis of organic and inorganic content. Using a micromillimeter caliper, four
measurements, evenly spaced around the core tube, were recorded to measure the
accretion above the horizon marker. For cores taken in August 2014, the average
accretion was divided by years for the period of March 2012 to August 2014. For cores
taken in July 2015, the average accretion rate was divided by years for the period of
March 2012 to July 2015. The average accretion rates from August 2014 to July 2015
were also assessed. Vertical accretion is defined as a gross linear sediment accumulation.
There are several advantages of using the horizon marker methodology: it is low
cost; it can be used in vegetated areas; core measurements are simple and fast;
measurements are not influenced by interference of the measuring equipment; and it
measures both organic and inorganic accumulation. Disadvantages include loss of
markers by bioturbation or erosion associated with flood events.
(2) Erosion Pins: Erosion pins (30-pins) made of stainless steel 1.5 mm in
diameter 1 m in length were installed approximately 3 inches northeast of each sediment
plate also installed for this study. Erosion pins were distributed in high marsh, low marsh
and tidal flat environments, upland environments were not included. The pins were
driven into the ground leaving a small portion aboveground for measurement. The height
of the pin was measured every two weeks when sediment plates were retrieved.
23
Measurement for each erosion pin was repeatedly made from the same angle to reduce
error. The measurement error associated with this method is about 1 mm (Nolte et al.
2012). Biweekly rates from erosion pins were annualized for comparisons by summing
the biweekly rates throughout the year for each pin, and then averaging by environment.
Collecting accretion/erosion from erosion pins allows more frequent sampling,
and avoids the problem of sediment compaction, and has the ability to capture temporal
and spatial episodic events. Frequent observation also gives a more detailed indication of
variations in seasonal-related marsh sedimentation processes than is available from
marker horizons.
(3) 137Cs:
137Cs is an anthropogenic radioisotope with a half-life of 30.17 years.
The radioisotope was introduced into the environment during the 1950’s and 60’s during
atomic nuclear testing. Concentration of 137
Cs usually reveals a strong spike in 1963
when atmospheric atomic testing was at its highest. Vertical accretion rates are
commonly assessed using the 1963 spike as a dating marker. Accretion rates determined
using radiometric dating methods for Mustang Island, TX were acquired from a previous
study by Radosavljevic (2011).
Sediment Characterization
Organic Matter Content
Organic matter has been shown in many studies to be a significant contributing
factor for accretion rates in salt marshes throughout the Gulf of Mexico (Turner et al.
2002). Following the methods of Turner et al. (2002) the organic matter content of the
soil was determined by loss-on-ignition (LOI). Homogenized samples were placed on a
24
clean crucible and weighed after drying at 60˚C for 24 hours. Sample weights were
determined using an analytical balance. Samples were then burned at 550˚C for 3 hours,
and then reweighed after cooling to calculate percent of organic matter following the
equation:
% 𝑂𝑟𝑔𝑎𝑛𝑖𝑐 =𝑆𝑎𝑚𝑝𝑙𝑒 𝑊𝑒𝑖𝑔ℎ𝑡𝑑𝑟𝑦 − 𝑆𝑎𝑚𝑝𝑙𝑒 𝑊𝑒𝑖𝑔ℎ𝑡𝑎𝑠ℎ𝑒𝑑
𝑆𝑎𝑚𝑝𝑙𝑒 𝑊𝑒𝑖𝑔ℎ𝑡𝑑𝑟𝑦× 100
Grain Size
Sediment samples were initially digested in 5% H2O2 and gradually increased to
10%, 20%, and 30% H2O2 to remove organic matter. Vegetation was removed using
forceps prior to digestion. For sediment samples that did not have sufficient sediment for
analysis of organic matter and grain size an alternate method was chosen. Alternate
method: Grain size analysis was measured after organic material was measured and
removed from the sample using LOI methods. Samples that were burned for organic
matter and reused for grain size were placed in an ultrasonic water bath for one hour to
help separate sediment particles. Grain size was analyzed using a Coulter LS 13 320 laser
particle counter. The Coulter LS 13 320 laser particle counter uses polarized intensity
differential scattering and the tornado dry power dispersing system to produce reliable
particle size analysis without the risk of missing either the largest or smallest particles in
a sample. Maximum particle size for the laser particle analyzer is 2 mm while the
minimum particle size is 0.004 mm. Grain size was represented using the phi scale,
devised by Krumbein, which is a more convenient way of presenting data (Folk 1974).
Each sample was analyzed three times if possible to avoid bias from skewed runs.
Samples were classified in a ternary diagram following Shepard (1954) using the
statistical program R.
25
Results
All data analysis was conducted in the statistical program R (Version: 3.2.2) using
R Studio (Version: 0.98.1062).
Vertical Accretion Rates
Fig. 11 Aerial imagery showing the distribution of horizon marker plots cored in August 2014 and July
2015.
26
Fig. 12 Sample core from a horizon marker plot in a high marsh area showing sediment accretion
accumulated from March 2012 to August 2014. Photos from left to right taken from different angles.
Of the 166 horizon marker plots created in March 2012, 50 plots were
successfully retrieved in August 2014, while 69 plots were successfully retrieved in July
2015 (Fig. 11). Success of a core was determined by the following criteria:
1. Red horizon marker was clearly visible
2. Marker was not smeared from top to bottom
3. Two or more readings were measureable
An example of a successful core is shown by Fig. 12. Accretion was calculated as
follows:
𝐴𝑐𝑐𝑟𝑒𝑡𝑖𝑜𝑛 𝑅𝑎𝑡𝑒 (𝑚𝑚 𝑦𝑟−1) =𝐷𝑒𝑝𝑡ℎ 𝑡𝑜 𝑀𝑎𝑟𝑘𝑒𝑟
𝑌𝑒𝑎𝑟𝑠 𝑆𝑖𝑛𝑐𝑒 𝑀𝑎𝑟𝑐ℎ 2012
For horizon markers cored in August 2014 for the period of March 2012 – August
2014 (HM 2014), depth was divided by 2.416 years. For horizon markers cored in July
2015 for the period of March 2012 – July 2015 (HM 2015), depth was divided by 3.333
years. Average vertical accretion rates are shown in Table 1 for all time scales.
27
Table 1 Comparison of accretion rates using different time scales averaged by wetland classifications.
Time
Scale Environment N
Accretion
(mm yr-1
)
Standard
Deviation
137Cs
1963-2011
High Marsh 6 1.385 0.402
High Flat 3 0.933 0.482
Low Marsh 3 3.263 0.768
Low Flat 1 1.850 NA
HM2014 03/2012-
08/2014
Upland 6 8.574 5.178
High Marsh 13 4.812 3.733
High Flat 13 2.851 2.639
Low Marsh 5 11.056 2.871
Low Flat 13 2.088 2.226
HM2015 03/2012-
07/2015
Upland 13 7.726 5.243
High Marsh 19 4.198 3.543
High Flat 14 3.873 4.504
Low Marsh 8 12.797 5.533
Low Flat 15 1.673 1.145
Erosion
Pin 07/2014-
07/2015
High Marsh 11 6.636 8.834
High Flat 3 -3.333 10.115
Low Marsh 9 16.000 16.598
Low Flat 7 1.714 2.870
Comparing Accretion Rates across All Time Scales
Significant differences showed up at a glance by observing the means and
variation for each environment and time scale (Fig. 13). If the interaction is not
significant you can see roughly parallel lines for any level of a factor. Significant
differences were found between Environment and Accretion Rate for all Timescales (p <
0.1).
A two-way Analysis of Variance (ANOVA) was used to determine the
differences between accretion rates and the four different time scales (137
Cs, HM 2014,
HM 2015, and Erosion Pins). Both Environment and Time Scale were considered fixed
factors in the model. A summary of the ANOVA model gave a general overview of the
significance, indicating Time Scales were significantly different using α = 0.1. 137
Cs
28
timescale was significantly different from HM2014, HM2015, and Erosion Pins (p < 0.1).
HM2014 and HM2015 were not significantly different, as well as HM2014 and HM2015
when compared to Erosion Pins (p > 0.1). The interaction between Time Scale and
Environment was not significant (p = 0.306), therefore post hoc testing proceeded on
each factor separately.
Fig. 13 Plot showing Accretion Rate for each Environment separated by Time Scale.
Diagnostics tests, which includes normality, heteroscedasticity, and Cook’s
distance, indicated some problems with heteroscedasticity, but were corrected for using a
variance function (Zuur et al. 2009). The varPower function was chosen as the best model
based on Akaike’s Information Criterion correction (AICc) values, which are based on
maximum likelihood fittings. Four ANOVAs were run with Environment as the main
factor, one for each Time Scale. Shaffer procedures were chosen to determine which
29
Environments and Years were different because the data was unbalanced (Shaffer 1986).
