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Nickel partitioning and toxicity in sediment during aging: Variation in toxicity related to stability of metal partitioning David M. Costello, Chad R. Hammerschmidt, and G. Allen Burton Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.6b04033 • Publication Date (Web): 16 Sep 2016 Downloaded from http://pubs.acs.org on September 18, 2016
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NICKEL PARTITIONING AND TOXICITY IN SEDIMENT DURING AGING: VARIATION IN
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TOXICITY RELATED TO STABILITY OF METAL PARTITIONING
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David M. Costello1,*, Chad R. Hammerschmidt2, and G. Allen Burton Jr.3,4
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1. Department of Biological Sciences, Kent State University, Kent, OH, 44242, USA
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2. Department of Earth & Environmental Sciences, Wright State University, Dayton, OH,
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45435, USA 3. School of Natural Resources & Environment, University of Michigan, Ann Arbor, MI, 48109, USA 4. Earth & Environmental Sciences, University of Michigan, Ann Arbor, MI, 48109, USA
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* Corresponding author
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Department of Biological Sciences PO Box 5190 Kent, OH 44242 Phone: (330) 672-2035 Email:
[email protected] 22
1 Table
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4 Figures
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Abstract
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Metals in sediment can be complexed by minerals, partition between solid and aqueous
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phases, and cause toxicity at high concentrations. We studied how the oxidation of surface
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sediment that occurs during aging alters the partitioning and toxicity of Ni. Two sediments
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(Burntwood and Raisin) were amended with Ni, equilibrated, incubated in a flow-through flume,
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and examined for sediment physicochemistry and toxicity to Hyalella azteca (7-d growth).
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Through time, the sediment surface (5 mm) was oxidized, acid-volatile sulfide concentrations
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declined in Raisin sediment, and amorphous Fe oxides increased. Porewater Ni concentrations
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declined through time but total Ni concentrations in sediment were unchanged, suggesting
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changes in Ni partitioning through time. Both sediments elicited a toxic dose–response by H.
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azteca early in the aging process; but only Burntwood, for which Ni was primarily partitioned to
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Fe oxide minerals, exhibited a consistent dose–response during aging. Low total Ni
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concentrations (20 mg kg-1) in Raisin sediment reduced H. azteca growth at initiation, but all Ni
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treatments (up to 3000 mg kg-1) exhibited similar growth after 12 days of aging. The dynamic
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toxicity observed in Raisin sediment was likely due to the instability of NiS in surface sediments
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early in the aging process. These data suggest that short-term toxicity assays with
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homogenized Ni-amended sediment (i.e., standard sediment toxicity tests) may be accurate for
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sediments where Ni speciation is dominated by oxidized ligands; however, under high-AVS and
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high-Fe conditions, calculated toxicity thresholds may be overly conservative (here by >100-
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fold) with respect to natural sediment conditions.
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TOC Art.
Non-toxic
Sediment toxicity
Raisin
Burntwood
Dynamic toxicity High AVS & moderate Fe Changing Ni partitioning
Stable toxicity Low AVS & high Fe Stable Ni partitioning
Highly toxic
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Aging amended sediment
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Introduction Partitioning and toxicity of metals (e.g., Cu, Ni, Zn) in sediment is strongly controlled by the
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abundance and distribution of other elements and molecules that co-precipitate, adsorb, and
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otherwise complex metals.1–3 A large and growing body of evidence demonstrates that, for most
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organisms, only freely dissolved metal ions cause toxicity, and metals bound to solid-phase
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ligands are non-toxic.1,4–7 Thus, the geochemical characteristics of sediment are key to
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controlling toxicity, and widely used sediment bioavailability models account for metal binding by
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reduced sulfur and organic carbon,1,8–10 which are purported to be the most important binding
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ligands. Although such multi-parameter bioavailability models offer more accurate estimates of
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toxicity than criteria derived from total metal concentrations, there are still limitations to this
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approach. Primary limitations to the current bioavailability models include an assumption of
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homogenous equilibrium conditions and an omission of metal binding to commonly occurring
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Fe, Mn, and Al oxide minerals.
