- Email: [email protected]
Dissolved organic matter and trace element variability in a blackwater-fed bay following precipitation
Journal Pre-proof Dissolved organic matter and trace element variability in a blackwater-fed bay following precipitation M.S. Sankar, Padmanava Dash, YueHan Lu, Varun Paul, Andrew E. Mercer, Zikri Arslan, Jac J. Varco, John C. Rodgers PII:
S0272-7714(19)30325-7
DOI:
https://doi.org/10.1016/j.ecss.2019.106452
Reference:
YECSS 106452
To appear in:
Estuarine, Coastal and Shelf Science
Received Date: 29 March 2019 Revised Date:
21 October 2019
Accepted Date: 25 October 2019
Please cite this article as: Sankar, M.S., Dash, P., Lu, Y., Paul, V., Mercer, A.E., Arslan, Z., Varco, J.J., Rodgers, J.C., Dissolved organic matter and trace element variability in a blackwater-fed bay following precipitation, Estuarine, Coastal and Shelf Science (2019), doi: https://doi.org/10.1016/ j.ecss.2019.106452. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.
1
Dissolved organic matter and trace element variability in a blackwater-fed
2
bay following precipitation
3 4
M. S. Sankar1, Padmanava Dash1*, YueHan Lu2, Varun Paul1, Andrew E. Mercer1, Zikri
5
Arslan3, Jac J. Varco4, John C. Rodgers1
6 7
1
Department of Geosciences, Mississippi State University, Mississippi State, MS 39762, USA
8
2
Department of Geological Sciences, University of Alabama, Tuscaloosa, AL 35487, USA
9
3
Department of Chemistry & Biochemistry, Jackson State University, Jackson, MS 39217, USA
10
4
Department of Plant & Soil Sciences, Mississippi State University, Mississippi State, MS
11
39762, USA
12 13 14 15
*Corresponding author: Department of Geosciences, Mississippi State University, Mississippi
16
State, MS 39762. Room # 109B, Hilbun Hall, Email: [email protected], Phone: 001-662-325-
17
0364, Fax: 001-662-325-9423
18 19 20 21 1
22
Abstract
23
Dissolved organic matter (DOM) often forms complexes with trace metals. The main objective
24
of this study was to identify the sources of trace elements to a coastal bay that is fed by two
25
blackwater rivers using DOM compositions. Surface water samples from twelve sites in Weeks
26
Bay, Alabama were collected during four field trips and a bottom sediment sample was collected
27
during one of the trips. Spectroscopic measurements in tandem with parallel factor analysis and
28
multivariate statistics were used to derive DOM compositions and inductively coupled plasma
29
mass spectrometry was used for determining trace metal concentrations. DOM chemistry and
30
trace element concentrations together with precipitation and discharge, watershed land use and
31
land cover data, and physicochemical parameters were used to determine the source of trace
32
elements in the adjoining areas of the watershed to the bay and finally settling into the bay
33
sediments. Arsenic, copper, and uranium fluxes increased while fluxes of mercury, zinc,
34
manganese, and iron decreased following precipitation events. Concentration of all trace
35
elements analyzed were 10,000 times higer in the bay botton sediments than their concentrations
36
in the water colunmn. Microbially reprocessed and soil derived DOM components increased
37
along with the trace elements and nutrients in the bay as a result of precipitation whereas
38
concentration of terrestrial humic-like DOM component remained the same during both dry
39
(spring) and wet (summer and fall) periods. Principal component analysis revealed significant
40
correlations between Microbially reprocessed DOM and the trace elements including arsenic,
41
copper and uranium indicating urban, pasture, and agricultural areas in the watershed were the
42
sources for these trace metals. On the other hand, multiple sources were identified for
43
manganese, zinc, and iron. Overall it was found that DOM compositions are useful for inferring
44
the possible sources and mobility of trace elements in aquatic systems.
2
45
Keywords: Dissolved organic matter; Trace elements; Weeks Bay; Precipitation events; EEM-
46
PARAFAC; PCA
47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 3
68 69
1. Introduction It has been recently reported that shallow Mississippi deltaic sediments serve as a source
70
of iron, manganese, and arsenic to the water column and redox reactions in the deltaic marshes
71
control the availability of trace elements like molybdenum, tungsten, arsenic, vanadium in the
72
coastal waters (Joung and Shiller, 2016; Telfeyan et al., 2018, 2017). The contamination of
73
mercury in the estuaries, bays and offshore regions of northern Gulf of Mexico (NGoM) has
74
been attributed to urban and agricultural runoff as well as atmospheric deposition (Apeti et al.,
75
2012; Lewis and Chancy, 2008). Consensus is yet to be reached regarding the source of these
76
trace elements, despite the associated contamination being one of the major problems adversely
77
impacting many forms of life in these coastal waterbodies (Lafabrie et al., 2011; Lewis and
78
Russell, 2015; Perry et al., 2015). Naturally occurring DOM is a complex mixture of different
79
organic compounds which can form complexes with trace elements, hence trace elements often
80
co-occur and covary with DOM of different origins (Yamashita and Jaffé, 2008). Based on DOM
81
composition, a substantial amount of humified terrestrial and some protein-like DOM
82
components were identified along the coastal water bodies of the southern US (Sankar et al.,
83
2018; Shank et al., 2011; Singh et al., 2010). Rivers and streams flowing into these coastal
84
waterbodies drain agricultural, forested and urbanized hinterlands and transport high amount of
85
dissolved nitrate, phosphate, carbon, and trace elements (Lafabrie et al., 2011; Reuter and
86
Perdue, 1977; Sankar et al., 2018; Stolpe et al., 2010; USEPA, 1999). There is a strong
87
correlation between the amount of water discharged and the quantity of organic matter delivered
88
through the coastal rivers of the United States (Keul et al., 2010; Reuter and Perdue, 1977; Zhou
89
et al., 2016). Specific studies have been conducted to understand the role of DOM in the
90
mobilization of trace elements (Hongxia et al., 2014; Reuter and Perdue, 1977; Stolpe et al.,
4
91
2010; Zhou et al., 2016). Strong metal binding capacity of both bacterially derived and soil
92
derived humic DOM compositions have been widely reported (Gu et al., 2011; Hongxia et al.,
93
2014; Reuter and Perdue, 1977). For instance, dissolved and colloidal trace elements, along with
94
nutrients and DOM are transported by Mississippi-Atchafalaya river system (Duan et al., 2007;
95
Stolpe et al., 2010; Zhou et al., 2016). This association might have important consequences in
96
terms of delivery and accumulation of toxic trace elements, such as arsenic, manganese, copper,
97
nickel, uranium, mercury, zinc, and nutrients including nitrate and phosphate along the
98
Mississippi deltaic sediments (Joung and Shiller, 2014, 2016; Slowey and Hood, 1971; Stolpe et
99
al., 2010).
100
Weeks Bay is a small coastal water body located near the city of Mobile (3rd most
101
populous city in Alabama) and is connected to NGoM through Mobile Bay. The freshwater input
102
into Weeks Bay is through two blackwater rivers, Fish River in the north and Magnolia River in
103
the southeast. Blackwater rivers are quite common all along the coastal areas of the southern US
104
and are connected to NGoM through estuaries and bays (Ruecker et al., 2017). They drain
105
extensive forested wetlands, thereby transporting brown colored water rich in soil-derived DOM
106
to coastal oceans (Spencer et al., 2013). Previous studies have shown that soil-derived DOM is
107
efficient in mobilizing trace elements via complexation (Benedetti et al., 1996; Tribovillard et
108
al., 2004; Weng et al., 2002). We hypothesized that these blackwater rivers are the main conduits
109
for not only DOM but also for toxic trace element transport into the coastal water bodies as a
110
result of rapid urbanization and industrialization in the southeastern US. We further hypothesised
111
that following precipitation events, the concentration of trace metals co-varied with specific
112
DOM components in the bay, and the DOM composition can be utilized to identify the source of
113
DOM and in turn, the trace elements. Hence, our objectives were to (1) determine the trace
5
114
element-DOM compositional associations, and (2) evaluate the changes in composition and
115
concentration of DOM and trace elements delivered into the Weeks Bay, NGoM in relation to
116
the average amount of precipitation in the watershed.
117
2. Materials and Methods
118
2.1 Study area, sample location and land use/ land cover analysis
119
Weeks Bay is fed by black water rivers and located on the eastern side of the Mobile Bay
120
in Baldwin County, coastal Alabama (Fig.1). It is designated as the 16th national estuarine
121
research reserve (NERR) of the US in 1986, hosting a wide variety of aquatic plants and animal
122
species. It is a shallow micro tidal tributary estuary (Camacho et al., 2014). The Weeks Bay
123
watershed covers a total area of 520.87 km2 and the Weeks Bay is a shallow water body with an
124
average depth of 2 m covering an area of 4.72 km2 (0.91% of the total watershed area). It
125
empties into the larger Mobile Bay through a narrow opening and the average water residence
126
time of Weeks Bay is 5 days (Caffrey et al., 2014). Two rivers flow into the bay; Fish River in
127
the north and Magnolia River in the south-east. To delineate the drainage basins of these two
128
rivers, hydrologic unit code-12 (HUC-12) boundary datasets for the Weeks Bay watershed were
129
downloaded from the United States Department of Agriculture (USDA) data gateway and 10 m
130
resolution digital elevation models were downloaded from the United States Geological Survey
131
(USGS) National Map download client. The digital elevation models and the HUC-12 watershed
132
boundary datasets were used in Arc-GIS 10.4.1 platform to delineate the drainage basins of the
133
Fish and Magnolia Rivers emptying to the Weeks Bay. Subsequently, the land use and land
134
cover dataset of 2015 was downloaded from the USDA data gateway and cropped using the
135
delineated watershed boundary for determining the areas covering each major land use and land
136
cover. It was found that the bay and associated river channels are surrounded by emergent 6
137
herbaceous wetlands (6.46 km2, 1.24 %), woody wetlands (67.62 km2, 12.98 %) and evergreen
138
forest (72.88 km2, 13.99 %) (Table 1). Cultivated cropland and pasture make up the major part of
139
the watershed (127.52 km2, 24.48 % and 98.94 km2, 19.00 %). Urbanized areas (68.38 km2,
140
13.13 %) were located on the northwestern and northern parts along Fish River and along the
141
southeastern areas of Magnolia River.
142
Four field campaigns were conducted to measure in situ water quality parameters and
143
collect water samples. Twelve water samples were collected during the campaigns on
144
05.09.2016, 06.19.2016 and 09.30.2016, while thirteen samples and a bay bottom sediment were
145
collected during the campaign on 06.26.2016 (Fig. 1). Water samples were collected from
146
locations distributed all along the bay in clean, acid-washed 1-liter high density polyethylene
147
(HDPE) bottles following the protocol explained in Dash et al. (2015). Sediment from the bottom
148
of the bay was collected using an extendable grab sampler and was stored in an O2-impermeable
149
Remel®bag. Water quality parameters including pH, oxidation-reduction potential (ORP, mV),
150
dissolved oxygen (DO, mg/L), total dissolved solids (TDS, mg/L), salinity (PSU) and water
151
temperature (°C) were collected from each sampling location during every field campaign by
152
using a HANNA® extendable probe. The collected water and sediment samples were stored in an
153
airtight cooler filled with ice and transported back to the lab. Water samples were filtered using
154
0.2 µm Whatman® nuclepore track-etch membrane filters, stored in amber colored glass bottles,
155
and refrigerated at 4°C until spectroscopic analysis of colored dissolved organic matter (CDOM).
156
The samples for dissolved organic carbon (DOC), total dissolved nitrogen (TDN), and anions
157
(nutrients) analyses were stored in acid washed 20 mL HDPE bottles and kept frozen in a -80 °C
158
freezer until analysis. The water samples for cations (trace elements) were acidified using
159
Fisherbrand® ultrapure nitric acid (0.2 %) and stored in acid washed and pre-combusted 20 mL
7
160
glass bottles and stored in room temperature until analysis following the U.S. Geological Survey
161
and U. S. Environmental Protection Agency protocols (USGS, 1999; USEPA, 1983).
162
The field campaigns were planned in accordance with precipitation events and the
163
corresponding river water discharge into the bay (Fig.2). Discharge data were obtained from the
164
United States Geological Survey (USGS) national water information system web interface. The
165
USGS discharge gauges were located at Magnolia River (USGS 02378300) and Fish River
166
(USGS 02378500). Daily average precipitation data for the Weeks Bay watershed was obtained
167
from National Weather Service (NWS) rainfall plots.
168
2.2 Water sample analysis, CDOM indices and PARAFAC modeling
169
Trace elements; arsenic (As), manganese (Mn), zinc (Zn), copper (Cu), mercury (Hg)
170
uranium (U) and iron (Fe) were analyzed using inductively coupled plasma mass spectrometry
171
(ICP-MS). Nutrients including phosphate (PO43-), nitrate (NO3-), ammonium (NH4+) and nitrite
172
(NO2-) anions were analyzed using a continuous flow auto-analyzer (Skalar Analytical Inc.,
173
Buford, GA) at Dauphin Island Sea Lab. The DOC and TDN content of the water samples were
174
measured on a SHIMADZU® total organic carbon-total nitrogen analyzer (TOCv-TNM1)
175
equipped with an ASI-V autosampler following the method described in Shang et al., 2018.
176
Toxicity of trace elements and nutrients were expressed in terms of the Unites States
177
Environmental Protection Agency (US EPA) recommended water quality criteria.
178
CDOM absorption was analyzed in a PerkinElmer® Lambda 850 UV/VIS double-beam
179
spectrophotometer (Waltham, MA, USA) following the analytical procedure described in Singh
180
et al., 2017. Absorption spectra of the samples and blank (deionized water, 18.2 mΩ purity) were
181
collected between 200nm and 750nm wavelengths at 2 nm interval in a clean 4 mL quartz
182
cuvette with 1cm path length. Effects of background and scattering were removed by subtracting 8
183
the absorption spectra of the samples from the blank. The blank subtracted sample absorbance
184
(A) was used to calculate Napierian absorption coefficient (a) at each wavelength (λ) (Fichot and
185
Benner, 2012; Singh et al., 2017; Zhang et al., 2013). Absorption coefficients were used to
186
calculate specific UV absorbance (SUVA254) by dividing absorption coefficient at 254nm by
187
DOC concentration (Lmg-1m-1). The slope ratio (SR) is the ratio of absorption coefficient
188
between 275 and 295 nm to that between 350 and 400 nm. Values of SUVA254 are directly
189
proportional to aromaticity of DOM, while SR values are inversely related to the molecular
190
weight of DOM in the water sample (Hansen et al., 2016; Kothawala et al., 2014; H. Lin et al.,
191
2016; Singh et al., 2017).
192
Fluorescence properties of the water samples (Excitation emission matrix, EEM) were
193
analyzed using Horiba® Jobin Yvon Inc., Fluoromax-4 spectrofluorometer (Edison, NJ, USA)
194
following the analytical procedure explained in Sankar et al., 2018. After applying company
195
specified instrumental corrections and calibrations, the EEMs of the samples and blanks
196
(deionized water,18.2 mΩ purity) were measured with excitation wavelengths of 240-450nm at
197
every 10 nm increment and emission wavelengths of 300-550nm at every 2nm increment. After
198
removing inner filter effects; the blank corrected and Raman normalized EEMs were used for
199
PARAFAC modeling (Kothawala et al., 2013; Singh et al., 2017; Stedmon and Markager, 2005).
200
Fluorescence Index (FI), Humification Index (HIX) and Biological Index (BIX) or Freshness
201
Index were calculated using the corrected EEMs. The calculation steps for these indices can be
202
found in Hansen et al., 2016 and elsewhere. The FI index indicates the source of DOM, which
203
can either be microbial (with high FI, between 1.6-2.0, usually derived from extracellular release
204
and leachate from bacteria and algae) or terrestrial (with low FI, between 1.2-1.5, usually from
205
terrestrial plants and soil organic matter). HIX can be used as a proxy for humification of natural
9
206
organic matter. An increase in HIX values indicates the condensation of fluorescent molecules
207
and decrease in the H/C ratio of DOM. The BIX is an indicator of the freshness of DOM. High
208
BIX values (>1) indicate freshly released DOM as a result of autochthonous production in the
209
aquatic system. On the other hand, low values of BIX (0.6-0.7) indicate less autochthonous
210
production of DOM in the water body (Huguet et al., 2009)
211
A total of 49 sample EEMs were used for PARAFAC modeling. After removal of the
212
outliers, the sample size was reduced to 46. Out of the 46 sample EEMs, 11 were following the
213
spring sampling event (9th May 2016), 12 each following summer-1 (19th June 2016) and
214
summer-2 (26th June 2016) sampling events, and 11 were following the fall sampling event (30th
215
September 2016). To avoid abnormalities during the modeling, the EEMs were normalized using
216
Raman integrated area at 350 nm excitation and 397 nm emission over 5 nm bandpass. Prior to
217
PARAFAC modeling, the excitation wavelengths were interpolated at 5 nm increments, and
218
emission wavelengths were interpolated at 4nm increments. A four component PARAFAC
219
model which explained 99.96 % variance of the data was validated by split half analysis using
220
Tucker congruence coefficients and random initialization. The scores of the PARAFAC
221
components (fluorescence intensity maximum, Fmax) were expressed in Raman units (R.U). The
222
DOMFluor tool box in MATLAB®- R2018a computing platform was used to create the
223
PARAFAC model (Stedmon and Bro, 2008).
224
2.3 Sediment characterization and geochemical analysis
225
The mineralogical characterization of the bay bottom sediment was carried out using a
226
Rigaku Ultima III X-ray diffractometer with a graphite monochromator and scintillation detector
227
at I2AT laboratory, Mississippi State University. The sample was pulverized and homogenized
228
using an agate mortar and piston and analyzed over 0° to 90° (2θ) angle. 10
229
Trace element analysis of the bay bottom sediment sample in duplicates were carried out
230
for As, Mn, U, Cu, Zn, Hg, and Fe. 0.5 gm of homogenized sediment sample and its duplicate
231
were digested using concentrated trace metal grade nitric acid and 30 % hydrogen peroxide on a
232
hot plate at 90°C following the EPA protocol (method SW-846 3050B). The digestate was later
233
refluxed using concentrated trace metal grade hydrochloric acid and then diluted to 50 mL using
234
deionized water before the ICP-MS analysis for As, Mn, U, Cu, Zn and Fe. The concentration of
235
Hg in bay bottom sediment was analyzed separately by cold vapor atomic absorption (CVAA)
236
spectroscopy (SW-846 Method 7471B). The soil standard reference material (PR-LCSSRM-
237
00018 B/ERA-550/http.eraqc.com) was also analyzed to estimate recovery.
238
2.4 Statistical Analysis
239
The R-version 3.3.2 (R® Core Team) programming platform was used for the statistical
240
analysis of all the measured and observed data. Principal Component Analysis (PCA) was
241
performed on PARAFAC components, fluorescence indices, absorption indices, water quality
242
parameters, and fluxes of DOC, TDN, nutrients, and trace elements to understand their
243
relationship. Bootstrap resampling statistics at confidence intervals of 2.5%, 50%, and 97.5%
244
was applied to trace element concentrations to estimate whether they were significantly different
245
statistically following different precipitation events by taking 1000 means (1000 replicates).
246
Mann-Whitney-Wilcoxon Test was used to explain the significant increase or decrease in
247
PARAFAC components from spring with low amount of precipitation to fall with high amount
248
of precipitation. The SUVA254 values showed minimum variation between the seasons hence,
249
One-way ANOVA was performed to understand the variance between and among the SUVA254
250
values during four sampling events. Tukey-HSD pairwise multiple comparisons post-hoc
251
analysis was also performed to find the significance in differences between SUVA254 values 11
252
following precipitation events. All of the statistical analyses were performed at 95% confidence
253
level (α=0.05). Maximum, minimum, average (mean) and standard deviation were calculated for
254
all the measured parameters. Interquartile range (IQR) was calculated for expressing the
255
variability in the observations. Data values greater than 3 times the IQR or above the third
256
quartile in the box plot were presented as outliers. Both p-value (t-test of regression, α=0.05) and
257
r value or correlation coefficient (0.5>r≥0.3 weak, 0.7>r≥0.5 moderate and r≥0.7 strong
258
relationship) were estimated to represent the significance, strength, and direction of the
259
relationship among the variables.