Results for post hoc are shown in Fig. 14. Upland environments were not compared
between horizon markers and 137
Cs because there were no cores taken in that
environment for radioisotope measurements. Vertical accretion rates from both HM2014
and HM2015 were significantly different from 137
Cs for High Marsh and Low Marsh
environments (p < 0.1), but not High Flat and Low Flat environments (p > 0.1). Vertical
accretion rates from both HM2014 and HM2015 were not significantly different than
Erosion Pin accretion rates for all Environments (p > 0.1). Vertical accretion rates from
HM2014 were not significantly different than accretion rates from HM2015 in all of the
Environments (p >0.1). 137
Cs and Erosion Pin accretion rates were significantly different
in High Marsh and Low Marsh environments (p < 0.1), but not in High Flat and Low Flat
environments (p > 0.1).
30
Fig. 14 Results from ANOVA comparing different Time Scales within specific levels of Environment. a) High Marsh, b) High Flat, c) Low Marsh, d) Low
Flat. Different number of asterisks between levels indicate significance (p < 0.1). Same number of asterisks between levels indicate no significance (p > 0.1).
31
Fig. 15 Results from ANOVA comparing different Environments within specific Time Scales using
Horizon Markers only; a) Vertical accretion rates for the period of March 2012-August 2014, b)
Vertical accretion rates for the period of March 2012-July 2015. Different number of asterisks between
levels indicate significance (p < 0.1). Same number of asterisks between levels indicate no significance
(p > 0.1).
A separate ANOVA was used to compare vertical accretion rates from HM2014
and HM2015 Environments, which included Upland as a factor. Factors were similar to
the previous model. A diagnostic test did not indicate any problems with residuals. The
interaction between Time Scale and Environment for this model was not significant (p =
0.9166). A multiple comparison function was used initially to determine differences
32
between HM2014 and HM2015. Results indicated no significant difference between
HM2014 and HM2015 (p= 0.429). Further post hoc testing included two ANOVAs with
Time Scale as the main factor for each Environment (Fig. 15), and an additional ANOVA
included Upland as the main factor for each Time Scale. ANOVA results comparing
Environments within Time Scales were similar for HM2014 and HM2015. There was no
significant difference between Upland and Low Marsh environments for both HM2014
and HM2015 (Fig. 15). There was also no significant difference between High Marsh,
High Flat, and Low Flat environments for both HM2014 and HM2015. Significant
differences only occurred between Upland and Low Marsh when compared to High
Marsh, High Flat, and Low Flat environments.
Focusing on Erosion Pins
The bi-weekly temporal variation in sediment accretion and erosion on the marsh
surface was measured using erosion pins for the period of July 2014 – July 2015 (Fig.
16). Studying the erosion pin data, ANOVA results indicated significant difference by
season, although post hoc tests showed that the summer of 2014 was the only
significantly different season (p < 0.1). This was during the highest deposition for High
Marsh, High Flat and Low Marsh environments which occurred in August due to wind
processes (Fig. 16).
34
Comparing Short-Term Accretion Rates
There were a total of 47 cores from the period of March 2012 to August 2014
(P2014) that were comparable to cores from the period of August 2014 to July 2015
(P2015) because not all cores retrieved in 2014 were successful in 2015. Cores were
further reduced to 33 for each year to only include cores classified as “Good” according
to the above criteria. Overall average accretion rates from P2014 were compared to
annualized accretion rates from P2015 using a linear mixed effect model (Zuur et al.
2009). Cores from P2015 were annualized by dividing the accretion by 11/12 because the
time period was one month short of a full year. A linear mixed effect model was used for
this analysis with Time Scale as the fixed factor, and Environment as the random factor
(Zuur et al. 2009). Westfall procedures were chosen to determine if Time Scales were
different since the data was balanced (Westfall 1997). Diagnostics tests did not indicate
any problems with residuals. Results from the ANOVA showed no significant differences
in accretion rates between P2014 and P2015 (p > 0.1). Differences grouped by
environment could not be assessed because some Low Marsh environments consisted of
one value for each year, which is also why Environment was considered a random factor
to help take into account the variation in accretions rates (Table 2). From the 33 cores
that were comparable, 10 indicated signs of erosion the highest being ~ -17 mm from an
Upland environment using average accretion (mm). The second highest was ~ -15mm
from a Low Flat environment using average accretion (mm).
35
Table 2 Average sediment accretion rates for P2014 and P2015 after removing poor quality cores.
Time
Scale Environment N
Accretion
(mm yr-1
)
Standard
Deviation
P2014 03/2012 –
08/2014
Upland 2 12.655 3.373
High Marsh 10 5.536 4.438
High Flat 8 1.778 0.657
Low Marsh 1 10.112 NA
Low Flat 12 2.248 2.377
P2015 08/2014 –
07/2015
Upland 2 -5.408 18.534
High Marsh 10 6.480 7.005
High Flat 8 2.650 4.646
Low Marsh 1 -0.953 NA
Low Flat 12 0.0900 5.891
Correlation to Elevation
A series of linear models were created to investigate the effects of elevation on
vertical accretion rates for HM2014, HM2015, and 137
Cs (Fig. 17, 18, and 19,
respectively). Linear models were separated using all data (except Upland) in one model
and salt marsh only data (High Marsh and Low Marsh) in the other model. Each
scatterplot further separates the data into two subcategories, all data and poor core quality
values removed. Linear models including salt marsh and flats for horizon markers in
HM2014 and HM2015 appear to have a positive correlation between accretion per year
and elevation. The linear relationships for both horizon markers are only significant for
models with poor core values removed (p < 0.1), but only a small percent of the variation
can be explained by elevation alone (Fig. 17 and 18). The linear relationship between
vertical accretion rates and elevation using 137
Cs data has a negative correlation for both
linear models using all data and poor core values removed (Fig. 19), but are not
considered significantly correlated (p > 0.1).
36
Fig. 17 Scatterplot showing relationship between accretion and elevation using horizon markers for the period of Marsh 2012 to August 2014. Plot on the left
shows accretions from all environments. Plot on the right shows accretion data for salt marsh only, low marsh and high marsh environments. Error bars indicate
standard error.
0.2
0.3
0.4
0.5
0.6
0 2 4 6 8 10 12 14 16Accretion (mm/yr)
Ele
vat
ion
(m
, N
AV
D8
8)
Good Poor
Salt Marsh and Flats (2014)
All Data Poor Removed
y = 0.35 + 0.0043x, r = 0.0186
y = 0.037 + 0.0022x, r = 0.0049
2
2
0.3
0.4
0.5
0.6
0 2 4 6 8 10 12 14 16Accretion (mm/yr)
Ele
vat
ion (
m,
NA
VD
88)
Salt Marsh Only (2014)
Good PoorAll Data Poor Removed
y = 0.54 + -0.011x, r = 0.144
y = 0.55 + -0.013x, r = 0.222
2
37
Fig. 18 Scatterplot showing relationship between accretion and elevation using horizon markers for the period of Marsh 2012 to August 2015. Plot on the left
shows accretions from all environments. Plot on the right shows accretion data for salt marsh only, low marsh and high marsh environments. Error bars indicate
standard error.
0.2
0.3
0.4
0.5
0.6
0 2 4 6 8 10 12 14 16 18 20 22 24Accretion (mm/yr)
Ele
vat
ion
(m
, N
AV
D8
8)
Good Poor
Salt Marsh and Flats (2015)
y = 0.38 + 0.0053x, r = 0.0203
y = 0.4 + -0.0041x, r = 0.0255
All Data Poor Removed
2
2
0.2
0.3
0.4
0.5
0.6
0 2 4 6 8 10 12 14 16 18 20 22 24Accretion (mm/yr)
Ele
vat
ion (
m,
NA
VD
88)
Good Poor
Salt Marsh Only (2015)
y = 0.53 + -0.0058x, r = 0.0326
y = 0.56 + -0.015x, r = 0.381
2
2
All Data Poor Removed
38
Fig. 19 Scatterplot showing relationship between accretion and elevation using
137Cs (Radosavljevic 2011). Plot on the left shows accretions from all
environments. Plot on the right shows accretion data for salt marsh only, low marsh and high marsh environments. Error bars indicate standard deviation.
0.2
0.3
0.4
0.5
0.6
0.7
0.5 1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5Accretion (mm/yr)
Ele
vat
ion (
m,
NA
VD
88)
Good Poor
Salt Marsh and Flats (Cs 137)
y = 0.63 + -0.072x, r = 0.172
y = 0.62 + -0.092x, r = 0.253
2
2
All Data Poor Removed
0.2
0.3
0.4
0.5
0.6
0.7
1.0 1.5 2.0 2.5 3.0 3.5 4.0 4.5Accretion (mm/yr)
Ele
vat
ion (
m,
NA
VD
88)
Good Poor
Salt Marsh Only (Cs 137)
y = 0.8 + -0.14x, r = 0.642
y = 0.76 + -0.097x, r = 0.831
2
2
All Data Poor Removed
39
Linear models for salt marsh only data indicate a negative correlation between
elevation and vertical accretion rate for all time scales. The linear model is significant for
HM2014 (all data), HM2015 (all data), and 137
Cs (both all data and poor core values
removed). Removing poor core values from HM 2014 and HM 2015 linear models
decreases the significant correlation and overall fit (p > 0.1). Removing poor core values
from 137
Cs improves the model (r2=0.831).