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Natural sediments and their chemical constituents are rarely homogenous and at
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equilibrium; spatial and temporal variation in physicochemical conditions can occur at fine (e.g.,
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sediment–water interface, diel) and broad (e.g., within a watershed, seasonal) scales.11,12
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Hyporheic exchange of well-oxygenated surface water into stream sediments coupled with high
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biological oxygen demand establishes strong redox gradients near the sediment–water
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interface.13 Thus, stream sediment is often characterized by a shallow (1–10 mm) oxic surface
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layer overlying reduced material. This spatial redox gradient is important for metal bioavailability
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because biota primarily interact with the oxidized surface layer and some metal-binding ligands
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are not thermodynamically stable under either oxidizing or reducing conditions. Amending
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sediment with metals, which is a common experimental approach for establishing dose–
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response thresholds, requires homogenization that perturbs sediment physicochemical
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conditions and may impact the realism of experimental scenarios when compared to naturally
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contaminated sediments.14,15 Furthermore, the timespan of most sediment dose–response 4 ACS Paragon Plus Environment
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experiments (3000 µg L-1. Our regression analysis showed no relationship between the deep
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porewater Ni concentration and the reduction in H. azteca growth. The mismatch between 17 ACS Paragon Plus Environment
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porewater Ni concentrations at depth and H. azteca growth rates emphasizes the point that
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conditions at the sediment surface, where organism exposure occurs, cannot be estimated from
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deep sediment chemistry.34 The dynamic H. azteca dose–response is most likely related to
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oxidation of AVS and release of sulfide-bound Ni. Additional support for this is found in the
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inability of sulfur-based bioavailability models to predict non-toxic conditions in freshly amended
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sediment. The first toxicity assay was completed when AVS concentrations were changing most
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rapidly (2 days of aging, Figure 1), and at that time sediment with AVS in excess of NiSEM
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resulted in H. azteca RGR that were 30% lower than control conditions. When Raisin sediment
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was fully aged and AVS concentrations had stabilized (>20 days of aging, Figure 1), there were
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no longer any treatments with observed toxicity when AVS exceeded NiSEM, but there were
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many sediments that exceeded non-toxic thresholds8,31 and no reduction in growth rates was
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observed. The treatments that exceeded the non-toxic threshold (i.e., 130 µmol Ni g-1 OC) fell
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into the range of ‘uncertain toxicity’ (130–3000 µmol Ni g-1 OC),1 so it is not unprecedented that
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no toxicity was observed. However, Besser and colleagues22 demonstrated that Raisin sediment
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is potentially toxic above the non-toxic threshold; the same Raisin sediment (RR3) caused
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significant mortality of H. azteca over a 28-d assay (i.e., LC20) when bioavailable Ni
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concentrations exceeded 108 µmol Ni g-1 OC.22 This study adds to the growing body of
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evidence demonstrating that AVS-based bioavailability models are inadequate for making
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predictions in sediment under non-equilibrium conditions with distinct vertical redox gradients
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and these models are not sufficiently resolved to predict toxic conditions.17,19
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Consequences for sediment risk assessment. Comparing between our sediments at
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different sampling periods allows us to draw critical conclusions about making risk assessment
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decisions about Ni in sediment. Early in the experiment, Raisin sediment was toxic at a lower Ni
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concentration than Burntwood sediment (EC10: 20 and 410 mg kg-1, respectively), whereas
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aged sediment provided opposite conclusions (EC10: >3000 and 410 mg kg-1, respectively).
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Considering most effects assessments are based on short-term (100-fold) when compared to field
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contaminated sediment in lotic systems. Although the magnitude of change in dose–response
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was large, the rate at which these sediments changed was quite fast. For the Raisin sediment,
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the dose–response relationship that was not representative of field conditions was eliminated
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after just 12 days of aging. However, we would caution that the very high amorphous Fe oxide
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concentrations with abundant binding sites may have contributed to the rapid decline in toxicity.
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It may be the case that reduced growth rates may have been sustained in a sediment with a
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lower concentration of oxidized ligands. These results are consistent with those from a similar
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study of Cu-amended sediment,6 which also demonstrated that sediment with reduced ligands
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required aging to reestablish oxidized surface sediment for accurate predictions of toxicity in
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field contaminated sediments.
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Acknowledgments.
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Jennifer Daley, Kyle Fetters, Maggie Grundler, Anna Harrison, Sara Nedrich, Olivia Rath, and
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Larissa Sano assisted with experimental setup and sampling. Katelynn Alcorn, Nick Johnson,
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Daniel Marsh, and Brendan Shields assisted with geochemical analyses. Chris Schlekat, Emily
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Rogevich Garman and three anonymous reviewers provided comments that improved this
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manuscript. Funding was provided by Rio Tinto, Nickel Producers Environmental Research
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Association, Copper Alliance, International Lead Zinc Research Organization, Vanitec, and
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Cobalt Development Institute.
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Supporting Information Available. Available information includes additional sediment
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chemistry results and a glossary of abbreviations. Also included are supporting tables of mean
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NiTOT concentrations, QA/QC results, and statistical results and figures depicting sediment
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physicochemistry (i.e., DOPEN, DOC, pH, Fe, Mn, NiSEM, and NiCFO) measured through time,
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Ni:Fe ratios in sediment, plots of raw data from all toxicity tests, a summary plot of dose–
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response statistical models, tissue Ni concentrations through time, and the relationship between
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RGR and porewater Ni. This material is available free of charge via the Internet at
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http://pubs.acs.org.
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Figure 1. Raisin surface (A) and deep (B) sediment AVS measured through time as sediment
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aged in a flow-through flume. Warmer colors (orange > yellow > green > blue > violet) indicate
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higher sediment NiTOT (mean NiTOT reported in legend). Solid lines indicate best-fit lines for
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specific NiTOT treatments as determined by multiple regression.