260
3. Results
261
3.1 Temporal changes in water quality and chemistry in response to seasonal meteorological
262
events
263
Monthly meteorological data for the year 2016 revealed that average precipitation in the
264
Weeks Bay watershed was higher during September 2016 (mean=8.49 mm, max=49.53 mm,
265
min=0 mm) followed by June 2016 (mean=5.60 mm, max=47.50 mm, min=0 mm) and May
266
2016 (mean=3.05 mm, max= 27.43 mm, min=0 mm). The precipitation events in the watershed
267
were marked by a sudden increase in water discharge into the bay through both rivers (Fig.2).
268
The average discharge of Fish and Magnolia Rivers during the months of September, June and
269
May 2016 were 2.11±0.79 m3/s, 2.38±0.82 m3/s, 3 .20±2.57 m3/s and 1.19±1.42 m3/s, 0.74±0.34
270
m3/s, 0.77±0.32 m3/s. The Fish River is larger yet displayed a greater increase in discharge than
271
the Magnolia River. As such, our sampling campaigns represented four seasonal precipitation
272
conditions, we coined spring for 9th May 2016, summer-1 for 19th June 2016, summer-2 for 26th
273
June 2016 and fall for 30th September 2016. The average amount of precipitation in the
274
watershed over five days prior to the sampling events is used for describing the variations during 12
275
each of the sampling events (Table 2). It is also important to note that the soil profile of entire
276
region remained wet with rainwater following 26th of June 2016 (summer-2) due to the
277
prevalence of rain events from the month of June 2016 onwards. Similarly, several precipitation
278
events were observed in September 2016.
279
Water quality parameters (pH, ORP, TDS, Salinity, DO, water temperature) of the bay
280
exhibited changes in accordance with seasonal precipitation and corresponding discharge events
281
(Table 3). The pH, TDS, and salinity showed an increasing trend, while both ORP and DO
282
values decreased with precipitation and discharge. pH values following fall precipitation event
283
were higher than the pH following spring precipitation event. The steady increase in pH from
284
spring to fall through summer precipitation events in the bay indicates freshwater input following
285
precipitation events. Net negative ORP values of the bay during all field sessions show the
286
prevalence of reducing condition. The water temperature was variable following spring
287
precipitation event compared to the summer and fall. It is important to note that high tides were
288
coinciding during water sampling following the summer-1 (0.52 m), summer-2 (0.40 m), and fall
289
precipitation events (0.40 m), while low tides coincided during sampling following the spring
290
precipitation (0.3 m) event (www.tidesandcurrents.noaa.gov).
291
The flux of trace elements, nutrients, DOC and TDN were calculated by multiplying their
292
concentration with five-day average river discharge to evaluate their variability between three
293
different seasons. While their actual concentrations were used to explain their toxicity if they had
294
exceeded EPA recommended water quality criteria for saltwater (EPA, 2018). The average flux
295
of As (20.75±1.29 mgs-1 to 43.46± 10.09 mgs-1), U (1.62±0.39 mgs-1 to 2.41±0.62 mgs-1) and Cu
296
(1.82±0.33 mgs-1 to 73.30±78.81 mgs-1) in the bay showed an increase in trend following the
297
spring precipitation event to fall precipitation event (Fig. 3). On the contrary, the average flux of 13
298
Hg (0.42±0.13 mgs-1 to 0.21± 0.63 mgs-1), Fe (1432.19±563.30 mgs-1 to 444.15±146.15 mgs-1),
299
Mn (268.53±83.02 mgs-1 to 156.50±31.16 mgs-1), and Zn (9.04± 8.69 mgs-1 to 3.45±1.45 mgs-1)
300
showed a general decrease in trend from spring precipitation event to fall precipitation event.
301
Arsenic concentrations were highly variable between sites following the fall precipitation event
302
(IQR=10.99) with an average value of 23.31±5.41 µgL-1 (SI Fig. 1). The maximum variability of
303
Cu flux between sites was observed following fall precipitation event (IQR= 79.72) and for U it
304
was following summer-1 precipitation event (IQR=1.25). Cu concentrations exceeded the EPA
305
recommended water quality criteria of 4.8 µgL-1 for acute toxicity and 3.1 µgL-1 for chronic
306
toxicity (EPA, 2018) following the fall precipitation event with an average concentration of
307
39.30±42.26 µgL-1 and at one site near the mouth of Fish River following the summer-1
308
precipitation event with a concentration of 14.39 µgL-1. The average concentration of Zn was
309
2.91±6.97 µgL-1 with maximum variation of flux between sites following the spring precipitation
310
event (IQR= 4.96). Fluxes of Hg, Fe, and Mn showed highest variation between sites following
311
the spring precipitation event (IQR=0.21; 624.27; 116.77). The average concentration of Mn was
312
always high and with an average concentration of 92.98±27.01 µgL-1. Concentration of Fe
313
following summer-1, summer-2, and fall precipitation events were lower (avg=235.57±73.03
314
µgL-1) compared to its concentration following the spring precipitation event
315
(avg=455.39±179.11 µgL-1). On the contrary, the Hg concentration was always below its toxicity
316
limits (EPA recommended water quality criteria for salt water 1.8 µgL-1 for acute toxicity and
317
0.94 µgL-1 for chronic toxicity (EPA, 2018)) with an average value of 0.08±0.11 µgL-1 except of
318
one site where the concentration was 1.17 µgL-1 near the mouth of the Weeks Bay Estuary to the
319
Mobile Bay (SI Fig. 1).
14
320
There was an increase in the average flux of both NO3- (214.84± 155.78 mgs-1 to
321
4211.34± 1550.98 mgs-1) and PO43- (109.27± 39.74 mgs-1 to 389.37± 122.09 mgs-1) from spring
322
to fall precipitation events. However, PO43- showed slight decrease in flux following the
323
summer-2 precipitation event. On the other hand, both NH4+and NO2- showed no such trend in
324
flux (Fig. 4). The greatest variation of PO43- flux was following the high precipitation event
325
(IQR= 184.65), and for NO3-, it was following the summer-1 precipitation event (IQR= 1724.69).
326
Both NH4+ and NO2- showed maximum variation following the low precipitation event (IQR=
327
469.37 and 439.25). The average concentrations of NO3-, NO2-, and NH4+ were 1267.41±478.78
328
µgL-1, 40.84±71.11 µgL-1 and, 24.93±28.26 µgL-1, respectively. PO43- concentrations were high
329
in all sampling locations following the high precipitation event (mean= 208.78± 65.46 µgL-1,
330
max= 303.91 µgL-1) and at one location following the moderately high precipitation event
331
(112.07 µgL-1) (SI Fig. 2).
332
Average flux and variation of both DOC and TDN were high following the spring
333
precipitation event compared to other sampling seasons (IQR= 2207.004; 2111.396) (Fig. 4).
334
During other three field campaigns, the flux of both DOC and TDN remained nearly same with
335
5582.79± 309.14 mgs-1; 636.61± 149.93 mgs-1, respectively, yet DOC showed a slight increase in
336
flux (mean= 7414.85± 352.73 mgs-1) following the fall precipitation event compared to the
337
summer-2 precipitation event (3979.49± 286.07 mgs-1). The actual concentration of DOC and
338
TDN is given in the supplementary material (SI. Fig. 2).
339
The fluxes of trace elements such as As, Cu, U and nutrients such as PO4-, NO3-, and
340
NO2- showed an increasing trend, while the fluxes of Fe, Mn, Zn, NH4+, DOC and TDN showed
341
a decreasing trend with salinity of the bay (SI. Fig. 4 & 5).
342
3.2 Seasonal variation of spectroscopic properties and development of PARAFAC model 15
343
The mean values of SUVA254 were high following both spring (6.68±1.43 L mg-1m-1) and
344
summer-1 precipitation events (7.50±0.63 L mg-1m-1) compared to both summer-2 (5.31±0.43 L
345
mg-1m-1) and fall precipitation events (5.89±0.39 L mg-1m-1) (Fig.5). On the other hand, average
346
values of SR showed a general increase in trend from spring (1.27±0.04) to fall precipitation
347
event (1.51±0.35) with maximum variation following the fall precipitation event (IQR= 0.43).
348
The mean values of both FI and BIX also increased from spring precipitation
349
(FI=1.44±0.02, BIX=0.65±0.02) to fall precipitation (FI=1.47±0.02, BIX=0.71±0.03) event (Fig.
350
5). The maximum variation of FI was following the summer-1 precipitation event (IQR= 0.043),
351
while for BIX it was the same following the fall-precipitation and summer-1 precipitation events
352
(IQR= 0.04). However, BIX values were always less than 1 during all field campaigns
353
(avg=0.69±0.04, max=0.77, min=0.60). The mean values of HIX remained nearly the same
354
following all the four field campaigns (0.76±0.05). The variation of HIX was maximum
355
following both fall and summer-2 precipitation events (IQR=0.08 and 0.07).
356
The PARAFAC analysis of the Weeks Bay water samples collected during the four field
357
campaigns in three different seasons resulted in a four-component model (C1, C2, C3, and C4).
358
The PARAFAC component C1 was a terrestrial, humic-like component; C2 was a microbial,
359
humic-like component; C3 was an allochthonous, terrestrial component or soil-derived
360
component; and C4 was a microbial tryptophan-like component (Fig. 6, Table 4). Components
361
C2, C3, and C4 showed a general increase of 7.61%, 11.19%, and C4=27.61%, respectively, in
362
average fluorescence intensity (Fmax) in the bay from spring precipitation to fall precipitation
363
events (Fig. 7). However, component C2 showed a slight decrease (2.18 %) in fluorescence
364
intensity from summer-2 to fall precipitation events. On the other hand, component C1 showed
365
limited change in average fluorescence intensity and had less variability during all seasons. The 16
366
components C2, C3, and C4 showed slightly higher variation in Fmax values with IQR of 0.03,
367
0.04 and 0.03, respectively, following the summer-1 precipitation event compared to other
368
precipitation events (Fig. 7).
369
3.3 Bottom sediment characterization and chemistry
370
Total digestion of Weeks Bay bottom sediment sample revealed the presence of Mn
371
(110.00±0.00 mg/Kg); Zn (30.00±1.41 mg/Kg); As (7.75±0.21 mg/Kg); Cu (4.05±0.07 mg/Kg);
372
U (2.35±0.07 mg/Kg); Hg (0.03±0.00 mg/Kg) and Fe (19500.00±707.11 mg/Kg). The recovery
373
of the above trace elements from the standard reference material (PR_LCSSRM_00018) was
374
above 95%. However, the XRD analysis of the bottom sediment revealed complete absence of
375
As, Cu, U, Mn, Zn, and Hg bearing minerals, with the presence of two predominant minerals:
376
Quartz (SiO2: 97.2%), and Pyrite (FeS2: 2.8%) (SI. Fig.3).
377
3.4 Statistical Results
378
To evaluate the change in water chemistry of the bay in response to precipitation in the
379
watershed and corresponding river water discharge, we used PCA analysis of PARAFAC
380
components, optical indices, DOC flux, TDN flux, inorganic ions (trace elements and nutrients)
381
flux, and water quality parameters (Fig. 8). The two principal components (PC); PC1 and PC2,
382
together explained 49.50 % of the total variance of the data. The presence of both microbial
383
PARAFAC components C2, C4 and the soil derived component C3 along with high FI, BIX, SR
384
on the positive side of the PC1 indicates allochthonous anthropogenic and some terrestrial soil
385
input. Whereas the presence of high SUVA254 and HIX along with PARAFAC component C1
386
along the negative side of the PC1 indicates terrestrial input. The HIX is inversely related to
387
component C3. The TDS, salinity, pH, nutrients (PO4, NO3-, NO2-), and the trace elements As, U,
17
388
and Cu were associated with microbial humic-like or protein-like PARAFAC component C4.
389
The ammonium ion (NH4+) and the trace elements Mn and Zn were associated with terrestrial
390
humic-like PARAFAC components C1. Hg and Fe showed no association with any PARAFAC
391
components, yet both were strongly associated with DOC and TDN. The ORP and DO were
392
present along the negative side of the PC1 axis and also directly related to both Fe and Hg.
393
Among the samples collected following all the precipitation events, all fall precipitation events
394
were located on the positive side of the PC1 axis, while all the samples representing the spring
395
precipitation events were positioned on the negative side of the PC1 axis. Whilst both summer
396
samples were located on the negative side of the PC2 axis. Additionally, positive relationship of
397
SUVA254 against Zn flux and FI against U flux and the negative relationship of component C4
398
vs Mn were also seen (SI. Fig.6)
399
Bootstrap resampling method at confidence intervals 2.5%, 50%, 97.5% was applied to
400
the flux of trace elements (As, Mn, U, Cu, Zn, Hg, Fe) following four field campaigns (Fig. 9).
401
The bootstrap results revealed that there was a significantly high flux of As, Cu and U in the bay
402
following the fall precipitation event compared to summer-1, summer-2 and spring precipitation
403
events (Table 5). In contrast, the flux of Hg, Mn, and Fe were significantly higher statistically
404
following the spring precipitation event than the summer-1, summer-2 and fall precipitation
405
events. The flux of Mn to the bay showed a statistically significant decrease from spring
406
precipitation event to summer-2 precipitation event. The flux of Zn to the bay was statistically
407
similar but higher following both spring and summer-1 precipitation events compared to its flux
408
following summer-2 and fall precipitation events.
409 410
The one-way ANOVA analysis indicated that variability of SUVA254 between the four sampling events (mean square=11.30) and the variability within each precipitation event (mean 18
411
square=0.69) are significantly different (F=16.46), therefore mean SUVA254 of each sampling
412
event is significantly different (p<0.05) from one another. Tukey-HSD pairwise multiple
413
comparison post-hoc analyses indicated similar mean SUVA254 following the summer-2 and fall
414
(p>0.05) precipitation events. The mean SUVA254 following the summer-2 and spring
415
precipitation events were the same and following the spring and fall precipitation events were
416
also the same (p>0.05). Mann-Whitney-Wilcoxon Test confirmed a significant (p<0.05) increase
417
in PARAFAC components C2, C3, and C4 from spring to fall precipitation events with U values
418
of 118, 104, and 118, respectively, while the component C1 showed no significant change
419
(p>0.05, U=72) following the precipitation events.
420
4. Discussion
421
4.1 Water and sediment chemistry
422
The concentration of Cu in Weeks Bay exceeded the EPA recommended water quality
423
criteria both for acute and chronic toxicity for aquatic life following the fall precipitation event.
424
On the other hand, the concentrations of other trace elements including U, Zn, Hg, As, Mn, and
425
Fe, and nutrients including NO3- and NO2- in the bay were lower than the EPA recommended
426
water quality criteria (EPA, 2018). Yet it is important to note that even at such low
427
concentrations, their regular input and concurrent deposition can lead to their enrichment in the
428
bay bottom sediments over time and also bioaccumulation/magnification of these trace metals in
429
aquatic organisms.
430
The flux of As, U, and Cu along with PO4- and NO3- into the bay increased following
431
increase in precipitation in the watershed (Figs. 3 and 4). Their co-occurrence and the
432
simultaneous increase in flux were not surprising as the predominant land use land cover of the
19
433
watershed surrounding Weeks Bay is agricultural land (cultivated crops-24.48%, hay and
434
pasture-19.00%). The application of phosphate-based fertilizers, micronutrients containing Cu
435
and animal manure in those agricultural areas can be one of the possible sources for the
436
excessive influx of PO4-, NO3- and Cu (Bandyopadhyay et al., 2014; Hudak, 2000; Miller et al.,
437
2011). Moreover, phosphate-based fertilizers can be a source of As or it can enhance the release
438
of adsorbed As from the soil fraction, especially from iron oxyhydroxides (Jayasumana et al.,
439
2015; T. Y. Lin et al., 2016; Molina et al., 2009; Signes-Pastor et al., 2007), which is in
440
agreement with the significant strong positive relationship (p<0.05, r= 0.74) of As and PO43- flux
441
in the bay. Similarly, the concentration of As (7.75±0.21 mg/Kg), Cu (4.05±0.07 mg/Kg), and U
442
(2.35±0.07 mg/Kg) were also very high in the bottom sediments. While naturally occurring
443
pyrite containing As (S- and Fe2+ atoms were replaced by As) can be a source for As (Blanchard
444
et al., 2007; Le Pape et al., 2017), the absence of As-bearing pyrite (SI Fig. 3) and increase in
445
the flux of As along with U, Cu, PO43-, and NO3- into the bay (Fig. 3) clearly indicates an
446
external or anthropogenic source for As. Previous studies in the adjacent watersheds have
447
attributed enhanced concentrations of trace elements to external sources. Lafabrie et al. (2011)
448
reported high amount of As and Hg in the Fish River sediments and identified Warrior Coal
449
Field (coal enriched in As and Hg) located at northwestern corner of Mobile Bay watershed and
450
the chemical industrial plants located between Mobile Bay and Mobile-Tensaw Delta as the
451
possible sources. Zielinski et al. (2007) have also reported the presence of As, Hg, and U in the
452
feed coal and its derivative fly ash in the Warrior Coal Field. The increase in the flux of U along
453
with the flux of As and Cu in the bay in response to seasonal precipitation and discharge (spring
454
to fall) suggests additional sources of U from the watershed. There was no nuclear reactor near
455
the watershed. Although there are a couple of nuclear power plants in the state of Tennessee,
20
456
along the Tennessee River, the river is not connected to Weeks Bay. However, there are exposed
457
out crops of black shale formations present along the north-eastern Alabama, but no streams
458
flowing to Weeks Bay are connected to those outcrops. Hence, the possible source of U could be
459
the effluent of Warrior Coal Field, as the coal contains a substantial amount of U as an impurity
460
(Zielinski et al., 2007).
461
Overall there was a decrease in flux of Mn, Hg, Fe, and Zn in the bay from spring to fall
462
precipitation event. However, their concentrations in sediment (19500.00±707.11 mg/Kg;
463
110.00±0 mg/Kg; 30.00±1.41 mg/Kg; 0.03±0.00 mg/Kg) were very high, and their high flux in
464
bay following spring precipitation event may be due to the prevalence of higher reducing
465
conditions (lower ORP values) in the bay. Warrior Coal Field and the chemical industrial plants
466
in the watershed are likely the sources of Hg contamination in Weeks Bay. The concentration of
467
Hg was high following the spring precipitation event compared to the fall precipitation event
468
possibly because of dilution following the summer and fall precipitation events. Previous studies
469
have reported the presence of high concentrations of Mn, Zn, and Cu in the shallow regions of
470
the Gulf of Mexico and suggested their release from reductive dissolution of bottom sediments
471
via decomposing organic matter (Joung and Shiller, 2016; Slowey and Hood, 1971). Another
472
possible source of Mn and Zn could be fertilizer such as basic slag containing Ca, Mg, Mn, and
473
Zn commonly used in the agricultural areas of Southeastern United States. Also, application of
474
ammonium fertilizers can lead to nitrification and soil acidification that accelerates leaching of
475
cations adsorbed to soil.
476
Both NH4+ and NO2- fluxes were negatively related to NO3- flux (p >0.05, r= -0.31 and
477
p<0.05, r= -0.21) in the bay. The weak inverse relationship of both NH4+ and NO2- against NO3-
478
could be due to the active nitrification/denitrification process in the bay. The high flux of NO2-, 21
479
high amount of DO, and low flux of NO3- following spring precipitation event compared to their
480
concentration following the summer and fall precipitation events could indicate high anaerobic
481
denitrification process following spring precipitation and discharge (Kim et al., 2010).
482
High DOC was observed following the spring precipitation event compared to summer
483
and fall precipitation events possibly because of higher residence time of the river effluents in
484
Weeks Bay and vice versa. This pattern suggests that the input of DOC is hydrologically
485
controlled, that is, the flow path is shifted from deep, low-DOC soil horizons to shallow, high-
486
DOC horizons following spring with low amount of precipitation to fall with high amount of
487
precipitation events (Dalzell et al., 2007; Hu et al., 2016; Zhou et al., 2016). Thus our study
488
shows that the DOC flux into Weeks Bay and then to NGoM through Mobile Bay increases with
489
discharge.