Grain Size Analysis
A ternary plot was constructed for all the samples to classify the sediment texture
overall by environment type. Grain size distributions of 50 samples were determined
from the horizon marker plots cored in August 2014 (Fig. 20a). Grain sizes of 69 samples
were determined for plots cored in July 2015 (Fig. 20b). Most of the samples for Upland,
High Marsh, High Flat, and Low Marsh environments consisted of fine sand, while most
samples from High Algal Flat, and Low Algal Flat environments were silty-sand (Fig.
20). Sediment samples from July 2015 followed a similar pattern to August 2014 grain
size samples.
40
Fig. 20 Textural classification of sediment samples from horizon markers. a) Horizon markers cored in August 2014, b) Horizon markers cored in July 2015.
41
Organic Matter Analysis
Sediment samples from marker horizons were also analyzed for organic matter
content using loss-on-ignition methods. Organic matter was measured from the top 2 cm
of the marsh surface. The average percent of organic matter from HM2014 was 3.27 ±
1.94% for all samples (N=50) with 0.82% as the minimum from Upland and High Marsh
environments, and 10.38% as the maximum from a thick algal mat on the surface. The
average percent organic matter from HM2015 was 3.77 ± 3.05% for all samples (N=69)
with 0.67% as the minimum from an Upland environment, and 17.57% as the maximum
from a thick algal mat on the surface. The average percent organic matter of each
environment was noted for each horizon marker Time Scale (Fig. 21).
Fig. 21 Relationship between percent organic matter and Environment for both Time Scales using horizon
markers.
Relative contributions of organic and inorganic matter to vertical accretion rates
were calculated following Bricker-Urso et al. (1989) based on bulk density and loss-on-
ignition data, as follows:
2
4
6
8
Upland High Marsh High Flat High Algal Flat Low Marsh Low Algal FlatEnvironment
Org
anic
Mat
ter
(%)
HM2014 HM2015
42
𝑆𝑖 =𝑆𝑡 ∗ 𝐿𝑂𝐼
𝐷𝑖
Where St = total average sediment accumulation (g cm-2
yr-1
), LOI = ratio of loss-
on-ignition (%LOI/100 for organic, 1 - %LOI/100 for inorganic), Di = sediment density
(2.6 g cm-3
for inorganic, 1.1 g cm-3
for organic (DeLaune et al. 1983), and Si = inorganic
and organic sediment accretion in cm yr-1
, but were converted to mm yr-1
. Organic matter
contribution includes porosity and water content, which over estimates the actual
contribution, therefore ratios of inorganic to organic from the Radosavljevic (2011) study
(Fig. 24), were also applied after the calculation to reduce organic matter inflation (Fig.
22 and 23).
Rates of vertical accretion were also plotted against rates of inorganic and organic
sediment accretion without taking into account porosity and water content (Fig. 25).
Vertical accretion rates were significantly correlated with organic and inorganic accretion
for all horizon markers (p < 0.1). Linear fit however was more significant for inorganic
matter (r2= 0.90) in comparison to organic matter (r
2 = 0.64). Inorganic matter generally
dominates vertical accretion contribution based on organic matter percentage determined
by the LOI method.
43
Fig. 22 Relative contributions of organic and inorganic matter to accretion from horizon markers cored in August 2014 for the period of March 2012 to
August 2014. Organic matter contributions include porosity and water content. Rate of sea level rise at Rockport, TX is also shown by the light grey
area.
44
Fig. 23 Relative contributions of organic and inorganic matter to accretion from horizon markers cored in July 2015 for the period of March 2012 to July
2015. Organic matter contributions include porosity and water content. Rate of sea level rise at Rockport, TX is also shown by the light grey area.
45
Fig. 24 Relative contributions of organic and inorganic matter to accretion from 137
Cs cores from previous study (Radosavljevic 2011). Organic matter
contributions includes porosity and water content. Rate of sea level rise at Rockport, TX is also shown by the light grey area.
46
Fig. 25 Relationship between vertical accretion rates and both organic and inorganic accretion rates from
combined (HM2014 and HM2015) horizon markers (annual time scale) and 137
Cs (decadal time scale). a)
organic accretion b) inorganic accretion c) organic versus inorganic d) legend for all three graphs. Note:
These graphs do not take into account porosity and water content.
47
Discussion
The success rate of horizon marker plot retrieved over time increased slightly
from 30% in August 2014 to 41% in July 2015. The increase of plot recovery was due to
improved coring equipment in July 2015. A few horizon markers were also missed during
core operations in August 2014 due to lack of visual aids. Horizon markers in Low Marsh
environments near the main tidal creek were not obtained due to the difficulty of coring
and loss of the markers. The loss of the marker can be attributed to many factors such as
wind resuspension, wave erosion, and bioturbation mixing with organic and inorganic
matter. Man-made horizon markers using brick dust have been known to have a low
recovery rate in many studies (D.R. Cahoon and Turner 1989; Knaus and Van Gent 1989;
Nolte et al. 2012).
Comparing Vertical Accretion Rates
Comparing different methods over various time scales is difficult because of the
various processes occurring simultaneously, such as subsidence (both shallow and deep),
plant processes (above and below), sea level rise, and sedimentation (Callaway et al.
1996). Annual accretion measurements using horizon markers generally highlights
accumulation events on the marsh surface, but most likely overestimates surface
elevation change because of subsurface processes occurring below the horizon marker
(D.R. Cahoon et al. 1995). Decadal accretion measurements however, highlight
accumulation of the surface processes as well as processes, such as compaction and
bioturbation that occur within the sediment column above and below the horizon marker.
Compaction within the decadal rates, calculated from dry bulk density measurements
48
throughout the column, increased at an average rate of 0.0096 per cm (Radosavljevic
2011). The largest average rate of change in compaction, 0.1216 per cm, occurs within
the top 3 cm of the marsh surface (Radosavljevic 2011), which falls within the range of
the average depth to horizon markers, 1.4 cm. Average depth to the 137
Cs marker is
approximately 7 cm. The significant difference between the decadal rates using the 137
Cs
and the annual rates derived from the horizon markers may also be attributed to other
factors. 137
Cs measurements take into account several hurricanes since 1963 that have
passed and deposited sediments to the bayside (Table 3). There have been a total of 29
hurricanes since 1963 within 200 km of Mustang Island. The highest category was H4
named Bret in 1999 that landed in Kennedy County. Storm surge associated with
hurricanes wash sediments from the Gulf shore to the bayside opening washover channels
for a period of time. Washover fans on the bayside are the sites of tidal flats and salt
marshes. The cores from the Radosavljevic (2011) study, approximately 1 m deep,
showed several washover facies throughout the column with a sharp contact to tidal flat
facies and eolian flat facies indicating that accumulation of sediments were deposited by
a hurricane.
49
Table 3 List of hurricanes, tropical storms depression since 1963 within 200 km of Mustang Island (NOAA
2014b).
Hurricane Category Name Landed on Mustang?
H4 Bret (1999) No
H3 Celia (1970), Allen (1980) Yes, Celia
H2 Beulah (1967) and Dolly (2008) No
H1
Edith (1971), Fern (1971), and
Claudette (2003)
Yes, Fern
Tropical Storms
N=14 Yes, Candy (1968) and
Charley (1998)
Tropical Depression N=7 No
Vertical accretion rates on the decadal scale are expected to be lower because of
physical compaction and decomposition of organic matter. Tidal flat rates were much
lower than all Environments regardless of Time Scale, which points to future potential
loss in this habitat zone, although the ANOVA for Low Flat environment (Fig. 14d;
Table 1) should be taken with caution because there was only one sample representing
Low Flat using 137
Cs. The most significant differences in vertical accretion between
horizon markers and 137
Cs were for High Marsh and Low Marsh environments. Previous
studies have indicated that pore space is often one of the most important factors affecting
the overall accretion rate in sandy environments because it can potentially occupy as
much as 30-40% of the sediment volume (McLachlan and Turner 1994; Callaway et al.
1996). This is especially true for short-term studies that measure surface processes.