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Figure 2. Ni in pore waters of Burntwood (A) and Raisin (B) deep sediments as they aged in a
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flow-through flume. Warmer colors indicate higher sediment NiTOT. Solid lines indicate best-fit
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lines for specific NiTOT treatments as determined by multiple regression. Note change in scale on
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the y-axis between panels.
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Figure 3. Relative growth rates (RGR) of Hyalella azteca exposed to Burntwood and Raisin
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sediments from the first four of seven sampling dates (after 2, 9, 16, and 23 days of aging)
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representing the time period when toxicity in Raisin sediment was most dynamic (data from all
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sampling periods can be found in SI Figure S9). Data from all time periods was pooled for fitting
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statistical models and calculating best-fit lines; RGR was negatively related to Ni in both
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sediments (p < 0.01), but Raisin sediment became less toxic through time (NiTOT × time, p =
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0.002) and Burntwood sediment dose–response was stable (p = 0.07). Dashed lines and slopes
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represent best-fit lines for dose–response relationships on those particular days (e.g.,
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Burntwood: RGRD2 = 0.11 – 0.14 × log(NiTOT)). Note the log scale on the x-axis and the change
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in scale between Burntwood and Raisin sediment.
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Figure 4. Hyalella azteca growth in response to solid-phase bioavailable Ni in Raisin surface
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sediment of different ages. Each symbol represents the mean growth rate of replicate chambers
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from a single treatment on a given sampling date (n = 5) normalized relative to the predicted
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growth on reference sediment. Solid-phase bioavailable Ni is expressed as the concentration of
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simultaneously extracted Ni (NiSEM) in excess of acid volatile sulfide (AVS) corrected for
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sediment organic carbon (OC) content. Warmer colors indicate higher NiTOT treatments.
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Numbers indicate sampling days on which the RGR for the nearest symbols were measured. 22 ACS Paragon Plus Environment
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Samples identified with asterisks are samples where RGR was reduced below control rates
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when bioavailable Ni concentrations were below the empirical non-toxic threshold (120 µmol
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NiSEM g-1 OC).1,31 The arrow indicates the increase in H. azteca growth rate in the high Ni
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sediment (3000 mg kg-1) as it aged (RGR after 2 and 100 days of aging are identified).
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Table 1. Initial physicochemical characteristics of test sediments prior to spiking with Ni and aging in a flow-through
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mesocosm.
sediment
acid volatile sulfide (µmol g-1)
organic matter (%)
total carbon (%)
total Fe (mg kg-1)
amorphous Fe oxides (mg kg-1)
crystalline Fe oxides (mg kg-1)
total Ni (mg kg-1)
Burntwood Raisin
0.01 9.1
10 15
4.2 8.2
42000 13000
3200 5300
13000 2900
55 5
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Figure 1
Acid volatile sulfide (µmol g−1)
Acid volatile sulfide (µmol g−1)
Raisin 15
A
7 260 620 1300 3000
surface
10
5
0 15
0
B
20
40
60
80
100
80
100
deep
Aging time (d) 10
5
0 0
20
40
60
Aging time (d)
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Figure 2
Porewater Ni (µg L−1)
2500
A
Burntwood
2000
B
Raisin
10000 8000
1500
6000
1000
4000
500
2000
0
0 0
20
40
60
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100
0
20
Aging time (d)
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Aging time (d)
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Figure 3
BURNTWOOD 0.20
0.20
0.15
0.10
0.10
0.05
0.05
Relative growth rate (mg mg-1 d-1)
0.20
slope = -0.014 10
100
0.00 1000 0.20
d9
0.15
0.15
0.10
0.10
0.05
0.05
0.00
0.20
slope = -0.014 10
100
0.00 1000 0.20
d16
0.15
0.15
0.10
0.10
0.05
0.05
0.00
0.20
slope = -0.014 10
100
0.00 1000 0.20
d23
0.15
0.15
0.10
0.10
0.05
0.05
0.00
d2
d2
0.15
0.00
RAISIN
slope = -0.014 10
100
0.00 1000
slope = -0.020 1
10
100
1000
d9
slope = -0.008 1
10
100
1000
d16
slope = -0.004 1
10
100
1000
d23
slope = -0.001 1
10
100
Total Ni (mg kg-1 dw)
ACS Paragon Plus Environment
1000 10000
Page 31 of 32
Environmental Science & Technology
Normalized RGR (% of ref)
Figure 4
140
100
120 100 80
*
60
2
*
40 -200
0
200
400
600
(NiSEM-AVS)/f OC (µmol NiSEM g−1 OC)
ACS Paragon Plus Environment
Dynamic toxicity
Non-toxic 0.01
Environmental Science Technology Page 32 of 32 AVS & moderate Fe Raisin &High Changing Ni partitioning
Slope estimate
Sediment toxicity
0.00
-0.01 -0.02 Burntwood
-0.03
Stable toxicity Low AVS & high Fe Stable Ni partitioning
ACS Paragon Plus Environment -0.04 Highly toxic 0
20 40 60 80 100 Aging amended sediment