490
Stolpe et al. (2010) reported the presence of U-CDOM colloids, Mn in Fe-rich colloids
491
and Cu-CDOM complexes in the Pearl, Mississippi, and Atchafalaya Rivers. A positive
492
correlation was observed between the fluxes of Fe and DOC in the bay following all precipitation
493
events (p<0.05, r=0.86) indicating their co-occurrence as Fe-DOM colloids. According to
494
Novotnik et al. (2018) the mobility of U is also controlled by its oxidation state and the presence
495
of complexing agents like inorganic carbon, PO43-, and DOM. We observed a significant positive
496
relationship (p<0.05, r=0.73) between the fluxes of U and PO43-, however we did also observe a
497
week but significant correlation between DOC and U (p<0.05, r=0.33) in our dataset, but did not
498
observe any correlation between Cu and DOC in Weeks Bay.
499
4.2 Variation DOM in response to precipitation
22
500
The variation of both absorption and fluorescence indices from low spring precipitation
501
through the moderate summer to high fall precipitation revealed the input of less humified,
502
simpler, low molecular weight, microbially reprocessed or protein-like DOM into the bay
503
following the precipitation events. The SUVA254 values had minimum change as a function of
504
precipitation and discharge, however the ANOVA analysis confirmed that the variability of
505
SUVA254 between and within each precipitation event were significantly different (p<0.05). The
506
difference in mean SUVA254 values following the three seasonal precipitation events (spring,
507
summer and fall) indicates DOM export from multiple sources. That is high aromatic and high
508
molecular weight DOM input from adjoining herbaceous wetlands, woody wetlands, and
509
evergreen forests and low aromatic DOM from the croplands, pasture, and urbanized areas (Lu et
510
al., 2013). Meanwhile, high value of SUVA254 following the event of summer-1 precipitation
511
could be due to higher input of soil-derived DOM along with other terrestrially derived DOM,
512
both with high aromatic character, into the bay from dry riparian areas and surrounding woody
513
herbaceous wetlands. The higher and fluctuating SUVA254 values during the events of
514
precipitation in summer and fall could also be due to the input of humic DOM from the coal
515
effluents from warrior coal fields. The release of humic substances from coal is been widely
516
reported (De Souza and Bragança, 2018; Valero et al., 2014). The SR values, proxy for DOM
517
molecular weight, were also high following the summer-1, summer-2 and fall precipitation
518
events compared to spring precipitation event indicating high influx of low molecular weight or
519
simpler microbial humic-like or protein-like DOM from the croplands, pasture, and urbanized
520
areas into the bay following the high amount of precipitation during the summer and fall seasons.
521
The BIX values were always less than one during all four trips indicating the dominance
522
of organic matter from external sources or allochthonous input. Increases in both BIX (10.26 %)
23
523
and FI (2.03 %) indices along with fluctuating HIX values as discharge increases also indicates
524
addition of fresh, microbially derived, DOM into the bay through the river discharge in response
525
to precipitation (Fig. 5). The sources for this pool of fresh microbial organic matter could be
526
human-modified lands such as croplands, pasture, and urbanized areas. Previous studies have
527
reported that agricultural and urban areas export DOM with enhanced signatures from microbial
528
sources (Lu et al., 2013; Sankar et al., 2018).
529
Concomitant increase protein-like (C2: U=118, p<0.05 and C4: U=118, p<0.05) and soil-
530
derived components (C3: U=104, p<0.05) and relatively constant input of terrestrial humic-like
531
(C1: U=72, p>0.05) component from the spring low precipitation through moderate to fall high
532
precipitation indicate continuous input of protein-like and soil derived DOM to the bay from
533
agricultural and urbanized areas following precipitation (Fig. 7). The reason for the low
534
variability of the component C1 during all field campaigns could be due to the continuous supply
535
of terrestrial humic-like DOM from the woody herbaceous wetlands present all along the banks
536
of the bay (Sankar et al., 2018). Furthermore, the component C1 has been found in multiple
537
studies as a background fluorescence in fluvial waters due to its refractory nature (Sankar et al.,
538
2018; Singh et al., 2017; 2010). The largest variation of soil derived DOM component (C3)
539
following summer-1 precipitation (IQR= 0.04) could be because of its large influx due to
540
flushing from within and above the dry soil horizons during the initial period of summer
541
precipitation.
542
Based on the variation of both optical indices and DOM composition, it is quite evident
543
that precipitation in the watershed has mobilized a considerable amount of allochthonous fresh
544
microbially reprocessed DOM into the bay from the Weeks Bay Watershed. Additionally, there
545
is a possibility of allochthonous microbially reprocessed DOM input into Weeks Bay through the 24
546
Mobile Bay from Mobile Bay Watershed especially during the events of high tides, however
547
more data is required from the Mobile Bay to ascertain this claim.
548
4.3 Relationship of salinity and dissolved constituents
549
The trace elements and nutrients showed a conservative mixing behavior in the Weeks Bay.
550
Increasing trends in the fluxes of As, Cu, U, NO3-, PO4-, and NO2- with increasing salinity was
551
observed because the field data collection during fall, summer-1, and summer-2 precipitation
552
events coinciding with high tides. Decreasing trends in the fluxes of Fe, Mn, Zn, Hg, and NH4+
553
with increasing salinity indicates their release from bay bottom owing to the highly reducing
554
conditions especially during spring precipitation events. The precipitation induced freshwater
555
input caused an increase in fluxes of As, Cu, U, NO3-, PO4- and NO2-. On the other hand,
556
prevalence of higher redox conditions in the bay bottom during dry weather conditions increased
557
the Fe, Mn, Zn, Hg concentrations along with NH4+ by dissolution of their oxidized forms. The
558
low inverse relationship of Hg and salinity suggests dilutionary effects during the events of
559
precipitation or atmospheric deposition and settling in the bay. The inverse relationship of DOC
560
and TDN with salinity supports the shifting of hydrology from spring low to fall high
561
precipitation events (SI Fig. 4 & 5).
562
4.4 DOM and trace element relationships
563
The samples collected following fall precipitation event were positioned all along the
564
positive side of the PC1 axis indicating protein-like or microbial humic-like DOM input into the
565
bay from the croplands, pasture, and urbanized areas of the watershed. On the contrary, both of
566
the samples collected following summer-1 and summer-2 precipitation events were located on
567
the negative side of the PC2 axis indicating more of microbially reprocessed and soil derived
25
568
DOM input into the bay following summer precipitation (Fig. 8). While all samples collected
569
following the spring precipitation event were in the negative side of the PC1 axis indicating less
570
microbial humic-like or protein-like and more terrestrial humic-like DOM input. The PCA plot
571
clearly shows a strong connection between the fresh, microbially or anthropogenically derived,
572
simpler DOM components (C2 and C4), the trace elements (As, Cu, U), and the nutrients (PO43-
573
and NO3-). Their mutual relationship clearly indicates that As, Cu, U and inorganic N and P
574
nutrients were flushed into the bay along with microbially derived DOM components (C2 and
575
C4) from the adjoining agricultural and urbanized areas (Fig 8 and SI. Fig.6). Furthermore, the
576
positive relationship of pH, with components C2, C4 along with As, Cu, U and PO43- and, NO3-
577
indicates that they entered the bay as the result of water discharge through the rivers following
578
the high amount of precipitation during both fall and summer seasons. Hg shows no correlation
579
with any of the PARAFAC components, nutrients, trace elements, or pH indicating its
580
introduction into the bay through atmospheric deposition or dilutionary effect due to its low
581
concentration. The strong positive relationship of Hg, DOC, and ORP could be due to the
582
formation of Hg-DOM complexes in the bay water under reducing conditions (Gu et al., 2011;
583
Harris et al., 2012; Ravichandran, 2004). A strong positive correlation of Fe and DOC indicates
584
the existence of Fe-DOM colloids in the bay (Stolpe et al., 2010). Similarly, the bootstrap
585
resampling technique also confirmed increase in flux of As, Cu and U with seasonal
586
precipitation, that is from spring to fall in the bay (Fig. 9). On the other hand, the flux of Hg, Mn,
587
and Fe to the bay was high following low amount of precipitation during the spring implying the
588
effect of dilution or the presence of low redox conditions (Table 3). We are also not ruling out
589
the fact that such change in trends of elemental flux in the bay could also be the result of the
26
590
change in redox conditions due to groundwater surface water interactions in the bay. However
591
we do not have associated groundwater data to prove such claim.
592
Only a few studies have evaluated the source of trace elements in the coastal areas of
593
NGoM (Lafabrie et al., 2011; Telfeyan et al., 2017; USEPA, 1999). In the present work, we
594
correlated DOM sources and its chemical properties with trace elements, which was found to be
595
effective in the identification of the source of trace elements. Our results suggest that
596
precipitation in the watershed and the subsequent water discharge through both the rivers into the
597
bay affected the quality and chemistry of the Weeks Bay water. In addition to freshwater
598
discharge from the Fish and Magnolia Rivers, Weeks Bay receives tidal flows from Mobile Bay
599
as well (Passeri et al., 2016). The amount of Mobile Bay water incursion to Weeks Bay or the
600
concentration of water quality parameters in the Mobile Bay was not investigated in this study.
601
However, trends of TDS and salinity in the Weeks Bay observed in this study were similar on all
602
four field campaigns, which can be attributed to tidal effects during the time of field work. The
603
DO concentration of an aqueous solution reduces in response to increase in salinity and
604
temperature (Lay et al., 2010), hence, the low DO content of the bay water following the events
605
of summer and fall precipitation were coinciding with both high salinity and temperature, and
606
high DO concentrations were coinciding with both low salinity and temperature following spring
607
with low amount of precipitation. Freshwater input into Mobile Bay happens mainly through the
608
Tombigbee River, the Alabama River, and their tributaries; which drains a much larger
609
watershed. We acknowledge that the incursion of water from Mobile Bay, which includes
610
freshwater from the Mobile Bay Watershed and seawater, to Weeks Bay may have an effect on
611
the water quality of the Weeks Bay especially during high tides. Collection of field data from the
27
612
Mobile Bay and adjoining coastal waters, and hydrodynamic modeling will help in quantifying
613
the effect of flow of Mobile Bay waters to Weeks Bay.
614
5. Conclusion
615
The trace element, nutrient, and DOM amount in the Weeks Bay was very much
616
dependent on precipitation in the watershed and subsequent water discharge into the bay through
617
the two blackwater rivers, Fish and Magnolia. Statistical analyses of water quality parameters
618
following spring low-fall high precipitation events indicated that the concentration of trace
619
elements As, Cu, and U, and the nutrients NO3- and PO43- were higher in the Weeks Bay
620
following fall high-precipitation events. Moreover, the availability of microbial humic-like or
621
protein-like DOM components increased in the bay along with soil-derived, humic component
622
following precipitation during summer and fall seasons. This clearly indicates that following the
623
fall precipitation, the trace elements As, Cu, and U are exported to the bay along with
624
microbially processed DOM from various anthropogenic sources present in the watershed such
625
as agricultural areas or industries. Further, the spectroscopic properties, BIX (< 1 during the
626
study period), FI (gradually increasing) and SUVA254 (decreasing) along with increasing
627
microbial humic-like, protein-like and soil-derived humic DOM components following higher
628
amount of summer and fall precipitation indicated that the trace metals were mobilized to the bay
629
along with allochthonous DOM. Results also revealed that the trace element and DOM fluxes in
630
Weeks Bay was largely dependent on hydrologic characteristics (precipitation and dishcarge)
631
and land use land cover. Future work may include exploring the inclursion of contaminants into
632
Weeks bay through Mobile Bay and its drainage system during high tides.
633 634
Increasing precipitation events are projected due to global climate change, which can affect DOM-trace element mobility in the coastal waterbodies. This study highlights the 28
635
importance of DOM composition in determining sources of trace elements in the watershed.
636
Increasing precipitation events are projected due to global climate change, which can affect
637
DOM-trace element mobility in the coastal waterbodies in the southern states and worldwide.
638
This study highlights the importance of DOM composition in determining sources of trace
639
elements in the watershed. Trace metals analysis can be time consuming and expensive., while
640
DOM fluorometric analysis is comparatively inexpensive. In this article we have demonstrated
641
the use of DOM composition as PARAFAC components to source track contaminant trace
642
element sources. This method can be utilized to identify the contaminant sources in other regions
643
around the globe.
644
Acknowledgement
645
The research was supported by the faculty start-up grant to Dr. Padmanava Dash. The authors are
646
thankful to Ms. Devon Flickinger and Mr. Rusch Ragland of Department of Geosciences,
647
Mississippi State University and Dr. Scott Phipps of the Weeks Bay National Estuarine Research
648
Reserve for their help during field campaigns.
649
References
650
Apeti, D.A., Lauenstein, G.G., Evans, D.W., 2012. Recent status of total mercury and methyl
651
mercury in the coastal waters of the northern Gulf of Mexico using oysters and sediments
652
from NOAA’s mussel watch program. Mar. Pollut. Bull. 64, 2399–2408.
653
doi:10.1016/j.marpolbul.2012.08.006
654
Bandyopadhyay, S., Ghosh, K., Varadachari, C., 2014. Multimicronutrient slow-release fertilizer
655
of zinc, iron, manganese, and copper. Int. J. Chem. Eng. 2014, 1–7.
656
doi:10.1155/2014/327153 29
657
Benedetti, M.F., Van Riemsdijk, W.H., Koopal, L.K., Kinniburgh, D.G., Gooddy, D.C., Milne,
658
C.J., 1996. Metal ion binding by natural organic matter: From the model to the field.
659
Geochim. Cosmochim. Acta 60, 2503–2513. doi:10.1016/0016-7037(96)00113-5
660
Blanchard, M., Alfredsson, M., Brodholt, J., Wright, K., Catlow, C.R.A., 2007. Arsenic
661
incorporation into FeS2pyrite and its influence on dissolution: A DFT study. Geochim.
662
Cosmochim. Acta 71, 624–630. doi:10.1016/j.gca.2006.09.021
663
Caffrey, J.M., Murrell, M.C., Amacker, K.S., Harper, J.W., Phipps, S., Woodrey, M.S., 2014.
664
Seasonal and Inter-annual Patterns in Primary Production, Respiration, and Net Ecosystem
665
Metabolism in Three Estuaries in the Northeast Gulf of Mexico. Estuaries and Coasts 37,
666
222–241. doi:10.1007/s12237-013-9701-5
667
Camacho, R.A., Martin, J.L., Diaz-Ramirez, J., McAnally, W., Rodriguez, H., Suscy, P., Zhang,
668
S., 2014. Uncertainty analysis of estuarine hydrodynamic models: An evaluation of input
669
data uncertainty in the Weeks Bay estuary, Alabama. Appl. Ocean Res. 47, 138–153.
670
doi:10.1016/j.apor.2014.04.004
671
Dalzell, B.J., Filley, T.R., Harbor, J.M., 2007. The role of hydrology in annual organic carbon
672
loads and terrestrial organic matter export from a midwestern agricultural watershed.
673
Geochim. Cosmochim. Acta 71, 1448–1462. doi:10.1016/j.gca.2006.12.009
674
De Souza, F., Bragança, S.R., 2018. Extraction and characterization of humic acid from coal for
675
the application as dispersant of ceramic powders. J. Mater. Res. Technol. 7, 254–260.
676
doi:10.1016/j.jmrt.2017.08.008
677 678
Duan, S., Bianchi, T.S., Sampere, T.P., 2007. Temporal variability in the composition and abundance of terrestrially-derived dissolved organic matter in the lower Mississippi and 30
679 680
Pearl Rivers. Mar. Chem. 103, 172–184. doi:10.1016/j.marchem.2006.07.003 Fichot, C.G., Benner, R., 2012. The spectral slope coefficient of chromophoric dissolved organic
681
matter (S275-295) as a tracer of terrigenous dissolved organic carbon in river-influenced
682
ocean margins. Limnol. Oceanogr. 57, 1453–1466. doi:10.4319/lo.2012.57.5.1453
683
Gu, B., Bian, Y., Miller, C.L., Dong, W., Jiang, X., Liang, L., 2011. Mercury reduction and
684
complexation by natural organic matter in anoxic environments. Proc. Natl. Acad. Sci. 108,
685
1479–1483. doi:10.1073/pnas.1008747108
686
Hansen, A.M., Kraus, T.E.C., Pellerin, B.A., Fleck, J.A., Downing, B.D., Bergamaschi, B.A.,
687
2016. Optical properties of dissolved organic matter (DOM): Effects of biological and
688
photolytic degradation. Limnol. Oceanogr. 61, 1015–1032. doi:10.1002/lno.10270
689
Harris, R., Pollman, C., Landing, W., Evans, D., Axelrad, D., Hutchinson, D., Morey, S.L.,
690
Rumbold, D., Dukhovskoy, D., Adams, D.H., Vijayaraghavan, K., Holmes, C., Atkinson,
691
R.D., Myers, T., Sunderland, E., 2012. Mercury in the Gulf of Mexico: Sources to
692
receptors. Environ. Res. 119, 42–52. doi:10.1016/j.envres.2012.08.001
693
Hongxia, Y., Jinxu, G., Wei, L., Keyan, T., 2014. Investigating the composition of dissolved
694
organic matter in natural water in rare earth mine using EEM-PARAFAC analysis. Environ.
695
Sci. Process. Impacts 16, 2527–2535. doi:10.1039/C4EM00380B
696
Hu, Y., Lu, Y., Edmonds, J.W., Liu, C., Wang, S., Das, O., Liu, J., Zheng, C., 2016.
697
Hydrological and Land Use Control of Watershed Exports of DOM in a Large Arid River
698
Basin in Northwestern China. J. Geophys. Res. Biogeosciences 121, 466–478.
699
doi:10.1002/2015JG003082
31
700 701 702
Hudak, P.F., 2000. Regional trends in nitrate content of Texas groundwater. J. Hydrol. 228, 37– 47. doi:10.1016/S0022-1694(99)00206-1 Huguet, A., Vacher, L., Relexans, S., Saubusse, S., Froidefond, J.M., Parlanti, E., 2009.
703
Properties of fluorescent dissolved organic matter in the Gironde Estuary. Org. Geochem.
704
40, 706–719. doi:10.1016/j.orggeochem.2009.03.002
705
Jayasumana, C., Fonseka, S., Fernando, A., Jayalath, K., Amarasinghe, M., Siribaddana, S.,
706
Gunatilake, S., Paranagama, P., 2015. Phosphate fertilizer is a main source of arsenic in
707
areas affected with chronic kidney disease of unknown etiology in Sri Lanka. Springerplus
708
4, 1–8. doi:10.1186/s40064-015-0868-z
709
Joung, D., Shiller, A.M., 2014. Dissolved barium behavior in Louisiana Shelf waters affected by
710
the Mississippi/Atchafalaya River mixing zone. Geochim. Cosmochim. Acta 141, 303–313.
711
doi:10.1016/j.gca.2014.06.021
712
Joung, D.J., Shiller, A.M., 2016. Temporal and spatial variations of dissolved and colloidal trace
713
elements in Louisiana Shelf waters. Mar. Chem. 181, 25–43.
714
doi:10.1016/j.marchem.2016.03.003
715
Keul, N., Morse, J.W., Wanninkhof, R., Gledhill, D.K., Bianchi, T.S., 2010. Carbonate
716
chemistry dynamics of surface waters in the Northern Gulf of Mexico. Aquat. Geochemistry
717
16, 337–351. doi:10.1007/s10498-010-9091-2
718
Kim, S.W., Miyahara, M., Fushinobu, S., Wakagi, T., Shoun, H., 2010. Nitrous oxide emission
719
from nitrifying activated sludge dependent on denitrification by ammonia-oxidizing
720
bacteria. Bioresour. Technol. 101, 3958–3963. doi:10.1016/j.biortech.2010.01.030
32
721
Kothawala, D.N.., Murphy, K.R.., Stedmon, C.A.., Weyhenmeyer, G.A.., Tranvik, L.J.., 2013.
722
Inner filter correction of dissolved organic matter fluorescence. Limnol. Oceanogr. Methods
723
11, 616–630. doi:10.4319/lom.2013.11.616
724
Kothawala, D.N., Stedmon, C.A., Müller, R.A., Weyhenmeyer, G.A., Köhler, S.J., Tranvik, L.J.,
725
2014. Controls of dissolved organic matter quality: Evidence from a large-scale boreal lake
726
survey. Glob. Chang. Biol. 20, 1101–1114. doi:10.1111/gcb.12488
727
Lafabrie, C., Major, K.M., Major, C.S., Cebrián, J., 2011. Arsenic and mercury bioaccumulation
728
in the aquatic plant, Vallisneria neotropicalis. Chemosphere 82, 1393–1400.