Porosity of sediment depends on the arrangement or packing individual grains. Removing
50
pore space volume from this study significantly reduces the annual accretion rates to
within the range of decadal accretion rates (Fig. 26). Pore space was removed by only
taking into account organic and inorganic contributions calculated from bulk density
measurements as follows:
𝑃𝑜𝑟𝑒 𝑆𝑝𝑎𝑐𝑒 = 𝑉𝑒𝑟𝑡𝑖𝑐𝑎𝑙 𝐴𝑐𝑐𝑟𝑒𝑡𝑖𝑜𝑛 (𝑚𝑚 𝑦𝑟−1) − (𝑂𝑟𝑔𝑎𝑛𝑖𝑐 𝐶𝑜𝑛𝑡𝑟𝑖𝑏𝑢𝑡𝑖𝑜𝑛 (𝑚𝑚 𝑦𝑟−1)
+ 𝐼𝑛𝑜𝑟𝑔𝑎𝑛𝑖𝑐 𝐶𝑜𝑛𝑡𝑟𝑖𝑏𝑢𝑡𝑖𝑜𝑛 (𝑚𝑚 𝑦𝑟−1))
Erosion pin accretions were also significantly different to 137
Cs (p < 0.1), but not
to both HM2014 and HM2015 accretion rates (p > 0.1). Erosion pins offer a higher
frequency of measurements which usually increases the variance. The high amount of
variation in erosion pins made it difficult to observe differences to annual accretion rates
using horizon markers, but not the decadal accretion rates using 137
Cs. By measuring
accretion rates bi-weekly and annualizing we are able to capture the dynamic changes
occurring on the marsh surface throughout the year. Erosion pins take into account
accretion and erosion from episodic and spatially variable events that occurred
throughout the year, which may have reduced the overall mean for some Environments
(Fig. 16).
51
Fig. 26 Organic and inorganic contributions of HM2014 (top) and HM2015 (bottom) excluding pore and
water space.
52
Focusing on Erosion Pins
Although vertical accretion rates over the two week periods had a substantial
amount of variation over time, ANOVA results indicated significant differences in
accretion by Environment (Fig. 16). Variations in Tidal Flats containing a thick layer of
algal mat were often caused by gas filled voids producing a spongecake structure during
flooding events. Variations were also caused by eolian sediments deposited on Tidal Flats
often delivered from surrounding barren flats. The high accreting outlier in the Low Flat
environments was caused by a buildup of algae after a long period of inundation (Fig.
16). Upon returning two weeks later the accreting algae dried up and shrunk to a thin
layer of algal mat. High Flat environments overall remained fairly consistent with the
exception of one eroding site near a high traffic area. Although the erosion pin was never
disturbed by vehicle tire tracks, it was disturbed by wildlife, most likely coyotes roaming
around. Small variations in Low Marsh environments were mostly due to bioturbation.
The high accreting outlier in Low Marsh environments was due to aeolian transport
similar to a few High Marsh environments along the same area (Fig. 16). The high
accretion in August 2014 is an example of a short-episodic event that strongly influences
sediment accretion.
Comparing Short-Term Accretion Rates
Short-term monitoring over the two periods using the marker horizons did not
indicate significant differences in accretion rates between March 2012 – August 2014
(P2014) and August 2014 – July 2015 (P2015). The two different time periods show a
53
large amount of variation within each Environment making it difficult to distinguish any
differences. When observing total accretion (mm) between the two time periods however
there is a significant difference (p < 0.1) indicating that significant sediment transport
occurred in P2014 to generate slightly higher accretion. Erosion in some areas was most
likely caused by heavy rainfall during the fall and winter months of 2014. Before coring
in August 2014, the windy, arid climate caused unconsolidated, fine sand sediments to
move quickly across the marsh surface. This caused high sediment accretion in some
areas that were captured in the August 2014 cores. Caution is taken when interpreting the
difference in accretion rates between P2014 and P2015 because very few cores were
comparable (N=33).
Correlation to Elevation
The linear models used to investigate the relationship between vertical accretion
and elevation showed different correlations when grouped by environment. Linear
models were split into two groups, salt marsh only and all data, because the presence of
vegetation has been known to modify physical process by efficiently trapping more
sediment. Linear models do not include Upland environments for HM2014 and HM2015.
Vegetation could not be further reduced to species level due to lack of representative
horizon marker plots. Removing tidal flats greatly improved the model; however
removing poor quality values reduces the significance for both HM2014 and HM2015
saltmarsh only data (Fig. 17 and 18). This is most likely because very few horizon marker
plots in the low marsh environment were recovered, and those that were recovered were
questionable. Both annual scale accretion rates using horizon markers follow the same
negative correlation patterns as the decadal scale accretion rates calculated using 137
Cs, as
54
elevation decreases there is an increase in vertical accretion (Fig. 19). The rate of change
however differs between the two time scales due to differences in accretion rates in low
marsh environments. The negative correlation follows previous studies along the Gulf
coast, stating that at lower elevations there is a higher probability of sediment deposition
due to tidal influences (Pethick 1981). That assumption may not necessarily be the case
for this study area due to the strong influence of wind on the geomorphology, but the
presence of vegetation may be helping to trap sediment more efficiently whether
transported by tidal or aeolian processes.
Relative Contribution of Organic and Inorganic Matter
Sediment accumulation in wetlands consists of organic and inorganic matter,
although the ratios vary among salt marshes. Organic matter is generally considered more
important than inorganic matter for vertical accretion because it maintains the soil’s
stability, water volume, and sustains pore space (Turner et al. 2002). The relative
contributions on a dry weight basis indicate that inorganic matter overwhelmingly
dominates accretion on Mustang Island; however, this contribution is less evident after
associating pore space and water content to organic matter (Fig. 22, 23, 24). Previous
studies have attributed pore space volume to organic matter because of its strong
correlation with water (Bricker-Urso et al. 1989). Following this assumption, the ratio of
organic to inorganic matter contribution for vertical accretion is approximately 1:1,
although there is some skepticism using this theory due to differences in climate.
The importance of inorganic contribution is evident by the significantly linear
relationship between accretion and inorganic accretion (Fig. 25b). Vertical accretion rates
55
for this area are directly related to both organic and inorganic matter, although the
relationship with inorganic matter has a stronger correlation (r2 = 0.91). On average
Upland environments had the least percent of organic matter content (1.54 ± 0.7 %),
while Low Algal Flat had the greatest organic matter content (6.44 ± 3.4 %). The linear
trend of increasing percent organic matter from Upland to Low Algal Flat is shown in
Fig. 21. The organic and inorganic accretion rates also show this linear trend in
increasing organic matter from Upland to Low Marsh environments indicating that
organic matter contributions are more significant in Low Marsh environments than
Upland (Fig. 25c). Overall organic and inorganic accretion rates for horizon markers
follow the same patterns as 137
Cs, dominated by inorganic matter (Fig. 25a, b). The strong
correlation with inorganic matter in short-term and longer-term studies suggests that
Mustang Island vertical accretion rates are influenced by the amount of inorganic matter
deposited in the area. The dominance of inorganic matter helps reinstate the fact that the
area depends greatly on episodic inputs from storms to maintain its elevation, which often
brings inorganic matter.
56
Fig. 27 Comparison of the relationship of vertical accretion with organic and inorganic accretion in the
present (MUI Horizon Marker) and previous study (MUI 137
Cs) for this area as well as other localities a)
organic accretion, b) inorganic accretion, c) organic versus inorganic accretion, d) legend for all plots
indicating locations. Data of other studies are from Turner et al. (2002) for Upper Texas coast, Louisiana,
and Rhode Island, and data for Texas (Aransas National Wildlife Refuge), San Bernard, Mississippi, and
Florida Keys are from Callaway et al. (1997).
57
When comparing organic and inorganic accretion rates in marshes of other
geographic areas, organic matter accretion for this study area appears to contribute much
less to vertical accretion (Fig. 27). The dominance of inorganic matter is due to the
generally drier and wind dominated character of wetland environments on Mustang
Island in comparison to other geographic areas. Lower, frequently inundated
environments in Mustang Island are more similar to marshes in Rhode Island, Florida and
Mississippi (Fig. 25 and 27). Previous studies have shown that there is an upper limit to
the amount of organic accretion, causing marshes to be lost to rising sea levels despite
having high accretion rates (McCaffrey and Thompson 1980; Bricker-Urso et al. 1989;
Turner et al. 2002). Results from this study follow similar patterns to marshes in
Louisiana receiving high amounts of inorganic sediment, and very little organic matter.
Both studies appear to reach an asymptote in the relationship between organic versus
inorganic, which suggests that organic accretion cannot match such high rates of
inorganic accretion (Fig. 28). Inorganic sediment has been shown to play an important
role creating a positive feedback loop with plant growth by increasing particulate
nutrient, which is shown by the positive relationship between organic and inorganic
matter (Fig. 25 b, c). It is important to keep in mind that the studies shown in Fig. 27, all
used radiometric dating methods using the 137
Cs marker (decadal accretion rates)
therefore the vertical accretion rate in this study using horizon markers (annual accretion
rates) are expected to be higher.
