Electron Transfer Budgets and Kinetics of Abiotic Oxidation and

7 Apr 2015 - total EAC of humic acid toward reaction with sulfide ... EAC from organic sulfur formation (assuming Sorg to be zerovalent, see section ...
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Electron transfer budgets and kinetics of abiotic oxidation and incorporation of aqueous sulfide by dissolved organic matter Zhiguo Yu, Stefan Peiffer, Jörg Göttlicher, and Klaus-Holger Knorr Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/es505531u • Publication Date (Web): 07 Apr 2015 Downloaded from http://pubs.acs.org on April 11, 2015

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Electron transfer budgets and kinetics of abiotic

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oxidation and incorporation of aqueous sulfide by

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dissolved organic matter

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Zhi-Guo Yu1, 2 , Stefan Peiffer1, Jörg Göttlicher3, Klaus-Holger Knorr1, 2,*

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1

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Universitätsstrasse 30, 95447 Bayreuth, Germany

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2

Limnological Research Station & Department of Hydrology, University of Bayreuth,

present address: Hydrology Group, Institute of Landscape Ecology, University of Münster,

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Heisenbergstr.2, 48149 Münster, Germany

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3

12

Eggenstein-Leopoldshafen, Germany

ANKA Synchrotron Radiation Facility, Karlsruhe Institute of Technology, 76344

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KEYWORDS: Sulfur cycling; Humic acid; anoxic conditions; Electron transfer; organic

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sulfur; Redox processes, Freshwater systems

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TABLE OF CONTENTS GRAPHIC

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ABSTRACT

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The reactivity of natural dissolved organic matter (DOM) towards sulfide and has not been

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well studied with regard to electron transfer, product formation and kinetics. We thus

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investigated the abiotic transformation of sulfide upon reaction with reduced and non-reduced

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Sigma Aldrich humic acid (HA), at pH 6 under anoxic conditions. Sulfide reacted with non-

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reduced HA at conditional rate constants of 0.227~0.325 h-1. The main transformation

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products were elemental S (S0), and thiosulfate (S2O32-), yielding electron accepting capacities

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of 2.82~1.75 µmol e- (mg C) -1. Native iron contents in the HA could account for only 6~9%

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of this electron transfer. About 22~37 % of S reacted with the HA to form organic S (Sorg).

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Formation of Sorg was observed and no inorganic transformation products occurred for

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reduced HA. X-ray absorption near edge structure (XANES) spectroscopy supported Sorg to

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be mainly zerovalent, such as thiols, organic di- and polysulfides, or heterocycles. In

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conclusion, our results demonstrate that HA can abiotically re-oxidize sulfide in anoxic

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environments at rates competitive to sulfide oxidation by molecular oxygen or iron oxides.

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INTRODUCTION

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Bacterial sulfate reduction (BSR) to sulfide is recognized as an important pathway of organic

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matter degradation in freshwater systems. High rates of BSR have been observed in many

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studies.1–3 However, sulfate (SO42-) concentrations in wetlands, lake sediments and rice paddy

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soils are often in the micromolar-range, and stocks are thus considered too low to sustain

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sulfate reduction in the long-term.3,4 S cycling has been intensively studied for decades,5–9

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also because sulfide is a highly reactive towards iron oxides and other inorganic elements,

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leading to partial oxidation and formation of e.g. S0 and S2O32-.10,11 Such fast and spontaneous

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sulfide oxidation has led to the hypothesis that abiotic reoxidation of sulfide to S0 and S2O32-,

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or potentially microbially mediated further oxidation to SO42-, could sustain the observed high

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rates of sulfate reduction.3,5,7

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Besides the commonly considered inorganic electron acceptors, organic matter may play a

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crucial role in redox processes in the environment.12 While it is known that functional groups

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of organic matter, such as quinones,13 can be reversibly reduced by acting as electron

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acceptors in anaerobic microbial respiration,12,14–16 less is known of redox reactions of

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reactive species, such as sulfide, with organic matter.3,17,18

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In a laboratory batch experiment at pH 6, DOM mediated the oxidation of sulfide on a time

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scale of hours, leading to the formation S2O32- and Sorg.18 The electron accepting capacity of

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DOM (Pahokee Peat Reference HA (PP-HA)) for sulfide calculated from S2O32- formation

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was 0.6 µmol e- (mg C) -1. From studies of sediment diagenesis, it is known that upon