729
doi:10.1016/j.chemosphere.2010.11.070
730
Lay, W.C.L., Liu, Y., Fane, A.G., 2010. Impacts of salinity on the performance of high retention
731
membrane bioreactors for water reclamation: A review. Water Res. 44, 21–40.
732
doi:10.1016/j.watres.2009.09.026
733
Le Pape, P., Blanchard, M., Brest, J., Boulliard, J.C., Ikogou, M., Stetten, L., Wang, S., Landrot,
734
G., Morin, G., 2017. Arsenic Incorporation in Pyrite at Ambient Temperature at Both
735
Tetrahedral S-Iand Octahedral FeIISites: Evidence from EXAFS-DFT Analysis. Environ.
736
Sci. Technol. 51, 150–158. doi:10.1021/acs.est.6b03502
737
Lewis, M., Chancy, C., 2008. A summary of total mercury concentrations in flora and fauna near
738
common contaminant sources in the Gulf of Mexico. Chemosphere 70, 2016–2024.
739
doi:10.1016/j.chemosphere.2007.09.020
740
Lewis, M.A., Russell, M.J., 2015. Contaminant profiles for surface water, sediment, flora and
741
fauna associated with the mangrove fringe along middle and lower eastern Tampa Bay.
742
Mar. Pollut. Bull. 95, 273–282. doi:10.1016/j.marpolbul.2015.04.001 33
743
Lin, H., Chen, M., Zeng, J., Li, Q., Jia, R., Sun, X., Zheng, M., Qiu, Y., 2016. Size
744
characteristics of chromophoric dissolved organic matter in the Chukchi Sea. J. Geophys.
745
Res. Ocean. 121, 6403–6417. doi:10.1002/2016JC011771
746
Lin, T.Y., Wei, C.C., Huang, C.W., Chang, C.H., Hsu, F.L., Liao, V.H.C., 2016. Both
747
Phosphorus Fertilizers and Indigenous Bacteria Enhance Arsenic Release into Groundwater
748
in Arsenic-Contaminated Aquifers. J. Agric. Food Chem. 64, 2214–2222.
749
doi:10.1021/acs.jafc.6b00253
750
Lu, Y., Bauer, J.E., Canuel, E.A., Yamashita, Y., Chambers, R.M., Jaffé, R., 2013.
751
Photochemical and microbial alteration of dissolved organic matter in temperate headwater
752
streams associated with different land use. J. Geophys. Res. Biogeosciences 118, 566–580.
753
doi:10.1002/jgrg.20048
754
Miller, M.., Phipps, S.W., Major, C.S., Major, K.M., 2011. Effects of Environmental Variation
755
and Non-point Source (NPS) Nutrient Pollution on Aquatic Plant Communities in Weeks
756
Bay National Estuarine Research Reserve (WBNERR), AL. Estuaries and Coasts (2011) 34,
757
1182–1193. doi:10.1007/s12237-011-9422-6
758
Molina, M., Aburto, F., Calderón, R., Cazanga, M., Escudey, M., 2009. Trace element
759
composition of selected fertilizers used in Chile: Phosphorus fertilizers as a source of long-
760
term soil contamination. Soil Sediment Contam. 18, 497–511.
761
doi:10.1080/15320380902962320
762
Perry, H., Isphording, W., Trigg, C., Riedel, R., 2015. Heavy metals in red crabs, Chaceon
763
quinquedens, from the Gulf of Mexico. Mar. Pollut. Bull. 101, 845–851.
764
doi:10.1016/j.marpolbul.2015.11.020 34
765 766 767 768 769
Ravichandran, M., 2004. Interactions between mercury and dissolved organic matter - A review. Chemosphere 55, 319–331. doi:10.1016/j.chemosphere.2003.11.011 Reuter, J.H., Perdue, E.M., 1977. Importance of heavy metal - organic matter interactions in natural waters. Geochim. Cosmochim. Acta 41, 325–334. Ruecker, A., Uzun, H., Karanfil, T., Tsui, M.T.K., Chow, A.T., 2017. Disinfection byproduct
770
precursor dynamics and water treatability during an extreme flooding event in a coastal
771
blackwater river in southeastern United States. Chemosphere 188, 90–98.
772
doi:10.1016/j.chemosphere.2017.08.122
773
Sankar, M.S., Dash, P., Singh, S., Lu, Y.H., Mercer, A.E., Chen, S., 2018. Effect of photo-
774
biodegradation and biodegradation on the biogeochemical cycling of dissolved organic
775
matter across diverse surface water bodies. J. Environ. Sci. (China) 1–18.
776
doi:10.1016/j.jes.2018.06.021
777
Shank, G.C., Evans, A., Yamashita, Y., Jaffé, R., 2011. Solar radiation-enhanced dissolution of
778
particulate organic matter from coastal marine sediments. Limnol. Oceanogr. 56, 577–588.
779
doi:10.4319/lo.2011.56.2.0577
780
Signes-Pastor, A., Burló, F., Mitra, K., Carbonell-Barrachina, A.A., 2007. Arsenic
781
biogeochemistry as affected by phosphorus fertilizer addition, redox potential and pH in a
782
west Bengal (India) soil. Geoderma 137, 504–510. doi:10.1016/j.geoderma.2006.10.012
783
Singh, S., D’Sa, E.J., Swenson, E.M., 2010. Chromophoric dissolved organic matter (CDOM)
784
variability in Barataria Basin using excitation-emission matrix (EEM) fluorescence and
785
parallel factor analysis (PARAFAC). Sci. Total Environ. 408, 3211–3222.
786
doi:10.1016/j.scitotenv.2010.03.044 35
787
Singh, S., Dash, P., Silwal, S., Feng, G., Adeli, A., Moorhead, R.J., 2017. Influence of land use
788
and land cover on the spatial variability of dissolved organic matter in multiple aquatic
789
environments. Environ. Sci. Pollut. Res. doi:10.1007/s11356-017-8917-5
790
Slowey, F.J., Hood, D.W., 1971. Copper, manganese and zinc concentrations in Gulf of Mexico
791
waters. Geochim. Cosmochim. Acta 35, 121–138. doi:https://doi.org/10.1016/0016-
792
7037(71)90052-4
793
Spencer, R.G.M., Aiken, G.R., Dornblaser, M.M., Butler, K.D., Holmes, R.M., Fiske, G., Mann,
794
P.J., Stubbins, A., 2013. Chromophoric dissolved organic matter export from U.S. rivers.
795
Geophys. Res. Lett. 40, 1575–1579. doi:10.1002/grl.50357
796
Stedmon, C. a., Bro, R., 2008. OCEANOGRAPHY : METHODS Characterizing dissolved
797
organic matter fluorescence with parallel factor analysis : a tutorial. Limnol. Oceanogr.
798
Methods 6, 572–579. doi:10.4319/lom.2008.6.572
799
Stedmon, C. a., Markager, S., 2005. Tracing the production and degradation of autochthonous
800
fractions of dissolved organic matter using fluorescence analysis. Limnol. Oceanogr. 50,
801
1415–1426. doi:10.4319/lo.2005.50.5.1415
802
Stolpe, B., Guo, L., Shiller, A.M., Hassellov, M., 2010. Size and composition of colloidal
803
organic matter and trace elements in the Mississippi River, Pearl River and the northern
804
Gulf of Mexico, as characterized by flow field-flow fractionation. Mar. Chem. 118, 119–
805
128. doi:10.1016/j.marchem.2009.11.007
806
Telfeyan, K., Breaux, A., Kim, J., Cable, J.E., Kolker, A.S., Grimm, D.A., Johannesson, K.H.,
807
2017. Arsenic, vanadium, iron, and manganese biogeochemistry in a deltaic wetland,
808
southern Louisiana, USA. Mar. Chem. 192, 32–48. doi:10.1016/j.marchem.2017.03.010 36
809
Telfeyan, K., Breaux, A., Kim, J., Kolker, A.S., Cable, J.E., Johannesson, K.H., 2018. Cycling of
810
oxyanion-forming trace elements in groundwaters from a freshwater deltaic marsh. Estuar.
811
Coast. Shelf Sci. 204, 236–263. doi:10.1016/j.ecss.2018.02.024
812
Tribovillard, N., Riboulleau, A., Lyons, T., Baudin, F., 2004. Enhanced trapping of molybdenum
813
by sulfurized marine organic matter of marine origin in Mesozoic limestones and shales.
814
Chem. Geol. doi:10.1016/j.chemgeo.2004.08.011
815 816 817 818
USEPA, 1999. The Ecological Condition of Estuaries in the Gulf of Mexico. EPA 620-R-98-004 80. USEPA, 1983. Sample preservation. pp.xv-xx. In Methods for Chemical Analysis of Water and Wastes, EPA-600/4-79-020. U.S.E.P.A., Cincinnati, Ohio, USA
819
USGS, 1999. Collection of Water Samples. TWRI Book 9, Chapter A4.
820
Valero, N., Gómez, L., Pantoja, M., Ramírez, R., 2014. Production of humic substances through
821
coal-solubilizing bacteria. Brazilian J. Microbiol. 45, 911–918. doi:10.1590/S1517-
822
83822014000300021
823
Weng, L., Temminghoff, E.J.M., Lofts, S., Tipping, E., Van Riemsdijk, W.H., 2002.
824
Complexation with dissolved organic matter and solubility control of heavy metals in a
825
sandy soil. Environ. Sci. Technol. 36, 4804–4810. doi:10.1021/es0200084
826
Yamashita, Y., Jaffé, R., 2008. Characterizing the interactions between trace metals and
827
dissolved organic matter using excitation-emission matrix and parallel factor analysis.
828
Environ. Sci. Technol. 42, 7374–9. doi:10.1021/es801357h
829
Zhang, Y., Liu, X., Osburn, C.L., Wang, M., Qin, B., Zhou, Y., 2013. Photobleaching Response
37
830
of Different Sources of Chromophoric Dissolved Organic Matter Exposed to Natural Solar
831
Radiation Using Absorption and Excitation-Emission Matrix Spectra. PLoS One 8.
832
doi:10.1371/journal.pone.0077515
833
Zhou, Z., Stolpe, B., Guo, L., Shiller, A.M., 2016. Colloidal size spectra, composition and
834
estuarine mixing behavior of DOM in river and estuarine waters of the northern Gulf of
835
Mexico. Geochim. Cosmochim. Acta 181, 1–17. doi:10.1016/j.gca.2016.02.032
836
Zielinski, R.A., Foster, A.L., Meeker, G.P., Brownfield, I.K., 2007. Mode of occurrence of
837
arsenic in feed coal and its derivative fly ash, Black Warrior Basin, Alabama. Fuel 86, 560–
838
572. doi:10.1016/j.fuel.2006.07.033
839
List of figures
840
Fig. 1 Land use and land cover map of the study area with sampling points indicated
841
Fig. 2 Precipitation in the Weeks Bay watershed and discharge through the Fish and Magnolia
842
Rivers
843
Fig. 3 Variation in the fluxes of trace elements to Weeks Bay following spring (n=12), summer-1
844
(n=12), summer-2 (n=13) and fall (n=12) sampling events. ‘n’ denotes number of samples.
845
Fig. 4 Variation in fluxes of nutrients to Weeks Bay following spring (n=12), summer-1 (n=12),
846
summer-2 (n=13) and fall (n=12) sampling events. ‘n’ denotes number of samples.
847
Fig. 5 Variation of absorption (SUVA254, SR) and fluorescence indices (HIX, FI, BIX) in Weeks
848
Bay water following spring (n=12), summer-1 (n=12), summer-2 (ML, n=13) and fall (n=12)
849
sampling events. ‘n’ denotes number of samples.
38
850
Fig. 6 Excitation (blue curve) and emission (red curve) loadings for four dissolved organic
851
matter components derived using a parallel factor (PARAFAC) model that was validated using
852
split-half analysis as well as random initialization. Contour plots corresponding to the
853
components identified in the PARAFAC model are shown for each of the components.
854
Fig. 7 Variation of parallel factor (PARAFAC) components in Weeks Bay water following
855
spring (n=11), summer-1 (n=12), summer-2 (n=12) and fall (n=11) sampling events. ‘n’ denotes
856
number of samples.
857
Fig. 8 Principal component analysis (PCA) biplot for the Weeks Bay water chemistry. Samples
858
collected following spring (L, n=11), summer-1 (n=12), summer-2 (n=11) and fall (n=11)
859
sampling events were indicated by distinct symbols. ‘n’ denotes number of samples.
860
Fig. 9 Bootstrap resampling results of the discharged normalized concertation of trace elements
861
in Weeks Bay water following spring (n=1000), summber-1 (n=1000), summer-2 (n=1000) and
862
fall (n=1000) sampling events. ‘n’ denotes number of bootstrap means.
863
List of Tables
864
Table 1 The amount of land use and land cover area in km2 and in percentages of Weeks Bay
865
watershed
866
Table 2 The average amount of precipitation in the Weeks Bay watershed and discharge through
867
the Fish and Magnolia Rivers during five days prior to the sampling events during spring,
868
summer-1, summer-2 and fall field campaigns
869
Table 3 Distribution of water quality parameters for Weeks Bay waters collected during four
870
field campaigns
39
871
Table 4 Parallel factor (PARAFAC) analysis components information and their identification
872
Table 5 Bootstrap 2.5 %, 50% and 97.5 % quantile values of trace elements following spring,
873
summer-1, summer-2 and fall water sampling events.
40
Tables:
Table 1 Land Classes Open Water Developed, Open Space Developed, Low Intensity Developed, Medium Intensity Developed, High Intensity Barren Land Deciduous Forest Evergreen Forest Mixed Forest Shrub/Scrub Herbaceuous Hay/Pasture Cultivated Crops Woody Wetlands Emergent Herbaceuous Wetlands
Area (Km2) 4.49 22.02 7.89 2.75 0.56 2.20 0.31 22.14 0.64 8.79 13.29 49.02 64.86 37.88 4.79
Area (%) 1.86 9.11 3.27 1.14 0.23 0.91 0.13 9.16 0.27 3.64 5.50 20.29 26.84 15.68 1.98
Table 2 Name of the Date of sampling sampling events
Spring Summer-1 Summer-2 Fall
05/09/2016 06/19/2016 06/26/2016 09/30/2016
Average amount of precipitation five days prior to the sampling (mm) 0.66 3.51 0.15 2.03
Average discharge through Fish River five days prior to sampling (m3/s)
5.51± 4.93 2.19± 0.03 1.70± 0.03 1.93± 0.10
Average discharge through Magnolia River five days prior to sampling (m3/s)
0.78± 0.06 0.77± 0.22 0.60± 0.02 1.80± 2.48
Table 3 Water Quality Parameter pH
ORP (mV)
TDS (mg/L)
Salinity (PSU)
DO (mg/L)
Temperature (°C)
Spring
Summer-1
Summer-2
Fall
Avg:8.06±0.31 Avg:8.20±0.34 Avg=8.69±0.23 Avg=8.78±0.20 IQR=0.23 IQR=0.48 IQR=0.26 IQR=0.13 Max=8.9 Max=8.57 Max=8.95 Max=9 Min =7.71 Min=7.59 Min=8.13 Min=8.21 Avg=-58.24±44.08 Avg=-17.63±27.81 Avg=-31.06±14.90 Avg=-79.78±47.62 IQR=78.65 IQR=42.80 IQR=22.15 IQR=14.70 Max=-6.10 Max=32.60 Max=-3.90 Max= -41.4 Min =-119.30 Min =-57.0 Min =-57.40 Min = -224.8 Avg=1984.25±2069.54 Avg=7125.92±3318.26 Avg=5684.17±2486.38 Avg=10973.50±3464.25 IQR=4097 IQR= 4729.75 IQR= 3009.25 IQR= 2524.75 Max=4261 Max= 11790 Max= 9611 Max= 17120 Min =7 Min =742 Min =86 Min = 3063 Avg=2.20±2.30 Avg=8.30±4.08 Avg=6.47±2.95 Avg=13.25±4.46 IQR=4.56 IQR=5.90 IQR=3.63 IQR=3.31 Max=4.75 Max= 14.17 Max=11.32 Max=21.43 Min =0.01 Min = 0.74 Min =0.08 Min =3.32 Avg=5.80±4.36 Avg=1.62±0.12 Avg=1.54±0.18 Avg=0.38±0.02 IQR=8.09 IQR=0.10 IQR=0.15 IQR=0.02 Max=12.6 Max=1.81 Max=1.79 Max=0.41 Min =1.59 Min =1.39 Min =1.07 Min =0.35 Avg=27.00±3.66 Avg=29.27±0.68 Avg=31.47±0.54 Avg=26.20±0.72 IQR=6.95 IQR=1.12 IQR=0.68 IQR=1.07 Max=30.83 Max=30.14 Max=32.06 Max=27.55 Min =23.43 Min =28.26 Min =30.33 Min =25.17
Table 4 Components (Ex/Em) unit nm
Description and reference
C1
(<250-330/448)
Terrestrial humic-like component, common in freshwater environment C1 Kothawala et al., 2014 C Coble 1996 C1 Singh et al., 2017 C1 Yamashita et al.,2010 C2 Sankar et al., 2018
C2
(<250-310/388)
Microbial Humic like, Anthropogenic origin, Protein like, common in agriculture dominated watershed, Prevalent in waste water, Microbially reprocessed, like marine humic-like C4 Yamashita et al.,2010 C2 Kothawala et al., 2014 C2 Singh et al., 2017 C3 Kowalczuk et al., 2010 C3 Hosen et al., 2014
C3
(270-400/504)
Humic-like, Terrestrial origin, high molecular weight and aromatic organic compounds, Soil derived, reduced terrestrial, common in wide range of freshwater environments such as wetlands and rangelands, humic acid-type C3 Kothawala et al., 2014 C4 Kowalczuk et al., 2010 C3 Singh et al., 2017 C5 Yamashita et al.,2010 C2 Hosen et al., 2014 C2 Lu et al., 2013
C4
(280/334)
Tryptophan-like, Protein like, autochthonous production; autochthonous algal and microbially derived proteins; Protein like indicative of recent production, also commonly found in croplands, wastewater, industrial, and livestock wastes C8 Fellman et al., 2009 C4 Singh et al., 2017 T Coble, 1996 C6 Kowalczuk et al., 2010 C7 Yamashita et al.,2010 C4 Hosen et al., 2014 C4 Singh et al., 2014
Table 5 Sampling Session Bootstrap Quantiles As Mn U Cu Zn Hg Fe
Flux during Spring (mgs-1) 2.5 % 50 % 97.5 % 20.41 20.76 242.55 265.78 1.50 1.62 5.45 5.72 7.33 9.05 0.38 0.42 1279.96 1429.23
21.10 288.54 1.72 6.00 11.62 0.45 1600.28
Flux during Summer-1 (mgs-1) 2.5 % 50 % 97.5 % 12.26 137.14 0.99 4.35 4.39 0.08 369.5742
13.07 156.38 1.17 5.18 7.59 0.09 411.07
13.83 175.91 1.36 6.72 13.74 0.10 459.99
Flux during Summer-2 (mgs-1) 2.5 % 50 % 97.5 %
Flux during Fall (mgs-1) 2.5 % 50 % 97.5 %
12.67 105.61 0.64 3.56 1.93 0.02 211.66
40.96 43.46 147.81 155.98 2.26 2.41 52.79 71.70 3.09 3.43 0.11 0.21 406.25 442.37
13.49 110.57 0.69 3.77 2.12 0.02 219.19
14.19 117.14 0.74 3.94 2.37 0.03 227.38
46.39 164.18 2.60 96.11 3.84 0.40 483.63
Figures:
Fig. 1
Fig. 2
Fig. 3
Fig. 4
Fig. 5
C1
C2
C3
C4
Fig. 6
Fig. 7
F
ig. 8
Fig. 9
Highlights: •
Dissolved organic matter compositions were used for source-tracking trace metals.
•
Flux of As, Cu, U, PO4, and NO3 correlated with protein-like and soil derived DOM.
•
The trace element and DOM mobility was controlled by precipitation and discharge.
•
Multivariate statistics revealed anthropogenic sources for the trace metals.
We do not have any conflicts of interests.