58
Fig. 28 A comparison of the relationship between organic accretion and inorganic accretion. a) This study combined with Radosavljevic (2011), b) Louisiana
studies from Fig. 20. Shaded regions indicate 95% confidence interval. This figure is the similar to Fig. 20c except the geographic localities are plotted separately
for visualization.
59
Grain Size
Grain sizes are often used as a means of distinguishing coastal environments of
deposition (Simms et al. 2006). Grain size distribution did not differ very much between
HM2014 and HM2015 with the exception of additional measurements in HM2015 due to
increase in plot recovery. The majority of the horizon marker plots were classified as fine
sand, and a few algal flats classified as silty sand. Upland environments were 100% sand,
while High Marsh, High Flat, and Low Marsh environments had slight variations, but
remained classified as fine sand. Grain sizes became finer going from Upland to Low
Algal Flat environments (Fig. 20). Differentiating sediment grain size using means is
difficult for Mustang Island due to the uniformity of fine grain sizes across the marsh.
Implications for Sea-Level Rise and Marsh Loss
The rate of relative sea-level rise (RSLR) for this area over the last ~77 years
(1937 – 2014) has been 5.27 mm yr-1
, as recorded by the Rockport, TX tidal gauge
station (NOAA 2014a). Accretion rates using horizon markers appear to be “keeping up”
with RSLR in Low Marsh (~11-12 mm yr-1
) and Upland environments (~7-8 mm yr-1
),
but not Tidal Flats or High Marsh environments that sit just above Low Marsh
environments in elevation. The range in elevation of the Mustang Island environments is
minimal ranging from ~0.2 m to ~0.7 m, therefore even a small increase in tidal range
can greatly influence this area (Fig. 29).
60
Fig. 29 Range of elevations for each environment. Low flat elevations vary in this area, but are generally
considered to be at lower elevations than low marsh environments.
Tidal flats, which are important avian feeding habitats, will more than likely be
converted to low marsh environments, while the low marsh environments will likely
convert to open water. The short-term accretion rates categorized by environment follow
the same patterns as the decadal rates from 137
Cs (Fig. 13), but are significantly higher
due to pore space. Decadal accretion rates across all environments do not appear to keep
pace with RSLR for this area. Consequentially, changes in environmental states are
expected to occur as sea-level rises as we have seen in the past (Fig. 30). The rate of
change is what differs between the two time scales. There is a greater deficit for accretion
rates in Low Flat (~1.5-2 mm yr-1
) environments relative to sea-level rise rate (~5 mm yr-
1), which may explain the findings of (White et al. 2006) shown in Fig. 30. Tidal Flat loss
for Mustang Island has been declining since the 1950s, showing a transition of
environmental states from Tidal Flat to Low Marsh due to absence of washover channels,
Upland High Marsh High Flat Low Marsh Low Flat
0.2
0.3
0.4
0.5
0.6
0.7
Ele
vat
ion
(m
, N
AV
D8
8)
61
and fewer connections to estuarine systems (White et al. 2006). This has caused upland
vegetation to stabilize dunes along the west side of Mustang Island.
Fig. 30 Map showing wetland transitions from 1950’s, 1979, and 2002-04 for Mustang Island and Harbor
Island (White et al. 2006). Study area in Mustang Island is highlighted by the red box.
Estuarine marsh
Flats/beaches
Palustrine marsh
Aquatic beds
Scrub/shrub
Upland
0 5 102.5Km
2002-04 1979 1950's
1950 1979 2002-04
62
Conclusion
Vertical accretion rates were significantly different between annual scale and
decadal scale measurements. Decadal vertical accretion rates are much lower because of
the different processes being measured, as well as compaction and decomposition
throughout the core. Sediment accumulation for the period of 2014 to 2015 was minimal,
although there was high variation in accretion/erosion throughout the study as indicated
by the erosion pins. Inorganic matter was the major contributor for vertical accretion in
Mustang Island, which is drastically different than other geographic areas. This is due to
the arid, wind-dominated climate associated with Mustang Island. According to short-
term accretion rates Low Marsh environments are capable of keeping pace with RLSR;
however the area is expected to undergo changes in environmental states due to the low
amounts of organic matter contributing to vertical accretion. Mustang Island depends
greatly on episodic inputs from storms to maintain its elevation. Although hurricanes
often generate impacts detrimental to the environment, they also have potential benefits
by supplying large areas of coastal marsh with sediment. When storm-induced sediment
is sufficient, stability of coastal marshes may be enhanced for some time to help cope
with RSLR (Baustian and Mendelssohn 2015).
63
Chapter 3: Assessing Hydrological Influences
Introduction
In many estuarine wetlands throughout the Gulf of Mexico, hydroperiod, which
consists of flooding frequency and duration, is considered one of the major factors
controlling sediment deposition (D. R. Cahoon and Reed 1995).Winds, precipitation,
evaporation, astronomical tides, and fluctuating regional sea levels influence water levels
occurring in wetlands throughout the year. Marshes that are remote from a riverine source
such as Mustang Island rely on winter storms, tropical cyclones, and strong winds for
mobilizing sediments into the marsh. During storms, water levels are raised high enough
to flood the marsh and potentially deposit sediment. Tidal creeks are the system through
which sediments, organic matter, nutrients, and pollutants are transported into and out of
the wetlands. Sediment sources for remote marshes are largely related to resuspension of
existing sediments adjacent to the marsh environment. Hurricanes, on the other hand,
have the ability to transport large pulses of sediment onto the marsh surface through
washover channels. The sediment sources from hurricanes can come from bay and ocean-
side dunes and beaches washed over during the event. The major hydrodynamic
characteristics proposed by Gosselink and Turner (1978) are the water inputs, water
outputs, type of water flow, and hydropulses (seasonality).
Previous studies have illustrated the importance of microtopography in
controlling flooding regimes (Reed and Cahoon 1992). Variations within 0.04 m across
the marsh surface are able to produce significant changes in hydroperiod (Swenson and
Turner 1987). Variation in topography causes areas of the marsh to be flooded more
frequently and for longer periods than others. Evapotranspiration and tidal flooding can
64
also affect soil volume and precise marsh surface levels (Paquette et al. 2004). Surface
and groundwater circulation rate are also vital to the sedimentation process, chemistry,
and biological processes due to the strong feedback loop between circulation, sediment
dynamics, and the constantly changing geomorphology (Perillo et al. 2009). Vegetation
often provides important clues of hydrogeomorphic forces in an ecosystem (Brinson
1993). Sources of freshwater in salt marshes can come from river input, groundwater
flows, or as a result of rainfall. The overall freshwater input for Mustang Island is
determined by meteorological conditions, such as the precipitation and evaporation
balance. There are two effects of rainfall on salt marshes, reduction in soil salinity and
the flow of water across the surface of the marsh with the potential for eroding,
transporting, and depositing sediment within the wetland. In this study we examined the
relationship between wetland topography, hydroperiod, and sediment accumulation over
a period of 12-months. Results from this study will further our understanding of sediment
delivery into the marsh system through tidal processes thus having important implications
for wetland development and management. This study aims to answer the following
questions:
1) What is the relationship between hydroperiod and sediment accretion?
2) How much organic and inorganic matter is associated with hydroperiod?
This information will contribute to our understanding of the hydrological influence to the
sediment accretion of a brackish salt marsh.
Materials and Methods
Water Level Loggers
65
Eighteen water level loggers (WLL) were used to measure water depth and
temperature (Fig. 31). Data were acquired at defined intervals and stored in each WLL
until it was downloaded in the field. The WLL use pressure transducers to measure water
depth, therefore, data need to be adjusted for atmospheric pressure.
Fig. 31 Distribution of water levels loggers on Mustang Island, TX.
There were two types of water level loggers used in this study:
Water Level with a vented cable, which is capable of correcting for atmospheric pressure
automatically (OTT Orpheus Mini)
Water level non-vented with no cable (completely submerged), which needs corrections
for barometric pressure. Barometric pressure was acquired from the Packery Channel
tidal gauge less than 10 km from the study area and operated by the Texas Coastal Ocean
Observation Network at TAMU-CC.
67
Fig. 33 HOBO Onset water level logger deployment diagram (Source: HOBO Onset 2015).
Technical Information
The OTT Orpheus Mini is 1m in length with a water level measuring range from 0 –
4 m with an accuracy of ± 0.05% full scale (FS) or ±0.2 cm (Fig. 32). The temperature
measuring range is from -25˚C to +70˚C with an accuracy of ± 0.5˚C. Measurement
memory for data is 4MB (approximately 500,000 measurements). The HOBO Onset
U20L-04 is about 15 cm in length with water level measuring range from 0 – 4 m and
accuracy of ± 0.1% FS or ± 0.4 cm (Fig. 33). The temperature range is from -20˚C to
50˚C with an accuracy of ± 0.44˚C. Measurement memory is 64KB (approximately
21,700 measurements).