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reaction of sulfide with organic matter, also Sorg is formed during early stages of diagenesis,

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e.g. by Michael additions to oxidized quinones,17 by addition to unsaturated C double-bonds

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e.g. of lipids, 19,20 or by cross linkage of carbohydrates. 21 However, the short term and

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instantaneous reactivity of organic matter towards sulfide is still poorly understood and little

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is known of the transformation products, especially the species of Sorg that form.18,22

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Reduced organic S is identified as an important functional group in terrestrial and aquatic

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DOM, e.g. for influencing trace metal transport and fate in the ecosystem.22 Nevertheless, it

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remains difficult for the organic forms of S to disentangle the different functional groups and

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to determine their redox states.23 In FTIR spectroscopy, spectral features of S groups are

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difficult to evaluate as they overlap with other non-S functional groups ubiquitous in organic

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matter.18 Due to these methodological constraints there is still a need to elucidate, which

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organic S species typically form in sulfidic systems.

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To quantitatively understand S cycling under anoxic conditions and to set up an electron

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budget of sulfide oxidation and/or incorporation upon reaction with DOM, the determination

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of the redox speciation of Sorg is essential. While methods have been established for analysis

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of inorganic S specie,18,24 only few studies applied S K-edge XANES spectroscopy to identify

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Sorg speciation in natural organic matter.22,25,26 These latter studies suggest that XANES can

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be used to track Sorg speciation to understand S cycling in freshwater systems.

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In our study, we aimed at quantifying and characterizing the inorganic and organic products

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of sulfide oxidation by DOM, using a combined approach of wet chemical analysis and

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XANES spectroscopy. We hypothesized that the major oxidation product of sulfide would be

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thiosulfate, elemental S, and organic S. The latter could provide a diagenetic sink for S, but

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may contribute significantly to the S and electron budget. Thus, we intended to establish an

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electron budget including the redox state of Sorg. We further expected that organic matter

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subjected to reducing conditions, i.e. with lower electron accepting capacity, would have a

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lower reactivity towards sulfide compared to organic matter from oxidizing environments. By

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calculation of reaction rates we aimed at providing time scales of the oxidation of sulfide and

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the formation of Sorg.

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MATERIALS AND METHODS

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Preparation of humic acid solutions.

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As a model compound for our study, humic acid (HA) was purchased from Sigma Aldrich

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and used as received. The elemental composition is provided in SI, Table S1. HA stock

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solutions for batches were prepared by dissolving the HA powder in Millipore water (≥18.2

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MΩ cm) at pH 9 for 24 hours. This solution was subsequently brought to pH 6 by addition of

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hydrochloric acid, filtered (0.45 µm nylon) and diluted to 150 mg C L-1. Hydrogen and a Pd-

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catalyst (Pd 0.5% wt. on Al2O3, Aldrich, Germany) was used for wet chemically reduction of

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the HA solution. 27 Hydrogen consumption was experimentally measured (SI, Figure S1) to

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calculate an electron accepting capacity upon H2/Pd reduction. Equilibration of the reduction

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was reached within 48 hours, as obtained from headspace H2 concentrations over time.

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Setup of batch reactions

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All reagents in this study were deoxygenated by N2-purging and stored in a glove box (O2 < 1

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ppm, N2 atmosphere, InertLab, Innovative Technology, Amesbury, USA). All sample

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handling was performed in the glove box or in stoppered flasks (1 cm butyl stoppers,

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Glasgerätebau Ochs, Bovenden, Germany) to ensure anoxic conditions. All experiments were

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performed in brown serum bottles and in the dark, at 25 ± 1 0C. Triplicates of reduced/ non-

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reduced HA solutions of 25, 50 and 75 mg C L-1 were set up at pH 6 ± 0.05. Subsequently, a

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total sulfide concentration of 250 ± 1 µmol L-1 was spiked (speciation at pH 6: 91.25 % H2S,

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8.75% HS-, hereafter referred to as ‘sulfide’). To avoid sulfide partitioning, the headspace of

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the serum bottles was kept < 0.5 ml. We are aware that these conditions may not be

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representative of typical freshwater environments (~10 µmol L-1) ,7 nevertheless are not

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unrealistic for in-situ conditions and necessary to analyze the S fractions with reasonable

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effort. Constant pH was maintained using a bicarbonate buffer. Solutions were stirred at

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constant rate, three aliquots of 400 µl, 300 µl and 1ml were collected on various time points

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within 48 hours for determination of S2-, S2O32-, and S0, respectively.