S0272-7714(19)30325-7
DOI:
https://doi.org/10.1016/j.ecss.2019.106452
Reference:
YECSS 106452
To appear in:
Estuarine, Coastal and Shelf Science
Received Date: 29 March 2019 Revised Date:
21 October 2019
Accepted Date: 25 October 2019
Please cite this article as: Sankar, M.S., Dash, P., Lu, Y., Paul, V., Mercer, A.E., Arslan, Z., Varco, J.J., Rodgers, J.C., Dissolved organic matter and trace element variability in a blackwater-fed bay following precipitation, Estuarine, Coastal and Shelf Science (2019), doi: https://doi.org/10.1016/ j.ecss.2019.106452. This is a PDF file of an article that has undergone enhancements after acceptance, such as the addition of a cover page and metadata, and formatting for readability, but it is not yet the definitive version of record. This version will undergo additional copyediting, typesetting and review before it is published in its final form, but we are providing this version to give early visibility of the article. Please note that, during the production process, errors may be discovered which could affect the content, and all legal disclaimers that apply to the journal pertain. © 2019 Published by Elsevier Ltd.
1
Dissolved organic matter and trace element variability in a blackwater-fed
2
bay following precipitation
3 4
M. S. Sankar1, Padmanava Dash1*, YueHan Lu2, Varun Paul1, Andrew E. Mercer1, Zikri
5
Arslan3, Jac J. Varco4, John C. Rodgers1
6 7
1
Department of Geosciences, Mississippi State University, Mississippi State, MS 39762, USA
8
2
Department of Geological Sciences, University of Alabama, Tuscaloosa, AL 35487, USA
9
3
Department of Chemistry & Biochemistry, Jackson State University, Jackson, MS 39217, USA
10
4
Department of Plant & Soil Sciences, Mississippi State University, Mississippi State, MS
11
39762, USA
12 13 14 15
*Corresponding author: Department of Geosciences, Mississippi State University, Mississippi
16
State, MS 39762. Room # 109B, Hilbun Hall, Email: [email protected], Phone: 001-662-325-
17
0364, Fax: 001-662-325-9423
18 19 20 21 1
22
Abstract
23
Dissolved organic matter (DOM) often forms complexes with trace metals. The main objective
24
of this study was to identify the sources of trace elements to a coastal bay that is fed by two
25
blackwater rivers using DOM compositions. Surface water samples from twelve sites in Weeks
26
Bay, Alabama were collected during four field trips and a bottom sediment sample was collected
27
during one of the trips. Spectroscopic measurements in tandem with parallel factor analysis and
28
multivariate statistics were used to derive DOM compositions and inductively coupled plasma
29
mass spectrometry was used for determining trace metal concentrations. DOM chemistry and
30
trace element concentrations together with precipitation and discharge, watershed land use and
31
land cover data, and physicochemical parameters were used to determine the source of trace
32
elements in the adjoining areas of the watershed to the bay and finally settling into the bay
33
sediments. Arsenic, copper, and uranium fluxes increased while fluxes of mercury, zinc,
34
manganese, and iron decreased following precipitation events. Concentration of all trace
35
elements analyzed were 10,000 times higer in the bay botton sediments than their concentrations
36
in the water colunmn. Microbially reprocessed and soil derived DOM components increased
37
along with the trace elements and nutrients in the bay as a result of precipitation whereas
38
concentration of terrestrial humic-like DOM component remained the same during both dry
39
(spring) and wet (summer and fall) periods. Principal component analysis revealed significant
40
correlations between Microbially reprocessed DOM and the trace elements including arsenic,
41
copper and uranium indicating urban, pasture, and agricultural areas in the watershed were the
42
sources for these trace metals. On the other hand, multiple sources were identified for
43
manganese, zinc, and iron. Overall it was found that DOM compositions are useful for inferring
44
the possible sources and mobility of trace elements in aquatic systems.
2
45
Keywords: Dissolved organic matter; Trace elements; Weeks Bay; Precipitation events; EEM-
46
PARAFAC; PCA
47 48 49 50 51 52 53 54 55 56 57 58 59 60 61 62 63 64 65 66 67 3
68 69
1. Introduction It has been recently reported that shallow Mississippi deltaic sediments serve as a source
70
of iron, manganese, and arsenic to the water column and redox reactions in the deltaic marshes
71
control the availability of trace elements like molybdenum, tungsten, arsenic, vanadium in the
72
coastal waters (Joung and Shiller, 2016; Telfeyan et al., 2018, 2017). The contamination of
73
mercury in the estuaries, bays and offshore regions of northern Gulf of Mexico (NGoM) has
74
been attributed to urban and agricultural runoff as well as atmospheric deposition (Apeti et al.,
75
2012; Lewis and Chancy, 2008). Consensus is yet to be reached regarding the source of these
76
trace elements, despite the associated contamination being one of the major problems adversely
77
impacting many forms of life in these coastal waterbodies (Lafabrie et al., 2011; Lewis and
78
Russell, 2015; Perry et al., 2015). Naturally occurring DOM is a complex mixture of different
79
organic compounds which can form complexes with trace elements, hence trace elements often
80
co-occur and covary with DOM of different origins (Yamashita and Jaffé, 2008). Based on DOM
81
composition, a substantial amount of humified terrestrial and some protein-like DOM
82
components were identified along the coastal water bodies of the southern US (Sankar et al.,
83
2018; Shank et al., 2011; Singh et al., 2010). Rivers and streams flowing into these coastal
84
waterbodies drain agricultural, forested and urbanized hinterlands and transport high amount of
85
dissolved nitrate, phosphate, carbon, and trace elements (Lafabrie et al., 2011; Reuter and
86
Perdue, 1977; Sankar et al., 2018; Stolpe et al., 2010; USEPA, 1999). There is a strong
87
correlation between the amount of water discharged and the quantity of organic matter delivered
88
through the coastal rivers of the United States (Keul et al., 2010; Reuter and Perdue, 1977; Zhou
89
et al., 2016). Specific studies have been conducted to understand the role of DOM in the
90
mobilization of trace elements (Hongxia et al., 2014; Reuter and Perdue, 1977; Stolpe et al.,
4
91
2010; Zhou et al., 2016). Strong metal binding capacity of both bacterially derived and soil
92
derived humic DOM compositions have been widely reported (Gu et al., 2011; Hongxia et al.,
93
2014; Reuter and Perdue, 1977). For instance, dissolved and colloidal trace elements, along with
94
nutrients and DOM are transported by Mississippi-Atchafalaya river system (Duan et al., 2007;
95
Stolpe et al., 2010; Zhou et al., 2016). This association might have important consequences in
96
terms of delivery and accumulation of toxic trace elements, such as arsenic, manganese, copper,
97
nickel, uranium, mercury, zinc, and nutrients including nitrate and phosphate along the
98
Mississippi deltaic sediments (Joung and Shiller, 2014, 2016; Slowey and Hood, 1971; Stolpe et
99
al., 2010).
100
Weeks Bay is a small coastal water body located near the city of Mobile (3rd most
101
populous city in Alabama) and is connected to NGoM through Mobile Bay. The freshwater input
102
into Weeks Bay is through two blackwater rivers, Fish River in the north and Magnolia River in
103
the southeast. Blackwater rivers are quite common all along the coastal areas of the southern US
104
and are connected to NGoM through estuaries and bays (Ruecker et al., 2017). They drain
105
extensive forested wetlands, thereby transporting brown colored water rich in soil-derived DOM
106
to coastal oceans (Spencer et al., 2013). Previous studies have shown that soil-derived DOM is
107
efficient in mobilizing trace elements via complexation (Benedetti et al., 1996; Tribovillard et
108
al., 2004; Weng et al., 2002). We hypothesized that these blackwater rivers are the main conduits
109
for not only DOM but also for toxic trace element transport into the coastal water bodies as a
110
result of rapid urbanization and industrialization in the southeastern US. We further hypothesised
111
that following precipitation events, the concentration of trace metals co-varied with specific
112
DOM components in the bay, and the DOM composition can be utilized to identify the source of
113
DOM and in turn, the trace elements. Hence, our objectives were to (1) determine the trace
5
114
element-DOM compositional associations, and (2) evaluate the changes in composition and
115
concentration of DOM and trace elements delivered into the Weeks Bay, NGoM in relation to
116
the average amount of precipitation in the watershed.
117
2. Materials and Methods
118
2.1 Study area, sample location and land use/ land cover analysis
119
Weeks Bay is fed by black water rivers and located on the eastern side of the Mobile Bay
120
in Baldwin County, coastal Alabama (Fig.1). It is designated as the 16th national estuarine
121
research reserve (NERR) of the US in 1986, hosting a wide variety of aquatic plants and animal
122
species. It is a shallow micro tidal tributary estuary (Camacho et al., 2014). The Weeks Bay
123
watershed covers a total area of 520.87 km2 and the Weeks Bay is a shallow water body with an
124
average depth of 2 m covering an area of 4.72 km2 (0.91% of the total watershed area). It
125
empties into the larger Mobile Bay through a narrow opening and the average water residence
126
time of Weeks Bay is 5 days (Caffrey et al., 2014). Two rivers flow into the bay; Fish River in
127
the north and Magnolia River in the south-east. To delineate the drainage basins of these two
128
rivers, hydrologic unit code-12 (HUC-12) boundary datasets for the Weeks Bay watershed were
129
downloaded from the United States Department of Agriculture (USDA) data gateway and 10 m
130
resolution digital elevation models were downloaded from the United States Geological Survey
131
(USGS) National Map download client. The digital elevation models and the HUC-12 watershed
132
boundary datasets were used in Arc-GIS 10.4.1 platform to delineate the drainage basins of the
133
Fish and Magnolia Rivers emptying to the Weeks Bay. Subsequently, the land use and land
134
cover dataset of 2015 was downloaded from the USDA data gateway and cropped using the
135
delineated watershed boundary for determining the areas covering each major land use and land
136
cover. It was found that the bay and associated river channels are surrounded by emergent 6
137
herbaceous wetlands (6.46 km2, 1.24 %), woody wetlands (67.62 km2, 12.98 %) and evergreen
138
forest (72.88 km2, 13.99 %) (Table 1). Cultivated cropland and pasture make up the major part of
139
the watershed (127.52 km2, 24.48 % and 98.94 km2, 19.00 %). Urbanized areas (68.38 km2,
140
13.13 %) were located on the northwestern and northern parts along Fish River and along the
141
southeastern areas of Magnolia River.
142
Four field campaigns were conducted to measure in situ water quality parameters and
143
collect water samples. Twelve water samples were collected during the campaigns on
144
05.09.2016, 06.19.2016 and 09.30.2016, while thirteen samples and a bay bottom sediment were
145
collected during the campaign on 06.26.2016 (Fig. 1). Water samples were collected from
146
locations distributed all along the bay in clean, acid-washed 1-liter high density polyethylene
147
(HDPE) bottles following the protocol explained in Dash et al. (2015). Sediment from the bottom
148
of the bay was collected using an extendable grab sampler and was stored in an O2-impermeable
149
Remel®bag. Water quality parameters including pH, oxidation-reduction potential (ORP, mV),
150
dissolved oxygen (DO, mg/L), total dissolved solids (TDS, mg/L), salinity (PSU) and water
151
temperature (°C) were collected from each sampling location during every field campaign by
152
using a HANNA® extendable probe. The collected water and sediment samples were stored in an
153
airtight cooler filled with ice and transported back to the lab. Water samples were filtered using
154
0.2 µm Whatman® nuclepore track-etch membrane filters, stored in amber colored glass bottles,
155
and refrigerated at 4°C until spectroscopic analysis of colored dissolved organic matter (CDOM).
156
The samples for dissolved organic carbon (DOC), total dissolved nitrogen (TDN), and anions
157
(nutrients) analyses were stored in acid washed 20 mL HDPE bottles and kept frozen in a -80 °C
158
freezer until analysis. The water samples for cations (trace elements) were acidified using
159
Fisherbrand® ultrapure nitric acid (0.2 %) and stored in acid washed and pre-combusted 20 mL
7
160
glass bottles and stored in room temperature until analysis following the U.S. Geological Survey
161
and U. S. Environmental Protection Agency protocols (USGS, 1999; USEPA, 1983).
162
The field campaigns were planned in accordance with precipitation events and the
163
corresponding river water discharge into the bay (Fig.2). Discharge data were obtained from the
164
United States Geological Survey (USGS) national water information system web interface. The
165
USGS discharge gauges were located at Magnolia River (USGS 02378300) and Fish River
166
(USGS 02378500). Daily average precipitation data for the Weeks Bay watershed was obtained
167
from National Weather Service (NWS) rainfall plots.
168
2.2 Water sample analysis, CDOM indices and PARAFAC modeling
169
Trace elements; arsenic (As), manganese (Mn), zinc (Zn), copper (Cu), mercury (Hg)
170
uranium (U) and iron (Fe) were analyzed using inductively coupled plasma mass spectrometry
171
(ICP-MS). Nutrients including phosphate (PO43-), nitrate (NO3-), ammonium (NH4+) and nitrite
172
(NO2-) anions were analyzed using a continuous flow auto-analyzer (Skalar Analytical Inc.,
173
Buford, GA) at Dauphin Island Sea Lab. The DOC and TDN content of the water samples were
174
measured on a SHIMADZU® total organic carbon-total nitrogen analyzer (TOCv-TNM1)
175
equipped with an ASI-V autosampler following the method described in Shang et al., 2018.
176
Toxicity of trace elements and nutrients were expressed in terms of the Unites States
177
Environmental Protection Agency (US EPA) recommended water quality criteria.
178
CDOM absorption was analyzed in a PerkinElmer® Lambda 850 UV/VIS double-beam
179
spectrophotometer (Waltham, MA, USA) following the analytical procedure described in Singh
180
et al., 2017. Absorption spectra of the samples and blank (deionized water, 18.2 mΩ purity) were
181
collected between 200nm and 750nm wavelengths at 2 nm interval in a clean 4 mL quartz
182
cuvette with 1cm path length. Effects of background and scattering were removed by subtracting 8
183
the absorption spectra of the samples from the blank. The blank subtracted sample absorbance
184
(A) was used to calculate Napierian absorption coefficient (a) at each wavelength (λ) (Fichot and
185
Benner, 2012; Singh et al., 2017; Zhang et al., 2013). Absorption coefficients were used to
186
calculate specific UV absorbance (SUVA254) by dividing absorption coefficient at 254nm by
187
DOC concentration (Lmg-1m-1). The slope ratio (SR) is the ratio of absorption coefficient
188
between 275 and 295 nm to that between 350 and 400 nm. Values of SUVA254 are directly
189
proportional to aromaticity of DOM, while SR values are inversely related to the molecular
190
weight of DOM in the water sample (Hansen et al., 2016; Kothawala et al., 2014; H. Lin et al.,
191
2016; Singh et al., 2017).
192
Fluorescence properties of the water samples (Excitation emission matrix, EEM) were
193
analyzed using Horiba® Jobin Yvon Inc., Fluoromax-4 spectrofluorometer (Edison, NJ, USA)
194
following the analytical procedure explained in Sankar et al., 2018. After applying company
195
specified instrumental corrections and calibrations, the EEMs of the samples and blanks
196
(deionized water,18.2 mΩ purity) were measured with excitation wavelengths of 240-450nm at
197
every 10 nm increment and emission wavelengths of 300-550nm at every 2nm increment. After
198
removing inner filter effects; the blank corrected and Raman normalized EEMs were used for
199
PARAFAC modeling (Kothawala et al., 2013; Singh et al., 2017; Stedmon and Markager, 2005).
200
Fluorescence Index (FI), Humification Index (HIX) and Biological Index (BIX) or Freshness
201
Index were calculated using the corrected EEMs. The calculation steps for these indices can be
202
found in Hansen et al., 2016 and elsewhere. The FI index indicates the source of DOM, which
203
can either be microbial (with high FI, between 1.6-2.0, usually derived from extracellular release
204
and leachate from bacteria and algae) or terrestrial (with low FI, between 1.2-1.5, usually from
205
terrestrial plants and soil organic matter). HIX can be used as a proxy for humification of natural
9
206
organic matter. An increase in HIX values indicates the condensation of fluorescent molecules
207
and decrease in the H/C ratio of DOM. The BIX is an indicator of the freshness of DOM. High
208
BIX values (>1) indicate freshly released DOM as a result of autochthonous production in the
209
aquatic system. On the other hand, low values of BIX (0.6-0.7) indicate less autochthonous
210
production of DOM in the water body (Huguet et al., 2009)
211
A total of 49 sample EEMs were used for PARAFAC modeling. After removal of the
212
outliers, the sample size was reduced to 46. Out of the 46 sample EEMs, 11 were following the
213
spring sampling event (9th May 2016), 12 each following summer-1 (19th June 2016) and
214
summer-2 (26th June 2016) sampling events, and 11 were following the fall sampling event (30th
215
September 2016). To avoid abnormalities during the modeling, the EEMs were normalized using
216
Raman integrated area at 350 nm excitation and 397 nm emission over 5 nm bandpass. Prior to
217
PARAFAC modeling, the excitation wavelengths were interpolated at 5 nm increments, and
218
emission wavelengths were interpolated at 4nm increments. A four component PARAFAC
219
model which explained 99.96 % variance of the data was validated by split half analysis using
220
Tucker congruence coefficients and random initialization. The scores of the PARAFAC
221
components (fluorescence intensity maximum, Fmax) were expressed in Raman units (R.U). The
222
DOMFluor tool box in MATLAB®- R2018a computing platform was used to create the
223
PARAFAC model (Stedmon and Bro, 2008).
224
2.3 Sediment characterization and geochemical analysis
225
The mineralogical characterization of the bay bottom sediment was carried out using a
226
Rigaku Ultima III X-ray diffractometer with a graphite monochromator and scintillation detector
227
at I2AT laboratory, Mississippi State University. The sample was pulverized and homogenized
228
using an agate mortar and piston and analyzed over 0° to 90° (2θ) angle. 10
229
Trace element analysis of the bay bottom sediment sample in duplicates were carried out
230
for As, Mn, U, Cu, Zn, Hg, and Fe. 0.5 gm of homogenized sediment sample and its duplicate
231
were digested using concentrated trace metal grade nitric acid and 30 % hydrogen peroxide on a
232
hot plate at 90°C following the EPA protocol (method SW-846 3050B). The digestate was later
233
refluxed using concentrated trace metal grade hydrochloric acid and then diluted to 50 mL using
234
deionized water before the ICP-MS analysis for As, Mn, U, Cu, Zn and Fe. The concentration of
235
Hg in bay bottom sediment was analyzed separately by cold vapor atomic absorption (CVAA)
236
spectroscopy (SW-846 Method 7471B). The soil standard reference material (PR-LCSSRM-
237
00018 B/ERA-550/http.eraqc.com) was also analyzed to estimate recovery.
238
2.4 Statistical Analysis
239
The R-version 3.3.2 (R® Core Team) programming platform was used for the statistical
240
analysis of all the measured and observed data. Principal Component Analysis (PCA) was
241
performed on PARAFAC components, fluorescence indices, absorption indices, water quality
242
parameters, and fluxes of DOC, TDN, nutrients, and trace elements to understand their
243
relationship. Bootstrap resampling statistics at confidence intervals of 2.5%, 50%, and 97.5%
244
was applied to trace element concentrations to estimate whether they were significantly different
245
statistically following different precipitation events by taking 1000 means (1000 replicates).
246
Mann-Whitney-Wilcoxon Test was used to explain the significant increase or decrease in
247
PARAFAC components from spring with low amount of precipitation to fall with high amount
248
of precipitation. The SUVA254 values showed minimum variation between the seasons hence,
249
One-way ANOVA was performed to understand the variance between and among the SUVA254
250
values during four sampling events. Tukey-HSD pairwise multiple comparisons post-hoc
251
analysis was also performed to find the significance in differences between SUVA254 values 11
252
following precipitation events. All of the statistical analyses were performed at 95% confidence
253
level (α=0.05). Maximum, minimum, average (mean) and standard deviation were calculated for
254
all the measured parameters. Interquartile range (IQR) was calculated for expressing the
255
variability in the observations. Data values greater than 3 times the IQR or above the third
256
quartile in the box plot were presented as outliers. Both p-value (t-test of regression, α=0.05) and
257
r value or correlation coefficient (0.5>r≥0.3 weak, 0.7>r≥0.5 moderate and r≥0.7 strong
258
relationship) were estimated to represent the significance, strength, and direction of the
259
relationship among the variables.