Deploying Device
Criteria used to define location of water data loggers:
Must be within 1 m of a retrieved marker horizon
Preference is for clustered markers
Must have at least one logger in each geoenvironment type (High Marsh, Low
Marsh, and Tidal Flats)
A logger must be in each of two major tidal creeks (HOBOs were used for these
sites)
68
Orpheus Mini water level loggers were deployed using a 2.5 m fence post and 2.5 cm
diameter Schedule 40 PVC pipe 1 m in length (Fig. 32). The fence post was driven into
the ground leaving 1 m exposed to attach the PVC pipe with two steel hose clamps. The
Orpheus Mini is suspended in the protected well using a 2.5 cm adapter ring (Fig. 32).
Immediately after installing the OTT Orpheus Mini, the sampling interval was set to
record water level and temperature every six minutes using the OTT Water Logger
Operating Program. The time of every action, such as placing the batteries, deploying the
logger in the water or adjusting it to the appropriate level was recorded throughout the
study. Batteries were easily replaced by removing the pipe encasing the communication
unit located at the top. Water depth and time was recorded each visit to ensure accuracy
of the data. Sensors were placed ~1 cm above ground level to prevent sediment build-up
potentially blocking sensors.
Two HOBO water level loggers were deployed using cinder blocks as a method for
attachment (Fig. 33). The water level logger was also housed in a PVC pipe for
biofouling protection and was attached to the cinder block using zip-ties. HOBOs were
deployed in the main tidal creeks (WLL16 and 17) because the Orpheus Minis were not
capable of being completely submerged. HOBOs were attached to PVC wells using thin
nylon rope. One HOBO (WLL18) was used in a high marsh environment. An extra
HOBO was reserved as a backup.
Surveying Loggers
The elevation of the water level logger was measured using a RTK GPS at the top of
the logger as well as the base, so that water depth data can be converted from relative
depth to elevation or a tidal datum to allow for comparison among sites. Horizontal
69
coordinates were set to NAD83, vertical coordinates were set to NAVD88 using the
hybrid geoid model GEOID09. RTK GPS uses Virtual Reference Stations (VRS) as base
stations in order to reduce initialization time. The use of a network of reference stations
instead of a single reference station allows to model the systematic errors in the region,
which reduces the possibility of error (Landau et al. 2002). The VRS network stations are
continuously connected to a control center, gathering information from all receivers.
Initially the GPS rover needs a minimum of three reference stations that are connected to
the network server. Using VRS GPS, the rover sends its position to the control center
using a mobile phone data link. The control center then accepts the position and responds
by sending RTCM correction data to the rover to compute a high quality DGPS position
solution, and update its position. The network server calculates new RTCM corrections,
so that they appear to come from a station right beside the rover to give DGPS solutions
accurate to within 2 cm in the horizontal plane and 4 cm in the vertical direction (Landau
et al. 2002; Petovello 2011). During measurements and maintenance, it is critical that the
logger remain in the same location otherwise the elevation of the logger must be surveyed
each time the logger is moved.
Programming Data Logger
Data logger settings were set directly by connecting the device to a computer using an
IrDA – Link adapter (OTT) and a Coupler (HOBO). For each site, the measurement
station number and name was adjusted in the operating program to have a unique
identification for referencing. Time was adjusted to match the computer for consistency
in Universal Time Coordinate (UTC). After water level loggers were installed, water
level values were instantly viewed on the computer software program and corrected
70
respectively. Sampling interval for this study was adjusted to six minutes to match the
Texas Coastal Ocean Observation Network (TCOON) tidal gauge measurements for
reference.
Maintenance Work
The pressure probes were cleaned every other week to prevent accumulation of
barnacles, and heavy contamination due to algae, mud or sediment. Data was always
collected before cleaning the pressure probe. The pressure probe was cleaned easily by
removing the black protective cap from the sensor (OTT). Sensors were cleaned carefully
using a small brush (OTT) or using a cotton swap (HOBO). After probes were cleaned
they were placed carefully back into the well.
Assessing Hydroperiod
Start and end times of duration and depth of the flooding event for each sediment
plate was determined from survey data. Survey data was used to calculate the difference
in elevations between the sediment plate and the nearest water level logger to determine
water level estimates at the sediment plate (Fig. 34). The hydroperiod data was summed
for each sampling interval in order to establish the flooding regime during the sampling
period. From survey data, flood duration events, flood duration events with time and
depth, max water level, and number of flooding events were calculated. Duration (min)
was calculated using the summation of minutes that the sediment plate was flooded.
Duration in time and depth was calculated using the minutes the plate was flooded
multiplied by the depth (water column) during each six-minute interval. Number of
flooding events is simply the total count the sediment plate was exposed based on
71
elevation and water level as explained by Fig. 35. Distance to tidal creek from each
sediment plate was determined using a least cost path analysis in ArcMap 10.2. Least cost
path tool utilized a digital elevation model to create a slope and cost back-link raster.
Fig. 34 Schematic of hydroperiod measurements at sediment plates using nearest water level logger.
Fig. 35 Example of how number of flooding events were counted. F1 indicates 1
st count of flooding event,
and continues to F4, so in this example Number of Flooding Events = 4 (number of time sediment plate
was exposed after initial flooding event).
Sediment Plate Flooded
Wat
er L
evel
(m
)
Time
F1 F2 F3 F4
72
Sediment Plates
For each water level logger in this study, there was a corresponding set of sediment
plates, with the exception of all HOBOs. The sediment plates were made of plexiglass 7.5
cm in diameter and 3 mm thick similar to plates used by Kleiss (1993) (Fig. 36). A hole
1.5 cm in diameter was made in the center to attach a threaded PVC rod and threaded
nylon washer to secure the plate. There were 30 sediment plates installed: 11 in high
marsh (HM); 9 in low marsh (LM); and 10 in high and low tidal flat (TF) environments
(Fig. 37). They were left to accumulate sediment approximately every 2 weeks from July
2014 to July 2015. RTK GPS measurements were taken recording x, y, z coordinates for
each sediment plate. Sediment plate sites were chosen following the criteria below:
Criteria for sediment plate locations for this study:
Must be within 1 m of the marker horizons
Preference given to grouped markers
Fig. 36 Circular sediment plate modeled after Kleiss (1993). Diagram of sediment plate (left), sediment
plate example from low marsh environment after flooding event (right).
73
Fig. 37 Sediment plate distribution on Mustang Island, TX.
Sediment plates were revisited approximately every two weeks depending on an
event of heavy precipitation. When revisiting, sediment traps were removed to carefully
collect the accumulated sediment on top and placed in a sealed jar. Sediment adhering to
the bottom of the plate was removed in the field. Removed sediment plates were replaced
by clean ones each time. Sediment plates were left in place if they were flooded more
than 2 cm at the time of collection. In the lab sediment samples from the plates were
placed in pre-weighed jars washed with distilled water. Samples were then dried at 60˚C
for 24 hours or more if needed and weighed to calculate mass sedimentation rates,
expressed as g cm-2
. Sediment deposition was calculated by dividing the number of grams
by the surface area of the circular plate (minus the surface area of the threaded rod).
74
Samples with sufficient sediment were split to analyze grain size, and organic/inorganic
matter.
Sediment Characterization
Organic Matter Content
Organic matter methods were similar to Chapter 2.
Grain Size
Sediment grain size methods were similar to Chapter 2.
Results
A few months after water level loggers were deployed in July 2014 a few water
level loggers began to lose function over time. By the end of the study, two water level
loggers remained accurate (WLL4 and WLL8) and one (WLL9) was replaced with an
extra HOBO water level logger (Fig. 31). WLL14 and WLL15 were not included in any
data analysis. WLL data only includes accurate water level logger data up to the point of
water level logger failure for analysis. Because of this loss, there were several sediment
plates that were collected, but did not have hydroperiod data thus reducing data.
Hydroperiod
Influence on Sediment Deposition
Initial data exploration was performed using a pairs plot to observe relationships
among all factors, which include duration of flooding (min), duration in time and depth
(min*m), max water level, number of flooding events, and distance to tidal creek. The
relationships between sediment deposition and hydroperiod variables were tested by
multiple regression analysis. Variable inflation factors were computed to determine if
there was significant collinearity among the predictor variables. Based on this
75
information, as well as an exhaustive search of all linear models, a preliminary model
was made using the following criteria:
1. Small Akaike’s Information Criterion correction (AICc) values, based on
maximum likelihood fittings
2. Significance level of α = 0.1 for any variable included
3. And diagnostics at least as good as comparable models
The diagnostic tests, which include normality, heteroscedasticity, and Cook’s distance, of
the final model were checked to ensure that any model inference was valid.