260
3. Results
261
3.1 Temporal changes in water quality and chemistry in response to seasonal meteorological
262
events
263
Monthly meteorological data for the year 2016 revealed that average precipitation in the
264
Weeks Bay watershed was higher during September 2016 (mean=8.49 mm, max=49.53 mm,
265
min=0 mm) followed by June 2016 (mean=5.60 mm, max=47.50 mm, min=0 mm) and May
266
2016 (mean=3.05 mm, max= 27.43 mm, min=0 mm). The precipitation events in the watershed
267
were marked by a sudden increase in water discharge into the bay through both rivers (Fig.2).
268
The average discharge of Fish and Magnolia Rivers during the months of September, June and
269
May 2016 were 2.11±0.79 m3/s, 2.38±0.82 m3/s, 3 .20±2.57 m3/s and 1.19±1.42 m3/s, 0.74±0.34
270
m3/s, 0.77±0.32 m3/s. The Fish River is larger yet displayed a greater increase in discharge than
271
the Magnolia River. As such, our sampling campaigns represented four seasonal precipitation
272
conditions, we coined spring for 9th May 2016, summer-1 for 19th June 2016, summer-2 for 26th
273
June 2016 and fall for 30th September 2016. The average amount of precipitation in the
274
watershed over five days prior to the sampling events is used for describing the variations during 12
275
each of the sampling events (Table 2). It is also important to note that the soil profile of entire
276
region remained wet with rainwater following 26th of June 2016 (summer-2) due to the
277
prevalence of rain events from the month of June 2016 onwards. Similarly, several precipitation
278
events were observed in September 2016.
279
Water quality parameters (pH, ORP, TDS, Salinity, DO, water temperature) of the bay
280
exhibited changes in accordance with seasonal precipitation and corresponding discharge events
281
(Table 3). The pH, TDS, and salinity showed an increasing trend, while both ORP and DO
282
values decreased with precipitation and discharge. pH values following fall precipitation event
283
were higher than the pH following spring precipitation event. The steady increase in pH from
284
spring to fall through summer precipitation events in the bay indicates freshwater input following
285
precipitation events. Net negative ORP values of the bay during all field sessions show the
286
prevalence of reducing condition. The water temperature was variable following spring
287
precipitation event compared to the summer and fall. It is important to note that high tides were
288
coinciding during water sampling following the summer-1 (0.52 m), summer-2 (0.40 m), and fall
289
precipitation events (0.40 m), while low tides coincided during sampling following the spring
290
precipitation (0.3 m) event (www.tidesandcurrents.noaa.gov).
291
The flux of trace elements, nutrients, DOC and TDN were calculated by multiplying their
292
concentration with five-day average river discharge to evaluate their variability between three
293
different seasons. While their actual concentrations were used to explain their toxicity if they had
294
exceeded EPA recommended water quality criteria for saltwater (EPA, 2018). The average flux
295
of As (20.75±1.29 mgs-1 to 43.46± 10.09 mgs-1), U (1.62±0.39 mgs-1 to 2.41±0.62 mgs-1) and Cu
296
(1.82±0.33 mgs-1 to 73.30±78.81 mgs-1) in the bay showed an increase in trend following the
297
spring precipitation event to fall precipitation event (Fig. 3). On the contrary, the average flux of 13
298
Hg (0.42±0.13 mgs-1 to 0.21± 0.63 mgs-1), Fe (1432.19±563.30 mgs-1 to 444.15±146.15 mgs-1),
299
Mn (268.53±83.02 mgs-1 to 156.50±31.16 mgs-1), and Zn (9.04± 8.69 mgs-1 to 3.45±1.45 mgs-1)
300
showed a general decrease in trend from spring precipitation event to fall precipitation event.
301
Arsenic concentrations were highly variable between sites following the fall precipitation event
302
(IQR=10.99) with an average value of 23.31±5.41 µgL-1 (SI Fig. 1). The maximum variability of
303
Cu flux between sites was observed following fall precipitation event (IQR= 79.72) and for U it
304
was following summer-1 precipitation event (IQR=1.25). Cu concentrations exceeded the EPA
305
recommended water quality criteria of 4.8 µgL-1 for acute toxicity and 3.1 µgL-1 for chronic
306
toxicity (EPA, 2018) following the fall precipitation event with an average concentration of
307
39.30±42.26 µgL-1 and at one site near the mouth of Fish River following the summer-1
308
precipitation event with a concentration of 14.39 µgL-1. The average concentration of Zn was
309
2.91±6.97 µgL-1 with maximum variation of flux between sites following the spring precipitation
310
event (IQR= 4.96). Fluxes of Hg, Fe, and Mn showed highest variation between sites following
311
the spring precipitation event (IQR=0.21; 624.27; 116.77). The average concentration of Mn was
312
always high and with an average concentration of 92.98±27.01 µgL-1. Concentration of Fe
313
following summer-1, summer-2, and fall precipitation events were lower (avg=235.57±73.03
314
µgL-1) compared to its concentration following the spring precipitation event
315
(avg=455.39±179.11 µgL-1). On the contrary, the Hg concentration was always below its toxicity
316
limits (EPA recommended water quality criteria for salt water 1.8 µgL-1 for acute toxicity and
317
0.94 µgL-1 for chronic toxicity (EPA, 2018)) with an average value of 0.08±0.11 µgL-1 except of
318
one site where the concentration was 1.17 µgL-1 near the mouth of the Weeks Bay Estuary to the
319
Mobile Bay (SI Fig. 1).
14
320
There was an increase in the average flux of both NO3- (214.84± 155.78 mgs-1 to
321
4211.34± 1550.98 mgs-1) and PO43- (109.27± 39.74 mgs-1 to 389.37± 122.09 mgs-1) from spring
322
to fall precipitation events. However, PO43- showed slight decrease in flux following the
323
summer-2 precipitation event. On the other hand, both NH4+and NO2- showed no such trend in
324
flux (Fig. 4). The greatest variation of PO43- flux was following the high precipitation event
325
(IQR= 184.65), and for NO3-, it was following the summer-1 precipitation event (IQR= 1724.69).
326
Both NH4+ and NO2- showed maximum variation following the low precipitation event (IQR=
327
469.37 and 439.25). The average concentrations of NO3-, NO2-, and NH4+ were 1267.41±478.78
328
µgL-1, 40.84±71.11 µgL-1 and, 24.93±28.26 µgL-1, respectively. PO43- concentrations were high
329
in all sampling locations following the high precipitation event (mean= 208.78± 65.46 µgL-1,
330
max= 303.91 µgL-1) and at one location following the moderately high precipitation event
331
(112.07 µgL-1) (SI Fig. 2).
332
Average flux and variation of both DOC and TDN were high following the spring
333
precipitation event compared to other sampling seasons (IQR= 2207.004; 2111.396) (Fig. 4).
334
During other three field campaigns, the flux of both DOC and TDN remained nearly same with
335
5582.79± 309.14 mgs-1; 636.61± 149.93 mgs-1, respectively, yet DOC showed a slight increase in
336
flux (mean= 7414.85± 352.73 mgs-1) following the fall precipitation event compared to the
337
summer-2 precipitation event (3979.49± 286.07 mgs-1). The actual concentration of DOC and
338
TDN is given in the supplementary material (SI. Fig. 2).
339
The fluxes of trace elements such as As, Cu, U and nutrients such as PO4-, NO3-, and
340
NO2- showed an increasing trend, while the fluxes of Fe, Mn, Zn, NH4+, DOC and TDN showed
341
a decreasing trend with salinity of the bay (SI. Fig. 4 & 5).
342
3.2 Seasonal variation of spectroscopic properties and development of PARAFAC model 15
343
The mean values of SUVA254 were high following both spring (6.68±1.43 L mg-1m-1) and
344
summer-1 precipitation events (7.50±0.63 L mg-1m-1) compared to both summer-2 (5.31±0.43 L
345
mg-1m-1) and fall precipitation events (5.89±0.39 L mg-1m-1) (Fig.5). On the other hand, average
346
values of SR showed a general increase in trend from spring (1.27±0.04) to fall precipitation
347
event (1.51±0.35) with maximum variation following the fall precipitation event (IQR= 0.43).
348
The mean values of both FI and BIX also increased from spring precipitation
349
(FI=1.44±0.02, BIX=0.65±0.02) to fall precipitation (FI=1.47±0.02, BIX=0.71±0.03) event (Fig.
350
5). The maximum variation of FI was following the summer-1 precipitation event (IQR= 0.043),
351
while for BIX it was the same following the fall-precipitation and summer-1 precipitation events
352
(IQR= 0.04). However, BIX values were always less than 1 during all field campaigns
353
(avg=0.69±0.04, max=0.77, min=0.60). The mean values of HIX remained nearly the same
354
following all the four field campaigns (0.76±0.05). The variation of HIX was maximum
355
following both fall and summer-2 precipitation events (IQR=0.08 and 0.07).
356
The PARAFAC analysis of the Weeks Bay water samples collected during the four field
357
campaigns in three different seasons resulted in a four-component model (C1, C2, C3, and C4).
358
The PARAFAC component C1 was a terrestrial, humic-like component; C2 was a microbial,
359
humic-like component; C3 was an allochthonous, terrestrial component or soil-derived
360
component; and C4 was a microbial tryptophan-like component (Fig. 6, Table 4). Components
361
C2, C3, and C4 showed a general increase of 7.61%, 11.19%, and C4=27.61%, respectively, in
362
average fluorescence intensity (Fmax) in the bay from spring precipitation to fall precipitation
363
events (Fig. 7). However, component C2 showed a slight decrease (2.18 %) in fluorescence
364
intensity from summer-2 to fall precipitation events. On the other hand, component C1 showed
365
limited change in average fluorescence intensity and had less variability during all seasons. The 16
366
components C2, C3, and C4 showed slightly higher variation in Fmax values with IQR of 0.03,
367
0.04 and 0.03, respectively, following the summer-1 precipitation event compared to other
368
precipitation events (Fig. 7).
369
3.3 Bottom sediment characterization and chemistry
370
Total digestion of Weeks Bay bottom sediment sample revealed the presence of Mn
371
(110.00±0.00 mg/Kg); Zn (30.00±1.41 mg/Kg); As (7.75±0.21 mg/Kg); Cu (4.05±0.07 mg/Kg);
372
U (2.35±0.07 mg/Kg); Hg (0.03±0.00 mg/Kg) and Fe (19500.00±707.11 mg/Kg). The recovery
373
of the above trace elements from the standard reference material (PR_LCSSRM_00018) was
374
above 95%. However, the XRD analysis of the bottom sediment revealed complete absence of
375
As, Cu, U, Mn, Zn, and Hg bearing minerals, with the presence of two predominant minerals:
376
Quartz (SiO2: 97.2%), and Pyrite (FeS2: 2.8%) (SI. Fig.3).
377
3.4 Statistical Results
378
To evaluate the change in water chemistry of the bay in response to precipitation in the
379
watershed and corresponding river water discharge, we used PCA analysis of PARAFAC
380
components, optical indices, DOC flux, TDN flux, inorganic ions (trace elements and nutrients)
381
flux, and water quality parameters (Fig. 8). The two principal components (PC); PC1 and PC2,
382
together explained 49.50 % of the total variance of the data. The presence of both microbial
383
PARAFAC components C2, C4 and the soil derived component C3 along with high FI, BIX, SR
384
on the positive side of the PC1 indicates allochthonous anthropogenic and some terrestrial soil
385
input. Whereas the presence of high SUVA254 and HIX along with PARAFAC component C1
386
along the negative side of the PC1 indicates terrestrial input. The HIX is inversely related to
387
component C3. The TDS, salinity, pH, nutrients (PO4, NO3-, NO2-), and the trace elements As, U,
17
388
and Cu were associated with microbial humic-like or protein-like PARAFAC component C4.
389
The ammonium ion (NH4+) and the trace elements Mn and Zn were associated with terrestrial
390
humic-like PARAFAC components C1. Hg and Fe showed no association with any PARAFAC
391
components, yet both were strongly associated with DOC and TDN. The ORP and DO were
392
present along the negative side of the PC1 axis and also directly related to both Fe and Hg.
393
Among the samples collected following all the precipitation events, all fall precipitation events
394
were located on the positive side of the PC1 axis, while all the samples representing the spring
395
precipitation events were positioned on the negative side of the PC1 axis. Whilst both summer
396
samples were located on the negative side of the PC2 axis. Additionally, positive relationship of
397
SUVA254 against Zn flux and FI against U flux and the negative relationship of component C4
398
vs Mn were also seen (SI. Fig.6)
399
Bootstrap resampling method at confidence intervals 2.5%, 50%, 97.5% was applied to
400
the flux of trace elements (As, Mn, U, Cu, Zn, Hg, Fe) following four field campaigns (Fig. 9).
401
The bootstrap results revealed that there was a significantly high flux of As, Cu and U in the bay
402
following the fall precipitation event compared to summer-1, summer-2 and spring precipitation
403
events (Table 5). In contrast, the flux of Hg, Mn, and Fe were significantly higher statistically
404
following the spring precipitation event than the summer-1, summer-2 and fall precipitation
405
events. The flux of Mn to the bay showed a statistically significant decrease from spring
406
precipitation event to summer-2 precipitation event. The flux of Zn to the bay was statistically
407
similar but higher following both spring and summer-1 precipitation events compared to its flux
408
following summer-2 and fall precipitation events.
409 410
The one-way ANOVA analysis indicated that variability of SUVA254 between the four sampling events (mean square=11.30) and the variability within each precipitation event (mean 18
411
square=0.69) are significantly different (F=16.46), therefore mean SUVA254 of each sampling
412
event is significantly different (p<0.05) from one another. Tukey-HSD pairwise multiple
413
comparison post-hoc analyses indicated similar mean SUVA254 following the summer-2 and fall
414
(p>0.05) precipitation events. The mean SUVA254 following the summer-2 and spring
415
precipitation events were the same and following the spring and fall precipitation events were
416
also the same (p>0.05). Mann-Whitney-Wilcoxon Test confirmed a significant (p<0.05) increase
417
in PARAFAC components C2, C3, and C4 from spring to fall precipitation events with U values
418
of 118, 104, and 118, respectively, while the component C1 showed no significant change
419
(p>0.05, U=72) following the precipitation events.
420
4. Discussion
421
4.1 Water and sediment chemistry
422
The concentration of Cu in Weeks Bay exceeded the EPA recommended water quality
423
criteria both for acute and chronic toxicity for aquatic life following the fall precipitation event.
424
On the other hand, the concentrations of other trace elements including U, Zn, Hg, As, Mn, and
425
Fe, and nutrients including NO3- and NO2- in the bay were lower than the EPA recommended
426
water quality criteria (EPA, 2018). Yet it is important to note that even at such low
427
concentrations, their regular input and concurrent deposition can lead to their enrichment in the
428
bay bottom sediments over time and also bioaccumulation/magnification of these trace metals in
429
aquatic organisms.
430
The flux of As, U, and Cu along with PO4- and NO3- into the bay increased following
431
increase in precipitation in the watershed (Figs. 3 and 4). Their co-occurrence and the
432
simultaneous increase in flux were not surprising as the predominant land use land cover of the
19
433
watershed surrounding Weeks Bay is agricultural land (cultivated crops-24.48%, hay and
434
pasture-19.00%). The application of phosphate-based fertilizers, micronutrients containing Cu
435
and animal manure in those agricultural areas can be one of the possible sources for the
436
excessive influx of PO4-, NO3- and Cu (Bandyopadhyay et al., 2014; Hudak, 2000; Miller et al.,
437
2011). Moreover, phosphate-based fertilizers can be a source of As or it can enhance the release
438
of adsorbed As from the soil fraction, especially from iron oxyhydroxides (Jayasumana et al.,
439
2015; T. Y. Lin et al., 2016; Molina et al., 2009; Signes-Pastor et al., 2007), which is in
440
agreement with the significant strong positive relationship (p<0.05, r= 0.74) of As and PO43- flux
441
in the bay. Similarly, the concentration of As (7.75±0.21 mg/Kg), Cu (4.05±0.07 mg/Kg), and U
442
(2.35±0.07 mg/Kg) were also very high in the bottom sediments. While naturally occurring
443
pyrite containing As (S- and Fe2+ atoms were replaced by As) can be a source for As (Blanchard
444
et al., 2007; Le Pape et al., 2017), the absence of As-bearing pyrite (SI Fig. 3) and increase in
445
the flux of As along with U, Cu, PO43-, and NO3- into the bay (Fig. 3) clearly indicates an
446
external or anthropogenic source for As. Previous studies in the adjacent watersheds have
447
attributed enhanced concentrations of trace elements to external sources. Lafabrie et al. (2011)
448
reported high amount of As and Hg in the Fish River sediments and identified Warrior Coal
449
Field (coal enriched in As and Hg) located at northwestern corner of Mobile Bay watershed and
450
the chemical industrial plants located between Mobile Bay and Mobile-Tensaw Delta as the
451
possible sources. Zielinski et al. (2007) have also reported the presence of As, Hg, and U in the
452
feed coal and its derivative fly ash in the Warrior Coal Field. The increase in the flux of U along
453
with the flux of As and Cu in the bay in response to seasonal precipitation and discharge (spring
454
to fall) suggests additional sources of U from the watershed. There was no nuclear reactor near
455
the watershed. Although there are a couple of nuclear power plants in the state of Tennessee,
20
456
along the Tennessee River, the river is not connected to Weeks Bay. However, there are exposed
457
out crops of black shale formations present along the north-eastern Alabama, but no streams
458
flowing to Weeks Bay are connected to those outcrops. Hence, the possible source of U could be
459
the effluent of Warrior Coal Field, as the coal contains a substantial amount of U as an impurity
460
(Zielinski et al., 2007).
461
Overall there was a decrease in flux of Mn, Hg, Fe, and Zn in the bay from spring to fall
462
precipitation event. However, their concentrations in sediment (19500.00±707.11 mg/Kg;
463
110.00±0 mg/Kg; 30.00±1.41 mg/Kg; 0.03±0.00 mg/Kg) were very high, and their high flux in
464
bay following spring precipitation event may be due to the prevalence of higher reducing
465
conditions (lower ORP values) in the bay. Warrior Coal Field and the chemical industrial plants
466
in the watershed are likely the sources of Hg contamination in Weeks Bay. The concentration of
467
Hg was high following the spring precipitation event compared to the fall precipitation event
468
possibly because of dilution following the summer and fall precipitation events. Previous studies
469
have reported the presence of high concentrations of Mn, Zn, and Cu in the shallow regions of
470
the Gulf of Mexico and suggested their release from reductive dissolution of bottom sediments
471
via decomposing organic matter (Joung and Shiller, 2016; Slowey and Hood, 1971). Another
472
possible source of Mn and Zn could be fertilizer such as basic slag containing Ca, Mg, Mn, and
473
Zn commonly used in the agricultural areas of Southeastern United States. Also, application of
474
ammonium fertilizers can lead to nitrification and soil acidification that accelerates leaching of
475
cations adsorbed to soil.
476
Both NH4+ and NO2- fluxes were negatively related to NO3- flux (p >0.05, r= -0.31 and
477
p<0.05, r= -0.21) in the bay. The weak inverse relationship of both NH4+ and NO2- against NO3-
478
could be due to the active nitrification/denitrification process in the bay. The high flux of NO2-, 21
479
high amount of DO, and low flux of NO3- following spring precipitation event compared to their
480
concentration following the summer and fall precipitation events could indicate high anaerobic
481
denitrification process following spring precipitation and discharge (Kim et al., 2010).
482
High DOC was observed following the spring precipitation event compared to summer
483
and fall precipitation events possibly because of higher residence time of the river effluents in
484
Weeks Bay and vice versa. This pattern suggests that the input of DOC is hydrologically
485
controlled, that is, the flow path is shifted from deep, low-DOC soil horizons to shallow, high-
486
DOC horizons following spring with low amount of precipitation to fall with high amount of
487
precipitation events (Dalzell et al., 2007; Hu et al., 2016; Zhou et al., 2016). Thus our study
488
shows that the DOC flux into Weeks Bay and then to NGoM through Mobile Bay increases with
489
discharge.
490
Stolpe et al. (2010) reported the presence of U-CDOM colloids, Mn in Fe-rich colloids
491
and Cu-CDOM complexes in the Pearl, Mississippi, and Atchafalaya Rivers. A positive
492
correlation was observed between the fluxes of Fe and DOC in the bay following all precipitation
493
events (p<0.05, r=0.86) indicating their co-occurrence as Fe-DOM colloids. According to
494
Novotnik et al. (2018) the mobility of U is also controlled by its oxidation state and the presence
495
of complexing agents like inorganic carbon, PO43-, and DOM. We observed a significant positive
496
relationship (p<0.05, r=0.73) between the fluxes of U and PO43-, however we did also observe a
497
week but significant correlation between DOC and U (p<0.05, r=0.33) in our dataset, but did not
498
observe any correlation between Cu and DOC in Weeks Bay.
499
4.2 Variation DOM in response to precipitation
22
500
The variation of both absorption and fluorescence indices from low spring precipitation
501
through the moderate summer to high fall precipitation revealed the input of less humified,
502
simpler, low molecular weight, microbially reprocessed or protein-like DOM into the bay
503
following the precipitation events. The SUVA254 values had minimum change as a function of
504
precipitation and discharge, however the ANOVA analysis confirmed that the variability of
505
SUVA254 between and within each precipitation event were significantly different (p<0.05). The
506
difference in mean SUVA254 values following the three seasonal precipitation events (spring,
507
summer and fall) indicates DOM export from multiple sources. That is high aromatic and high
508
molecular weight DOM input from adjoining herbaceous wetlands, woody wetlands, and
509
evergreen forests and low aromatic DOM from the croplands, pasture, and urbanized areas (Lu et
510
al., 2013). Meanwhile, high value of SUVA254 following the event of summer-1 precipitation
511
could be due to higher input of soil-derived DOM along with other terrestrially derived DOM,
512
both with high aromatic character, into the bay from dry riparian areas and surrounding woody
513
herbaceous wetlands. The higher and fluctuating SUVA254 values during the events of
514
precipitation in summer and fall could also be due to the input of humic DOM from the coal
515
effluents from warrior coal fields. The release of humic substances from coal is been widely
516
reported (De Souza and Bragança, 2018; Valero et al., 2014). The SR values, proxy for DOM
517
molecular weight, were also high following the summer-1, summer-2 and fall precipitation
518
events compared to spring precipitation event indicating high influx of low molecular weight or
519
simpler microbial humic-like or protein-like DOM from the croplands, pasture, and urbanized
520
areas into the bay following the high amount of precipitation during the summer and fall seasons.
521
The BIX values were always less than one during all four trips indicating the dominance
522
of organic matter from external sources or allochthonous input. Increases in both BIX (10.26 %)
23
523
and FI (2.03 %) indices along with fluctuating HIX values as discharge increases also indicates
524
addition of fresh, microbially derived, DOM into the bay through the river discharge in response
525
to precipitation (Fig. 5). The sources for this pool of fresh microbial organic matter could be
526
human-modified lands such as croplands, pasture, and urbanized areas. Previous studies have
527
reported that agricultural and urban areas export DOM with enhanced signatures from microbial
528
sources (Lu et al., 2013; Sankar et al., 2018).
529
Concomitant increase protein-like (C2: U=118, p<0.05 and C4: U=118, p<0.05) and soil-
530
derived components (C3: U=104, p<0.05) and relatively constant input of terrestrial humic-like
531
(C1: U=72, p>0.05) component from the spring low precipitation through moderate to fall high
532
precipitation indicate continuous input of protein-like and soil derived DOM to the bay from
533
agricultural and urbanized areas following precipitation (Fig. 7). The reason for the low
534
variability of the component C1 during all field campaigns could be due to the continuous supply
535
of terrestrial humic-like DOM from the woody herbaceous wetlands present all along the banks
536
of the bay (Sankar et al., 2018). Furthermore, the component C1 has been found in multiple
537
studies as a background fluorescence in fluvial waters due to its refractory nature (Sankar et al.,
538
2018; Singh et al., 2017; 2010). The largest variation of soil derived DOM component (C3)
539
following summer-1 precipitation (IQR= 0.04) could be because of its large influx due to
540
flushing from within and above the dry soil horizons during the initial period of summer
541
precipitation.
542
Based on the variation of both optical indices and DOM composition, it is quite evident
543
that precipitation in the watershed has mobilized a considerable amount of allochthonous fresh
544
microbially reprocessed DOM into the bay from the Weeks Bay Watershed. Additionally, there
545
is a possibility of allochthonous microbially reprocessed DOM input into Weeks Bay through the 24
546
Mobile Bay from Mobile Bay Watershed especially during the events of high tides, however
547
more data is required from the Mobile Bay to ascertain this claim.
548
4.3 Relationship of salinity and dissolved constituents
549
The trace elements and nutrients showed a conservative mixing behavior in the Weeks Bay.
550
Increasing trends in the fluxes of As, Cu, U, NO3-, PO4-, and NO2- with increasing salinity was
551
observed because the field data collection during fall, summer-1, and summer-2 precipitation
552
events coinciding with high tides. Decreasing trends in the fluxes of Fe, Mn, Zn, Hg, and NH4+
553
with increasing salinity indicates their release from bay bottom owing to the highly reducing
554
conditions especially during spring precipitation events. The precipitation induced freshwater
555
input caused an increase in fluxes of As, Cu, U, NO3-, PO4- and NO2-. On the other hand,
556
prevalence of higher redox conditions in the bay bottom during dry weather conditions increased
557
the Fe, Mn, Zn, Hg concentrations along with NH4+ by dissolution of their oxidized forms. The
558
low inverse relationship of Hg and salinity suggests dilutionary effects during the events of
559
precipitation or atmospheric deposition and settling in the bay. The inverse relationship of DOC
560
and TDN with salinity supports the shifting of hydrology from spring low to fall high
561
precipitation events (SI Fig. 4 & 5).
562
4.4 DOM and trace element relationships
563
The samples collected following fall precipitation event were positioned all along the
564
positive side of the PC1 axis indicating protein-like or microbial humic-like DOM input into the
565
bay from the croplands, pasture, and urbanized areas of the watershed. On the contrary, both of
566
the samples collected following summer-1 and summer-2 precipitation events were located on
567
the negative side of the PC2 axis indicating more of microbially reprocessed and soil derived
25
568
DOM input into the bay following summer precipitation (Fig. 8). While all samples collected
569
following the spring precipitation event were in the negative side of the PC1 axis indicating less
570
microbial humic-like or protein-like and more terrestrial humic-like DOM input. The PCA plot
571
clearly shows a strong connection between the fresh, microbially or anthropogenically derived,
572
simpler DOM components (C2 and C4), the trace elements (As, Cu, U), and the nutrients (PO43-
573
and NO3-). Their mutual relationship clearly indicates that As, Cu, U and inorganic N and P
574
nutrients were flushed into the bay along with microbially derived DOM components (C2 and
575
C4) from the adjoining agricultural and urbanized areas (Fig 8 and SI. Fig.6). Furthermore, the
576
positive relationship of pH, with components C2, C4 along with As, Cu, U and PO43- and, NO3-
577
indicates that they entered the bay as the result of water discharge through the rivers following
578
the high amount of precipitation during both fall and summer seasons. Hg shows no correlation
579
with any of the PARAFAC components, nutrients, trace elements, or pH indicating its
580
introduction into the bay through atmospheric deposition or dilutionary effect due to its low
581
concentration. The strong positive relationship of Hg, DOC, and ORP could be due to the
582
formation of Hg-DOM complexes in the bay water under reducing conditions (Gu et al., 2011;
583
Harris et al., 2012; Ravichandran, 2004). A strong positive correlation of Fe and DOC indicates
584
the existence of Fe-DOM colloids in the bay (Stolpe et al., 2010). Similarly, the bootstrap
585
resampling technique also confirmed increase in flux of As, Cu and U with seasonal
586
precipitation, that is from spring to fall in the bay (Fig. 9). On the other hand, the flux of Hg, Mn,
587
and Fe to the bay was high following low amount of precipitation during the spring implying the
588
effect of dilution or the presence of low redox conditions (Table 3). We are also not ruling out
589
the fact that such change in trends of elemental flux in the bay could also be the result of the
26
590
change in redox conditions due to groundwater surface water interactions in the bay. However
591
we do not have associated groundwater data to prove such claim.
592
Only a few studies have evaluated the source of trace elements in the coastal areas of
593
NGoM (Lafabrie et al., 2011; Telfeyan et al., 2017; USEPA, 1999). In the present work, we
594
correlated DOM sources and its chemical properties with trace elements, which was found to be
595
effective in the identification of the source of trace elements. Our results suggest that
596
precipitation in the watershed and the subsequent water discharge through both the rivers into the
597
bay affected the quality and chemistry of the Weeks Bay water. In addition to freshwater
598
discharge from the Fish and Magnolia Rivers, Weeks Bay receives tidal flows from Mobile Bay
599
as well (Passeri et al., 2016). The amount of Mobile Bay water incursion to Weeks Bay or the
600
concentration of water quality parameters in the Mobile Bay was not investigated in this study.
601
However, trends of TDS and salinity in the Weeks Bay observed in this study were similar on all
602
four field campaigns, which can be attributed to tidal effects during the time of field work. The
603
DO concentration of an aqueous solution reduces in response to increase in salinity and
604
temperature (Lay et al., 2010), hence, the low DO content of the bay water following the events
605
of summer and fall precipitation were coinciding with both high salinity and temperature, and
606
high DO concentrations were coinciding with both low salinity and temperature following spring
607
with low amount of precipitation. Freshwater input into Mobile Bay happens mainly through the
608
Tombigbee River, the Alabama River, and their tributaries; which drains a much larger
609
watershed. We acknowledge that the incursion of water from Mobile Bay, which includes
610
freshwater from the Mobile Bay Watershed and seawater, to Weeks Bay may have an effect on
611
the water quality of the Weeks Bay especially during high tides. Collection of field data from the
27
612
Mobile Bay and adjoining coastal waters, and hydrodynamic modeling will help in quantifying
613
the effect of flow of Mobile Bay waters to Weeks Bay.
614
5. Conclusion
615
The trace element, nutrient, and DOM amount in the Weeks Bay was very much
616
dependent on precipitation in the watershed and subsequent water discharge into the bay through
617
the two blackwater rivers, Fish and Magnolia. Statistical analyses of water quality parameters
618
following spring low-fall high precipitation events indicated that the concentration of trace
619
elements As, Cu, and U, and the nutrients NO3- and PO43- were higher in the Weeks Bay
620
following fall high-precipitation events. Moreover, the availability of microbial humic-like or
621
protein-like DOM components increased in the bay along with soil-derived, humic component
622
following precipitation during summer and fall seasons. This clearly indicates that following the
623
fall precipitation, the trace elements As, Cu, and U are exported to the bay along with
624
microbially processed DOM from various anthropogenic sources present in the watershed such
625
as agricultural areas or industries. Further, the spectroscopic properties, BIX (< 1 during the
626
study period), FI (gradually increasing) and SUVA254 (decreasing) along with increasing
627
microbial humic-like, protein-like and soil-derived humic DOM components following higher
628
amount of summer and fall precipitation indicated that the trace metals were mobilized to the bay
629
along with allochthonous DOM. Results also revealed that the trace element and DOM fluxes in
630
Weeks Bay was largely dependent on hydrologic characteristics (precipitation and dishcarge)
631
and land use land cover. Future work may include exploring the inclursion of contaminants into
632
Weeks bay through Mobile Bay and its drainage system during high tides.
633 634
Increasing precipitation events are projected due to global climate change, which can affect DOM-trace element mobility in the coastal waterbodies. This study highlights the 28
635
importance of DOM composition in determining sources of trace elements in the watershed.
636
Increasing precipitation events are projected due to global climate change, which can affect
637
DOM-trace element mobility in the coastal waterbodies in the southern states and worldwide.
638
This study highlights the importance of DOM composition in determining sources of trace
639
elements in the watershed. Trace metals analysis can be time consuming and expensive., while
640
DOM fluorometric analysis is comparatively inexpensive. In this article we have demonstrated
641
the use of DOM composition as PARAFAC components to source track contaminant trace
642
element sources. This method can be utilized to identify the contaminant sources in other regions
643
around the globe.
644
Acknowledgement
645
The research was supported by the faculty start-up grant to Dr. Padmanava Dash. The authors are
646
thankful to Ms. Devon Flickinger and Mr. Rusch Ragland of Department of Geosciences,
647
Mississippi State University and Dr. Scott Phipps of the Weeks Bay National Estuarine Research
648
Reserve for their help during field campaigns.
649
References
650
Apeti, D.A., Lauenstein, G.G., Evans, D.W., 2012. Recent status of total mercury and methyl
651
mercury in the coastal waters of the northern Gulf of Mexico using oysters and sediments
652
from NOAA’s mussel watch program. Mar. Pollut. Bull. 64, 2399–2408.
653
doi:10.1016/j.marpolbul.2012.08.006
654
Bandyopadhyay, S., Ghosh, K., Varadachari, C., 2014. Multimicronutrient slow-release fertilizer
655
of zinc, iron, manganese, and copper. Int. J. Chem. Eng. 2014, 1–7.
656
doi:10.1155/2014/327153 29
657
Benedetti, M.F., Van Riemsdijk, W.H., Koopal, L.K., Kinniburgh, D.G., Gooddy, D.C., Milne,
658
C.J., 1996. Metal ion binding by natural organic matter: From the model to the field.
659
Geochim. Cosmochim. Acta 60, 2503–2513. doi:10.1016/0016-7037(96)00113-5
660
Blanchard, M., Alfredsson, M., Brodholt, J., Wright, K., Catlow, C.R.A., 2007. Arsenic
661
incorporation into FeS2pyrite and its influence on dissolution: A DFT study. Geochim.
662
Cosmochim. Acta 71, 624–630. doi:10.1016/j.gca.2006.09.021
663
Caffrey, J.M., Murrell, M.C., Amacker, K.S., Harper, J.W., Phipps, S., Woodrey, M.S., 2014.
664
Seasonal and Inter-annual Patterns in Primary Production, Respiration, and Net Ecosystem
665
Metabolism in Three Estuaries in the Northeast Gulf of Mexico. Estuaries and Coasts 37,
666
222–241. doi:10.1007/s12237-013-9701-5
667
Camacho, R.A., Martin, J.L., Diaz-Ramirez, J., McAnally, W., Rodriguez, H., Suscy, P., Zhang,
668
S., 2014. Uncertainty analysis of estuarine hydrodynamic models: An evaluation of input
669
data uncertainty in the Weeks Bay estuary, Alabama. Appl. Ocean Res. 47, 138–153.
670
doi:10.1016/j.apor.2014.04.004
671
Dalzell, B.J., Filley, T.R., Harbor, J.M., 2007. The role of hydrology in annual organic carbon
672
loads and terrestrial organic matter export from a midwestern agricultural watershed.
673
Geochim. Cosmochim. Acta 71, 1448–1462. doi:10.1016/j.gca.2006.12.009
674
De Souza, F., Bragança, S.R., 2018. Extraction and characterization of humic acid from coal for
675
the application as dispersant of ceramic powders. J. Mater. Res. Technol. 7, 254–260.
676
doi:10.1016/j.jmrt.2017.08.008
677 678
Duan, S., Bianchi, T.S., Sampere, T.P., 2007. Temporal variability in the composition and abundance of terrestrially-derived dissolved organic matter in the lower Mississippi and 30
679 680
Pearl Rivers. Mar. Chem. 103, 172–184. doi:10.1016/j.marchem.2006.07.003 Fichot, C.G., Benner, R., 2012. The spectral slope coefficient of chromophoric dissolved organic
681
matter (S275-295) as a tracer of terrigenous dissolved organic carbon in river-influenced
682
ocean margins. Limnol. Oceanogr. 57, 1453–1466. doi:10.4319/lo.2012.57.5.1453
683
Gu, B., Bian, Y., Miller, C.L., Dong, W., Jiang, X., Liang, L., 2011. Mercury reduction and
684
complexation by natural organic matter in anoxic environments. Proc. Natl. Acad. Sci. 108,
685
1479–1483. doi:10.1073/pnas.1008747108
686
Hansen, A.M., Kraus, T.E.C., Pellerin, B.A., Fleck, J.A., Downing, B.D., Bergamaschi, B.A.,
687
2016. Optical properties of dissolved organic matter (DOM): Effects of biological and
688
photolytic degradation. Limnol. Oceanogr. 61, 1015–1032. doi:10.1002/lno.10270
689
Harris, R., Pollman, C., Landing, W., Evans, D., Axelrad, D., Hutchinson, D., Morey, S.L.,
690
Rumbold, D., Dukhovskoy, D., Adams, D.H., Vijayaraghavan, K., Holmes, C., Atkinson,
691
R.D., Myers, T., Sunderland, E., 2012. Mercury in the Gulf of Mexico: Sources to
692
receptors. Environ. Res. 119, 42–52. doi:10.1016/j.envres.2012.08.001
693
Hongxia, Y., Jinxu, G., Wei, L., Keyan, T., 2014. Investigating the composition of dissolved
694
organic matter in natural water in rare earth mine using EEM-PARAFAC analysis. Environ.
695
Sci. Process. Impacts 16, 2527–2535. doi:10.1039/C4EM00380B
696
Hu, Y., Lu, Y., Edmonds, J.W., Liu, C., Wang, S., Das, O., Liu, J., Zheng, C., 2016.
697
Hydrological and Land Use Control of Watershed Exports of DOM in a Large Arid River
698
Basin in Northwestern China. J. Geophys. Res. Biogeosciences 121, 466–478.
699
doi:10.1002/2015JG003082
31
700 701 702
Hudak, P.F., 2000. Regional trends in nitrate content of Texas groundwater. J. Hydrol. 228, 37– 47. doi:10.1016/S0022-1694(99)00206-1 Huguet, A., Vacher, L., Relexans, S., Saubusse, S., Froidefond, J.M., Parlanti, E., 2009.
703
Properties of fluorescent dissolved organic matter in the Gironde Estuary. Org. Geochem.
704
40, 706–719. doi:10.1016/j.orggeochem.2009.03.002
705
Jayasumana, C., Fonseka, S., Fernando, A., Jayalath, K., Amarasinghe, M., Siribaddana, S.,
706
Gunatilake, S., Paranagama, P., 2015. Phosphate fertilizer is a main source of arsenic in
707
areas affected with chronic kidney disease of unknown etiology in Sri Lanka. Springerplus
708
4, 1–8. doi:10.1186/s40064-015-0868-z
709
Joung, D., Shiller, A.M., 2014. Dissolved barium behavior in Louisiana Shelf waters affected by
710
the Mississippi/Atchafalaya River mixing zone. Geochim. Cosmochim. Acta 141, 303–313.
711
doi:10.1016/j.gca.2014.06.021
712
Joung, D.J., Shiller, A.M., 2016. Temporal and spatial variations of dissolved and colloidal trace
713
elements in Louisiana Shelf waters. Mar. Chem. 181, 25–43.
714
doi:10.1016/j.marchem.2016.03.003
715
Keul, N., Morse, J.W., Wanninkhof, R., Gledhill, D.K., Bianchi, T.S., 2010. Carbonate
716
chemistry dynamics of surface waters in the Northern Gulf of Mexico. Aquat. Geochemistry
717
16, 337–351. doi:10.1007/s10498-010-9091-2
718
Kim, S.W., Miyahara, M., Fushinobu, S., Wakagi, T., Shoun, H., 2010. Nitrous oxide emission
719
from nitrifying activated sludge dependent on denitrification by ammonia-oxidizing
720
bacteria. Bioresour. Technol. 101, 3958–3963. doi:10.1016/j.biortech.2010.01.030
32
721
Kothawala, D.N.., Murphy, K.R.., Stedmon, C.A.., Weyhenmeyer, G.A.., Tranvik, L.J.., 2013.
722
Inner filter correction of dissolved organic matter fluorescence. Limnol. Oceanogr. Methods
723
11, 616–630. doi:10.4319/lom.2013.11.616
724
Kothawala, D.N., Stedmon, C.A., Müller, R.A., Weyhenmeyer, G.A., Köhler, S.J., Tranvik, L.J.,
725
2014. Controls of dissolved organic matter quality: Evidence from a large-scale boreal lake
726
survey. Glob. Chang. Biol. 20, 1101–1114. doi:10.1111/gcb.12488
727
Lafabrie, C., Major, K.M., Major, C.S., Cebrián, J., 2011. Arsenic and mercury bioaccumulation
728
in the aquatic plant, Vallisneria neotropicalis. Chemosphere 82, 1393–1400.