Before plotting data observations, all sediment plates that accreted from
bioturbation (N=35) were removed from data analysis to prevent skewed results.
Accretion caused by bioturbation from fiddler crabs was common throughout the study.
An initial scatterplot of the deposition on the sediment plates for each sampling period
and location (N= 293) showed no significant correlation with duration (p > 0.1, Fig. 38a).
Sediment plates that were estimated to be flooded however did show a slight correlation
(Fig. 38b). Relationships between deposition and duration for both scenarios (all
sediment plates and only flooded sediment plates) show a slight positive correlation when
converting the y-axis to log-scale, although there is a substantial amount of variation of
deposition for durations near zero (Fig. 38 c, d). A few algal flat environments had the
longest duration, but very little accretion, while some algal flat environments were hardly
flooded. Lower plots flooded more frequently than higher plots as shown by the
significant negative correlation between Frequency and Elevation (p < 0.1; r2= 0.18),
although a substantial amount of variation is left unexplained. The variation in marsh
topography combined with wind processes had a clear effect on sediment deposition.
76
It is expected that sites with a longer hydroperiod would have increased
deposition; therefore, a separate scatterplot was created to only include sediment plates
that lie along the main tidal creek (N= 50). Plates included: LM1, LM2, LM4, LM8,
LM10 (Fig. 37). Sediment deposition for plates near the main tidal creek had a
significantly positive correlation with number of flooding events and duration in time and
depth (Fig. 39). Using plates closer to the tidal creek significantly improved the
correlation with duration and flooding events (p < 0.1); although diagnostics plots
indicated there were some slight problems with heteroscedasticity caused by two
influential points (Fig. 39).
77
Fig. 38 Relationship of sediment plate deposition with flooding duration in time and depth. a) all sediment plates, b) only sediment plates
that were flooded, c) all sediment plates with y-axis log scaled, d) only flooded sediment plates with y-axis log-scaled.
78
Fig. 39 Relationship of sediment plate deposition with number of flooding events (a) and duration in time and depth (b) for plates in low marsh environments
near the main tidal creek only.
79
Several linear models were evaluated and further reduced to the equation in Fig.
39a which includes Number of Flooding Events as the fixed factor. The linear equation
including Number of Flooding Evens was chosen as the best model based on the criteria
preciously stated. Although a separate model, which included both Number of Flooding
Events and Duration in Time and Depth as fixed factors, explained a higher percent of the
variability in deposition, it was eliminated because the Duration in Time and Depth factor
was not significant after adjusting for heteroscedasticity (p > 0.1). Using Number of
Flooding Events, 50% of the variation in sediment deposition can be explained
significantly (p <0.1). The r2 value decreased slightly from 62% to 52% for linear
equation in Fig. 39a after fixing heteroscedasticity.
Organic and Inorganic Matter Associated with Hydroperiod
Relative contributions of organic and inorganic matter were calculated from the
weight of the sediment accumulation and results from LOI methods as follows:
𝑂𝑟𝑔𝑎𝑛𝑖𝑐 𝐴𝑐𝑐𝑢𝑚𝑢𝑙𝑎𝑡𝑖𝑜𝑛 (𝑔 𝑐𝑚−2) = 𝐿𝑂𝐼/100 (%) ∗ 𝑆𝑒𝑑𝑖𝑚𝑒𝑛𝑡 𝐷𝑒𝑝𝑜𝑠𝑖𝑡𝑖𝑜𝑛 (𝑔 𝑐𝑚−2)
𝐼𝑛𝑜𝑟𝑔𝑎𝑛𝑖𝑐 𝐴𝑐𝑐𝑢𝑚𝑢𝑙𝑎𝑡𝑖𝑜𝑛 (𝑔 𝑐𝑚−2)= 𝑆𝑒𝑑𝑖𝑚𝑒𝑛𝑡 𝐷𝑒𝑝𝑜𝑠𝑖𝑡𝑖𝑜𝑛 (𝑔 𝑐𝑚−2) − 𝑂𝑟𝑔𝑎𝑛𝑖𝑐 𝐴𝑐𝑐𝑢𝑚𝑢𝑙𝑎𝑡𝑖𝑜𝑛 (𝑔 𝑐𝑚−2)
Hydroperiod exerted a positive influence on organic and inorganic accumulation
processes for sediment plates (N=16) near the main tidal creek (Fig. 40). Organic and
inorganic matter contributions were both significantly correlated with the duration of the
plates (p < 0.1). Duration in Time and Depth of flooding explained 64% and 79% of
variation in accumulation of inorganic and organic matter respectively. Once again
diagnostic tests indicated very slight problems with heteroscedasticity caused by the two
influential points. This was only a slight problem for the linear model including inorganic
accumulation. There were no diagnostic problems for the linear model including organic
80
matter accumulation. Heteroscedasticity was not drastic enough to use variance functions
to correct problems. Plates closest to the main tidal creek (LM4 and LM8) had the highest
accumulation for both organic (~0.12 g cm-2
) and inorganic matter (~ 1.5 g cm-2
) (Fig.
40). Accumulation of matter does not take into account sediment porosity, density, or
water content.
Fig. 40 Relationship between accumulation of both organic and inorganic matter with duration in time and
depth. Accumulation of matter does not take into account sediment porosity, density or water content.
Water Levels
Water level calculations were estimates of how much water should be on the
marsh surface. The data does not take into account ponding effects that could possibly
increase duration and frequency for sediment plates. Water level patterns were highly
dependent on local proximity to tidal creeks and heavy rainfall. Duration of total flooding
81
events considering all sites (N= 293) ranged from 102 minutes in a high marsh
environment with sparse short grass to 336,732 minutes (~233 days) in a low tidal flat
environment with no vegetation covered by a thick layer of algal mat. These longer
flooding events were related to prolonged stagnant high-water across tidal flat
environments during September caused by high tides coupled with heavy local rainfall
throughout the winter and spring. The deepest flooding event for plates along the main
tidal creek occurred during September 28, 2014 (Fig. 41). LM2 was the deepest plate
flooded with a maximum water level of 43 cm (Fig. 41). Water level readings near the
main tidal creek indicate a seasonal hydroperiod pattern throughout the study with the
most flooding events occurring during Fall/Winter and Late Spring (Fig. 41).
Fig. 41 Water level referenced to NAVD88 near main tidal creek, including sediment plate elevations.
Horizontal lines represent elevation of sediment plates on the marsh surface.
82
Grain Size Analysis
To explore potential influences on sediment deposition, grain size analysis of
sediment samples was conducted. Only sediment samples with sufficient sediment for
both grain size and organic matter were split for analysis. If sediment samples from plates
did not have sufficient sediment they were combined with other sediment samples from
the same plate location. Grain sizes from sediment plate samples with no bioturbation
(N=49) throughout the year were analyzed (Fig. 42). Lower elevations (0.1 m -0.3 m)
were mostly silty-sand and sandy-silt according to the Shepard classification (Fig. 42b).
These areas are also classified as algal mats, and low marsh environments (Fig. 42a).
Grain sizes from sediment plates with no bioturbation near the main tidal creek (N=
15) were plotted separately for further observations (Fig. 43). Plates closest to the main
tidal creek (LM4 and LM8) had a grain size range from sand to silty sand (Fig. 43a).
These plates consisted of Avicennia germinans and Spartina alterniflora vegetation (Fig.
43b). LM1 and LM10 plates are at a slightly higher elevation relative to LM4 and LM8
(Fig. 41) and were classified as sand with vegetation cover consisting of succulents and
mangroves. Although LM2 has the lowest elevation it is also the farthest from the main
tidal creek (Fig. 37).
83
Fig. 42 Sediment grain size for all sediment plates, excludes plates with bioturbation. a) grain size classified by vegetation type, b) grain size classified by range
of elevation.
84
Fig. 43 Sediment grain size for plates near the main tidal creek, excludes plates with bioturbation. a) grain size classified by sediment plate ID, b) grain size
classified by vegetation type.
85
Discussion
Bioturbation was the main process for several sediment plates, but there is
skepticism by some whether this qualifies as true deposition or redistribution of sediment
already on the marsh surface. For the purpose of this study, sediment plates that accreted
due to bioturbation were omitted from analysis of results. Bioturbation was detectable by
the presence of small pellets formed from fiddler crabs.