729
doi:10.1016/j.chemosphere.2010.11.070
730
Lay, W.C.L., Liu, Y., Fane, A.G., 2010. Impacts of salinity on the performance of high retention
731
membrane bioreactors for water reclamation: A review. Water Res. 44, 21–40.
732
doi:10.1016/j.watres.2009.09.026
733
Le Pape, P., Blanchard, M., Brest, J., Boulliard, J.C., Ikogou, M., Stetten, L., Wang, S., Landrot,
734
G., Morin, G., 2017. Arsenic Incorporation in Pyrite at Ambient Temperature at Both
735
Tetrahedral S-Iand Octahedral FeIISites: Evidence from EXAFS-DFT Analysis. Environ.
736
Sci. Technol. 51, 150–158. doi:10.1021/acs.est.6b03502
737
Lewis, M., Chancy, C., 2008. A summary of total mercury concentrations in flora and fauna near
738
common contaminant sources in the Gulf of Mexico. Chemosphere 70, 2016–2024.
739
doi:10.1016/j.chemosphere.2007.09.020
740
Lewis, M.A., Russell, M.J., 2015. Contaminant profiles for surface water, sediment, flora and
741
fauna associated with the mangrove fringe along middle and lower eastern Tampa Bay.
742
Mar. Pollut. Bull. 95, 273–282. doi:10.1016/j.marpolbul.2015.04.001 33
743
Lin, H., Chen, M., Zeng, J., Li, Q., Jia, R., Sun, X., Zheng, M., Qiu, Y., 2016. Size
744
characteristics of chromophoric dissolved organic matter in the Chukchi Sea. J. Geophys.
745
Res. Ocean. 121, 6403–6417. doi:10.1002/2016JC011771
746
Lin, T.Y., Wei, C.C., Huang, C.W., Chang, C.H., Hsu, F.L., Liao, V.H.C., 2016. Both
747
Phosphorus Fertilizers and Indigenous Bacteria Enhance Arsenic Release into Groundwater
748
in Arsenic-Contaminated Aquifers. J. Agric. Food Chem. 64, 2214–2222.
749
doi:10.1021/acs.jafc.6b00253
750
Lu, Y., Bauer, J.E., Canuel, E.A., Yamashita, Y., Chambers, R.M., Jaffé, R., 2013.
751
Photochemical and microbial alteration of dissolved organic matter in temperate headwater
752
streams associated with different land use. J. Geophys. Res. Biogeosciences 118, 566–580.
753
doi:10.1002/jgrg.20048
754
Miller, M.., Phipps, S.W., Major, C.S., Major, K.M., 2011. Effects of Environmental Variation
755
and Non-point Source (NPS) Nutrient Pollution on Aquatic Plant Communities in Weeks
756
Bay National Estuarine Research Reserve (WBNERR), AL. Estuaries and Coasts (2011) 34,
757
1182–1193. doi:10.1007/s12237-011-9422-6
758
Molina, M., Aburto, F., Calderón, R., Cazanga, M., Escudey, M., 2009. Trace element
759
composition of selected fertilizers used in Chile: Phosphorus fertilizers as a source of long-
760
term soil contamination. Soil Sediment Contam. 18, 497–511.
761
doi:10.1080/15320380902962320
762
Perry, H., Isphording, W., Trigg, C., Riedel, R., 2015. Heavy metals in red crabs, Chaceon
763
quinquedens, from the Gulf of Mexico. Mar. Pollut. Bull. 101, 845–851.
764
doi:10.1016/j.marpolbul.2015.11.020 34
765 766 767 768 769
Ravichandran, M., 2004. Interactions between mercury and dissolved organic matter - A review. Chemosphere 55, 319–331. doi:10.1016/j.chemosphere.2003.11.011 Reuter, J.H., Perdue, E.M., 1977. Importance of heavy metal - organic matter interactions in natural waters. Geochim. Cosmochim. Acta 41, 325–334. Ruecker, A., Uzun, H., Karanfil, T., Tsui, M.T.K., Chow, A.T., 2017. Disinfection byproduct
770
precursor dynamics and water treatability during an extreme flooding event in a coastal
771
blackwater river in southeastern United States. Chemosphere 188, 90–98.
772
doi:10.1016/j.chemosphere.2017.08.122
773
Sankar, M.S., Dash, P., Singh, S., Lu, Y.H., Mercer, A.E., Chen, S., 2018. Effect of photo-
774
biodegradation and biodegradation on the biogeochemical cycling of dissolved organic
775
matter across diverse surface water bodies. J. Environ. Sci. (China) 1–18.
776
doi:10.1016/j.jes.2018.06.021
777
Shank, G.C., Evans, A., Yamashita, Y., Jaffé, R., 2011. Solar radiation-enhanced dissolution of
778
particulate organic matter from coastal marine sediments. Limnol. Oceanogr. 56, 577–588.
779
doi:10.4319/lo.2011.56.2.0577
780
Signes-Pastor, A., Burló, F., Mitra, K., Carbonell-Barrachina, A.A., 2007. Arsenic
781
biogeochemistry as affected by phosphorus fertilizer addition, redox potential and pH in a
782
west Bengal (India) soil. Geoderma 137, 504–510. doi:10.1016/j.geoderma.2006.10.012
783
Singh, S., D’Sa, E.J., Swenson, E.M., 2010. Chromophoric dissolved organic matter (CDOM)
784
variability in Barataria Basin using excitation-emission matrix (EEM) fluorescence and
785
parallel factor analysis (PARAFAC). Sci. Total Environ. 408, 3211–3222.
786
doi:10.1016/j.scitotenv.2010.03.044 35
787
Singh, S., Dash, P., Silwal, S., Feng, G., Adeli, A., Moorhead, R.J., 2017. Influence of land use
788
and land cover on the spatial variability of dissolved organic matter in multiple aquatic
789
environments. Environ. Sci. Pollut. Res. doi:10.1007/s11356-017-8917-5
790
Slowey, F.J., Hood, D.W., 1971. Copper, manganese and zinc concentrations in Gulf of Mexico
791
waters. Geochim. Cosmochim. Acta 35, 121–138. doi:https://doi.org/10.1016/0016-
792
7037(71)90052-4
793
Spencer, R.G.M., Aiken, G.R., Dornblaser, M.M., Butler, K.D., Holmes, R.M., Fiske, G., Mann,
794
P.J., Stubbins, A., 2013. Chromophoric dissolved organic matter export from U.S. rivers.
795
Geophys. Res. Lett. 40, 1575–1579. doi:10.1002/grl.50357
796
Stedmon, C. a., Bro, R., 2008. OCEANOGRAPHY : METHODS Characterizing dissolved
797
organic matter fluorescence with parallel factor analysis : a tutorial. Limnol. Oceanogr.
798
Methods 6, 572–579. doi:10.4319/lom.2008.6.572
799
Stedmon, C. a., Markager, S., 2005. Tracing the production and degradation of autochthonous
800
fractions of dissolved organic matter using fluorescence analysis. Limnol. Oceanogr. 50,
801
1415–1426. doi:10.4319/lo.2005.50.5.1415
802
Stolpe, B., Guo, L., Shiller, A.M., Hassellov, M., 2010. Size and composition of colloidal
803
organic matter and trace elements in the Mississippi River, Pearl River and the northern
804
Gulf of Mexico, as characterized by flow field-flow fractionation. Mar. Chem. 118, 119–
805
128. doi:10.1016/j.marchem.2009.11.007
806
Telfeyan, K., Breaux, A., Kim, J., Cable, J.E., Kolker, A.S., Grimm, D.A., Johannesson, K.H.,
807
2017. Arsenic, vanadium, iron, and manganese biogeochemistry in a deltaic wetland,
808
southern Louisiana, USA. Mar. Chem. 192, 32–48. doi:10.1016/j.marchem.2017.03.010 36
809
Telfeyan, K., Breaux, A., Kim, J., Kolker, A.S., Cable, J.E., Johannesson, K.H., 2018. Cycling of
810
oxyanion-forming trace elements in groundwaters from a freshwater deltaic marsh. Estuar.
811
Coast. Shelf Sci. 204, 236–263. doi:10.1016/j.ecss.2018.02.024
812
Tribovillard, N., Riboulleau, A., Lyons, T., Baudin, F., 2004. Enhanced trapping of molybdenum
813
by sulfurized marine organic matter of marine origin in Mesozoic limestones and shales.
814
Chem. Geol. doi:10.1016/j.chemgeo.2004.08.011
815 816 817 818
USEPA, 1999. The Ecological Condition of Estuaries in the Gulf of Mexico. EPA 620-R-98-004 80. USEPA, 1983. Sample preservation. pp.xv-xx. In Methods for Chemical Analysis of Water and Wastes, EPA-600/4-79-020. U.S.E.P.A., Cincinnati, Ohio, USA
819
USGS, 1999. Collection of Water Samples. TWRI Book 9, Chapter A4.
820
Valero, N., Gómez, L., Pantoja, M., Ramírez, R., 2014. Production of humic substances through
821
coal-solubilizing bacteria. Brazilian J. Microbiol. 45, 911–918. doi:10.1590/S1517-
822
83822014000300021
823
Weng, L., Temminghoff, E.J.M., Lofts, S., Tipping, E., Van Riemsdijk, W.H., 2002.
824
Complexation with dissolved organic matter and solubility control of heavy metals in a
825
sandy soil. Environ. Sci. Technol. 36, 4804–4810. doi:10.1021/es0200084
826
Yamashita, Y., Jaffé, R., 2008. Characterizing the interactions between trace metals and
827
dissolved organic matter using excitation-emission matrix and parallel factor analysis.
828
Environ. Sci. Technol. 42, 7374–9. doi:10.1021/es801357h
829
Zhang, Y., Liu, X., Osburn, C.L., Wang, M., Qin, B., Zhou, Y., 2013. Photobleaching Response
37
830
of Different Sources of Chromophoric Dissolved Organic Matter Exposed to Natural Solar
831
Radiation Using Absorption and Excitation-Emission Matrix Spectra. PLoS One 8.
832
doi:10.1371/journal.pone.0077515
833
Zhou, Z., Stolpe, B., Guo, L., Shiller, A.M., 2016. Colloidal size spectra, composition and
834
estuarine mixing behavior of DOM in river and estuarine waters of the northern Gulf of
835
Mexico. Geochim. Cosmochim. Acta 181, 1–17. doi:10.1016/j.gca.2016.02.032
836
Zielinski, R.A., Foster, A.L., Meeker, G.P., Brownfield, I.K., 2007. Mode of occurrence of
837
arsenic in feed coal and its derivative fly ash, Black Warrior Basin, Alabama. Fuel 86, 560–
838
572. doi:10.1016/j.fuel.2006.07.033
839
List of figures
840
Fig. 1 Land use and land cover map of the study area with sampling points indicated
841
Fig. 2 Precipitation in the Weeks Bay watershed and discharge through the Fish and Magnolia
842
Rivers
843
Fig. 3 Variation in the fluxes of trace elements to Weeks Bay following spring (n=12), summer-1
844
(n=12), summer-2 (n=13) and fall (n=12) sampling events. ‘n’ denotes number of samples.
845
Fig. 4 Variation in fluxes of nutrients to Weeks Bay following spring (n=12), summer-1 (n=12),
846
summer-2 (n=13) and fall (n=12) sampling events. ‘n’ denotes number of samples.
847
Fig. 5 Variation of absorption (SUVA254, SR) and fluorescence indices (HIX, FI, BIX) in Weeks
848
Bay water following spring (n=12), summer-1 (n=12), summer-2 (ML, n=13) and fall (n=12)
849
sampling events. ‘n’ denotes number of samples.
38
850
Fig. 6 Excitation (blue curve) and emission (red curve) loadings for four dissolved organic
851
matter components derived using a parallel factor (PARAFAC) model that was validated using
852
split-half analysis as well as random initialization. Contour plots corresponding to the
853
components identified in the PARAFAC model are shown for each of the components.
854
Fig. 7 Variation of parallel factor (PARAFAC) components in Weeks Bay water following
855
spring (n=11), summer-1 (n=12), summer-2 (n=12) and fall (n=11) sampling events. ‘n’ denotes
856
number of samples.
857
Fig. 8 Principal component analysis (PCA) biplot for the Weeks Bay water chemistry. Samples
858
collected following spring (L, n=11), summer-1 (n=12), summer-2 (n=11) and fall (n=11)
859
sampling events were indicated by distinct symbols. ‘n’ denotes number of samples.
860
Fig. 9 Bootstrap resampling results of the discharged normalized concertation of trace elements
861
in Weeks Bay water following spring (n=1000), summber-1 (n=1000), summer-2 (n=1000) and
862
fall (n=1000) sampling events. ‘n’ denotes number of bootstrap means.
863
List of Tables
864
Table 1 The amount of land use and land cover area in km2 and in percentages of Weeks Bay
865
watershed
866
Table 2 The average amount of precipitation in the Weeks Bay watershed and discharge through
867
the Fish and Magnolia Rivers during five days prior to the sampling events during spring,
868
summer-1, summer-2 and fall field campaigns
869
Table 3 Distribution of water quality parameters for Weeks Bay waters collected during four
870
field campaigns
39
871
Table 4 Parallel factor (PARAFAC) analysis components information and their identification
872
Table 5 Bootstrap 2.5 %, 50% and 97.5 % quantile values of trace elements following spring,
873
summer-1, summer-2 and fall water sampling events.
40
Tables:
Table 1 Land Classes Open Water Developed, Open Space Developed, Low Intensity Developed, Medium Intensity Developed, High Intensity Barren Land Deciduous Forest Evergreen Forest Mixed Forest Shrub/Scrub Herbaceuous Hay/Pasture Cultivated Crops Woody Wetlands Emergent Herbaceuous Wetlands
Area (Km2) 4.49 22.02 7.89 2.75 0.56 2.20 0.31 22.14 0.64 8.79 13.29 49.02 64.86 37.88 4.79
Area (%) 1.86 9.11 3.27 1.14 0.23 0.91 0.13 9.16 0.27 3.64 5.50 20.29 26.84 15.68 1.98
Table 2 Name of the Date of sampling sampling events
Spring Summer-1 Summer-2 Fall
05/09/2016 06/19/2016 06/26/2016 09/30/2016
Average amount of precipitation five days prior to the sampling (mm) 0.66 3.51 0.15 2.03
Average discharge through Fish River five days prior to sampling (m3/s)
5.51± 4.93 2.19± 0.03 1.70± 0.03 1.93± 0.10
Average discharge through Magnolia River five days prior to sampling (m3/s)
0.78± 0.06 0.77± 0.22 0.60± 0.02 1.80± 2.48
Table 3 Water Quality Parameter pH
ORP (mV)
TDS (mg/L)
Salinity (PSU)
DO (mg/L)
Temperature (°C)
Spring
Summer-1
Summer-2
Fall
Avg:8.06±0.31 Avg:8.20±0.34 Avg=8.69±0.23 Avg=8.78±0.20 IQR=0.23 IQR=0.48 IQR=0.26 IQR=0.13 Max=8.9 Max=8.57 Max=8.95 Max=9 Min =7.71 Min=7.59 Min=8.13 Min=8.21 Avg=-58.24±44.08 Avg=-17.63±27.81 Avg=-31.06±14.90 Avg=-79.78±47.62 IQR=78.65 IQR=42.80 IQR=22.15 IQR=14.70 Max=-6.10 Max=32.60 Max=-3.90 Max= -41.4 Min =-119.30 Min =-57.0 Min =-57.40 Min = -224.8 Avg=1984.25±2069.54 Avg=7125.92±3318.26 Avg=5684.17±2486.38 Avg=10973.50±3464.25 IQR=4097 IQR= 4729.75 IQR= 3009.25 IQR= 2524.75 Max=4261 Max= 11790 Max= 9611 Max= 17120 Min =7 Min =742 Min =86 Min = 3063 Avg=2.20±2.30 Avg=8.30±4.08 Avg=6.47±2.95 Avg=13.25±4.46 IQR=4.56 IQR=5.90 IQR=3.63 IQR=3.31 Max=4.75 Max= 14.17 Max=11.32 Max=21.43 Min =0.01 Min = 0.74 Min =0.08 Min =3.32 Avg=5.80±4.36 Avg=1.62±0.12 Avg=1.54±0.18 Avg=0.38±0.02 IQR=8.09 IQR=0.10 IQR=0.15 IQR=0.02 Max=12.6 Max=1.81 Max=1.79 Max=0.41 Min =1.59 Min =1.39 Min =1.07 Min =0.35 Avg=27.00±3.66 Avg=29.27±0.68 Avg=31.47±0.54 Avg=26.20±0.72 IQR=6.95 IQR=1.12 IQR=0.68 IQR=1.07 Max=30.83 Max=30.14 Max=32.06 Max=27.55 Min =23.43 Min =28.26 Min =30.33 Min =25.17
Table 4 Components (Ex/Em) unit nm
Description and reference
C1
(<250-330/448)
Terrestrial humic-like component, common in freshwater environment C1 Kothawala et al., 2014 C Coble 1996 C1 Singh et al., 2017 C1 Yamashita et al.,2010 C2 Sankar et al., 2018
C2
(<250-310/388)
Microbial Humic like, Anthropogenic origin, Protein like, common in agriculture dominated watershed, Prevalent in waste water, Microbially reprocessed, like marine humic-like C4 Yamashita et al.,2010 C2 Kothawala et al., 2014 C2 Singh et al., 2017 C3 Kowalczuk et al., 2010 C3 Hosen et al., 2014
C3
(270-400/504)
Humic-like, Terrestrial origin, high molecular weight and aromatic organic compounds, Soil derived, reduced terrestrial, common in wide range of freshwater environments such as wetlands and rangelands, humic acid-type C3 Kothawala et al., 2014 C4 Kowalczuk et al., 2010 C3 Singh et al., 2017 C5 Yamashita et al.,2010 C2 Hosen et al., 2014 C2 Lu et al., 2013
C4
(280/334)
Tryptophan-like, Protein like, autochthonous production; autochthonous algal and microbially derived proteins; Protein like indicative of recent production, also commonly found in croplands, wastewater, industrial, and livestock wastes C8 Fellman et al., 2009 C4 Singh et al., 2017 T Coble, 1996 C6 Kowalczuk et al., 2010 C7 Yamashita et al.,2010 C4 Hosen et al., 2014 C4 Singh et al., 2014
Table 5 Sampling Session Bootstrap Quantiles As Mn U Cu Zn Hg Fe
Flux during Spring (mgs-1) 2.5 % 50 % 97.5 % 20.41 20.76 242.55 265.78 1.50 1.62 5.45 5.72 7.33 9.05 0.38 0.42 1279.96 1429.23
21.10 288.54 1.72 6.00 11.62 0.45 1600.28
Flux during Summer-1 (mgs-1) 2.5 % 50 % 97.5 % 12.26 137.14 0.99 4.35 4.39 0.08 369.5742
13.07 156.38 1.17 5.18 7.59 0.09 411.07
13.83 175.91 1.36 6.72 13.74 0.10 459.99
Flux during Summer-2 (mgs-1) 2.5 % 50 % 97.5 %
Flux during Fall (mgs-1) 2.5 % 50 % 97.5 %
12.67 105.61 0.64 3.56 1.93 0.02 211.66
40.96 43.46 147.81 155.98 2.26 2.41 52.79 71.70 3.09 3.43 0.11 0.21 406.25 442.37
13.49 110.57 0.69 3.77 2.12 0.02 219.19
14.19 117.14 0.74 3.94 2.37 0.03 227.38
46.39 164.18 2.60 96.11 3.84 0.40 483.63
Figures:
Fig. 1
Fig. 2
Fig. 3
Fig. 4
Fig. 5
C1
C2
C3
C4
Fig. 6
Fig. 7
F
ig. 8
Fig. 9
Highlights: •
Dissolved organic matter compositions were used for source-tracking trace metals.
•
Flux of As, Cu, U, PO4, and NO3 correlated with protein-like and soil derived DOM.
•
The trace element and DOM mobility was controlled by precipitation and discharge.
•
Multivariate statistics revealed anthropogenic sources for the trace metals.
We do not have any conflicts of interests.