There are several factors that influence sediment deposition, as shown by the lack
of correlation between deposition and duration and time and depth and high variation
near zero in Fig. 38. The highest deposition of 37.8 g cm-2
occurred in a low marsh
environment near a dry tidal creek. This occurred in late August 2014, accreting about
10.2 cm in a period of approximately two weeks. Two other plates (LM9 and HM9) also
along the northwest side of the salt marsh also accumulated high amounts of sediment
(7.3 and 6.68 g cm-2
, respectively) in an earlier period during late-July 2014. The
accretion for LM9 was 3.95 cm, and the accretion for HM9 was 2.45 cm over a period of
two weeks. Strong southeasterly winds were the main process driving sediment accretion
for these episodic events (Fig. 38a). Aeolian suspended sediment accumulation varied
widely over short time periods and distances across the marsh surface. At the other end of
the spectrum, there were plates that were flooded throughout most of the study (TF5 and
TF6), but accreted very little sediment. Accretion for these sediment plates occurred from
the stagnant water that lingered throughout the year eventually creating a new layer of
algal mat, about 4mm thick. The low r2 value for sediment deposition versus duration in
time and depth using all sediment plates (N=293) indicates that factors in addition to
hydroperiod had a strong influence on deposition throughout the study (Fig. 38a).
86
Previous studies for marshes on the U.S. east coast suggests that the hydrological
patterns influence the microtopography of the marsh surface through a combination of
sedimentation and erosion in a feedback with hydrological patterns that create the
microtopography on a fine scale (Frey et al. 1985). Storms however, can influence the
microtopography on a larger scale. Sedimentation deposition has been known to be
closely related to major washover events from storms for this area. Sediment deposition
through aeolian processes is also a major factor for this area due to the arid, wind-
dominated climate associated with Mustang Island, TX. Hence the results focused on
sediment plates near the main tidal creek. Results did not include tidal plates near the
most northern tidal creek because culverts near a road further restricted tidal influences
for the area. Seasonal deposition patterns could not be observed using all sediment plates
because the sampling period of some plates, such as TF5 and TF6, carried across multiple
seasons due to prolonged flooding.
Influence of Hydroperiod on Deposition
The longest flooding event for plates near the main tidal creek was 77,970
minutes (54 days) occurring from May – June 2015. The maximum depth during this
period was 42 cm for LM4 and LM8 sediment plates. The high water was caused by an
extended period of heavy rainfall in both months (Fig. 44). Tropical Storm Bill (June 16,
2015) may have influenced prolonged inundation for the area. Total rainfall throughout
the study was above average caused by the effects of a moderate El Nino, which is
expected to continue through fall 2015 and gradually weaken by spring 2016 (NOAA
2015). The total rainfall for the 2015 water year which began on October 1, 2014 was
113.51 cm which is 41.19 cm above average (NOAA 2015).
87
Fig. 44 Precipitation and wind direction and magnitude throughout the study period. Y-axis represents precipitation in centimeters. Stick plot shows
wind direction and magnitude (scaled relatively to each other). Winds pointing north (90˚) indicate winds are coming from the south headed north
88
Accumulation of sediment was strongly correlated with both flooding duration
and number of flooding events (Fig. 39). However, the relationship explains less than
40% and 62% of the variation in sediment deposition, respectively, because not all
inundations contribute the same amount of sediment. The correlation between deposition
and flooding duration is slightly influenced by the LM4 and LM8 plates, located on the
far right in Fig. 39, which were flooded during the period of May and June 2015. It may
be that the few large events, such as Tropical Storm Bill, during the May/June sampling
period accounted for most of sediment deposited on top of these plates (Fig. 44). This
was also the same time period when two cement blocks were swept away, one of which
was anchoring WLL16. The absence of the heavy cement blocks (~35lbs) helps to
visualize the strength of the currents from Tropical Storm Bill within the tidal creek that
may have attributed to such high deposition. Storms are a major influence on sediment
delivery, distribution, and deposition within Mustang Island because of the absence of a
riverine source.
Contribution of Organic and Inorganic Matter Associated with Hydroperiod
When focusing on organic and inorganic accumulation both have a strong positive
correlation with duration although inorganic matter has a larger contribution. Comparing
accumulation rates of both organic and inorganic matter in marshes of this study and of a
study in Louisiana (D. R. Cahoon and Reed 1995), results indicate that organic matter
accumulation eventually reaches a limit, and is dominated by inorganic matter (Fig. 45).
The relationship implies that organic matter was delivered to the marsh surface during
flooding events. Overall results support observations in other research that sedimentation
89
can be episodic, and that sediment delivery is not consistent for each marsh surface
inundation (Wood and Hine 2007).
Fig. 45 A comparison of the relationship between accumulation of both organic and inorganic matter and
duration of flooding (log10 scaled x-axis) in the present study, using sediment plates near the main tidal
creek, and in a study in Louisiana.
The most important factor in determining sediment deposition on sediment plates
located near the main tidal creek was the number of flooding events, suggesting that
deposition increases as frequency of flooding events increases. Thus an increase in
frequency of flooding events allows suspended sediments within the water column to
potentially be deposited on the marsh surface. The interpretation of the model should be
taken cautiously for several reasons. There were two major influential points (LM4 and
LM8) that caused the linear model to have problems with heteroscedasticity. Before
fixing problems, duration (count) and duration (integral) were highly significant,
explaining a large portion of the variation of deposition. The final model, however, gives
the best estimate available and can be used to predict the expected deposition results for
0.0
0.5
1.0
1.5
2.0
2.5
100 1000 10000Duration (hrs)
Acc
um
ula
tio
n o
f M
atte
r (g
/cm
sq)
Louisiana Study (Cahoon & Reed, 1995)
This StudyInorganic Matter Organic Matter
90
areas near the main tidal creek. The model does not work in areas further from the tidal
creek because of the dynamic environment strongly influenced by wind processes.
Grain Size
Sediments along the backside of Mustang Island are transported by aeolian,
overwash, inlet migration, or tidal process. Previous studies have attempted to
differentiate wetland environments on Mustang Island with sediment grain size
characteristics, but this has proven to be difficult because of the uniformity of sediments
in the area (Simms et al. 2006; Radosavljevic 2011). The present study used the sediment
that was deposited onto the plate for grain size analysis as opposed to previous studies
that used samples from the top 5cm.
Simms et al. (2006) and Radosavljevic (2011) were able to effectively differentiate
beach and dune sediments from barrier flat environments by observing the relationship
between skewness and mean grain size (Fig. 46). Skewness is a measure of the amount of
asymmetry in a grain size distribution compared to a normal distribution. A skewness
value of 0.2 has been determined as a threshold to differentiate between sediments
deposited by wind and finer skewed barrier flat environments. Results from this study are
very similar to previous studies (Fig. 46 and 47). Sediment grain size using all sediment
plates (N=293) suggests algal flat, and a few low marsh environments have finer sand,
classified as silty sand, and sandy silt, which contributes to the asymmetry in skewness.
Algal mat and low marsh environments are known to be much more effective at trapping
fine sediment (Frantz et al. 2015), which helps explain the gap around the skewness
threshold of 0.2 for algal flat and low marsh environments and other environments (Fig.
47). The relationship between skewness and mean grain size indicates most low marsh
91
sediments fall above the 0.2 threshold suggesting that sediments are deposited by tidal
processes. Plates at higher elevations, such as high marsh and high tidal flats also show a
trend of more symmetrical grain size distributions, thus majority lie below the 0.2
skewness thresholds (Fig. 47). This could possibly be due to the aeolian processes driving
sediment transport to those areas.
92
Fig. 46 Mean grain size analysis and skewness from Simms et al., (2006) and Radosavljevic, (2011).
0.0
0.2
0.4
0.6
0.8
0 2 4 6Mean (phi)
Skew
nes
s
Beaches
Core data
Dunes
Eolian Flats
Simms et al.(2006)
0.0
0.2
0.4
0.6
0.8
0 2 4 6Mean (phi)
Skew
nes
s
Facies
Eolian Flat
High Marsh
Low Flat
Low Marsh
Tidal Flat
Washover Fan 1
Washver Fan 2
Radosavljevic, (2011)
93
Fig. 47 Mean grain size analysis and skewness for this study.
Sediment Plate Technique
The advantages of using sediment plates is that they are easy to install, are
more robust and are less likely to be interrupted by erosion. Sediment plates are
ideal for areas that do not experience significant erosion, such as the high marsh
region. Disadvantages include: sediment plates allow for only one measurement
when the sediment is removed for analysis.
0.0
0.2
0.4
0.6
0.8
0 2 4 6Mean (phi)
Skew
nes
s
High Marsh
High Tidal Flat
Low Marsh
Low Tidal Flat
This Study
94
Conclusion
In general aeolian sediment transport is a significant mechanism for
sediment deposition on marsh surfaces further from tidal creeks. Two windy
events produced elevated deposition rates of greater than 2cm and contributing
ten times as much accretion than occurs in one year. Although the deposition was
highly episodic across the marsh, sediment deposition correlated well with
number of flooding events, and duration for plates near the main tidal creek. The
total accumulation deposited on plates was dominated by inorganic sediments,
suggesting there is a limit of detrital organic matter contribution for this area.
95
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