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A parallel batch for analysis of Sorg formation was prepared to yield higher amounts of

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material for XANES analysis. Solutions of 150 mg C L-1 reduced/non-reduced HA were 5 ACS Paragon Plus Environment

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employed and the initial sulfide concentration was adjusted to the same molar S/C ratio as in

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the 25 mg C L-1 treatment. After 48 hours, the solutions were purged with N2 for 45 min to

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remove unreacted sulfide, a 25 ml aliquot was collected and extracted for 30 min with

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cyclohexane (2.5:1/v:v) to remove S0 which could influence detection of near-zerovalent Sorg.

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The underlying water phase was transferred into air-tight flasks, shock frozen with dry ice,

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freeze dried, and stored in the glove box until analysis.

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Analytical procedures

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Dissolved organic carbon (DOC) concentrations were measured using a Shimadzu TOC V-

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CPN analyzer. The consumption of H2 during reduction of non-reduced HA was measured

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from headspace H2 concentrations in the serum bottles, using a H2 trace analyzer TA 3000

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(Trace Analytical, AMETEC, Newark, USA).

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Inorganic S analysis: Sulfide was measured colorimetrically (methylene blue) at 665 nm on a

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Varian Cary 1E spectrophotometer. 28 Elemental S and S2O32- were determined by high-

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performance liquid chromatography (HPLC) (Beckman HPLC-system, C18-column, 0.8 ml

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min-1 flow rate, UV detection at 215 nm for S2O32-; PerkinElmer HPLC-system, C18-column,

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0.4 ml min-1 flow rate, UV detection at 265 nm for S0). Matrix effects and reproducibility

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were tested using an aqueous solution of either S0 or S2O32--spiked humic acid and a

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laboratory standard. To prevent interference during analysis of S2O32-, 50 µl of 0.1 mM Zn2+

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was spiked into all samples prior to analysis to precipitate remaining sulfide.

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Organic S analysis: Organic S speciation was analyzed at the Synchrotron Radiation Source

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ANKA, SUL-X beamline (wiggler as a source, Si(111) monocromator crystal pair, collimated

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beam), as powdered solid samples prepared as thin layers on Kapton tape. To adjust S

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contents to 1.3~2 % to avoid self-absorption, samples were diluted with cellulose (Sigmacell

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Type 20, 20 µm) if necessary.29 The beam was calibrated to the sulfate excitation energy of

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Na2SO4 at 2481.4 eV for S K-edge XANES spectroscopy. Due to the low X-ray energy of the

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S K-edge, spectra were collected under vacuum. The S Kα X-ray fluorescence emission was 6 ACS Paragon Plus Environment

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recorded with a seven element Si(Li) solid-state detector (SGX Sensortech, former Gresham).

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To prevent S species from beam damage, spectra were collected in a quick scan mode with

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sampling step widths of 1 eV from 2432 to 2461 eV and 2502 to 2756 eV, and 0.2 eV across

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the S K edge from 2461 to 2501 eV. Up to 4 scans of different sample spots were

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accumulated for each sample spectrum. Spectra were background corrected by fitting the S K

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pre-edge region with a linear and the post-edge with a polynomial function, and normalized to

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an edge jump of 1.22,29–31 Measured references are given in Table 1, spectral data is provided

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in the SI, Figure S2.

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Calculations and budgets

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Mass balances were calculated from measured concentrations of total sulfide addition,

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remaining sulfide in solution, and formation of S0 and S2O32-, as no other inorganic oxidation

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products were detected. Organic sulfur could thus be calculated from a mass balance. XANES

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spectroscopy was not used to quantify Sorg, but only to identify Sorg speciation. For conversion

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of sulfur species transformations into electron budgets and stoichiometries, see Table 2.

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RESULTS

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Transformation of sulfide by non-reduced/reduced humic acid

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As would be expected from electron accepting capacities, the amount of sulfide transformed

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by non-reduced humic acid (NR-HA) exceeded that of H2/Pd pre-reduced humic acid (RHA).

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Sulfide transformation also increased with increasing HA concentrations from 25, 50 to 75

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mg C L-1, both for NR-HA and for RHA (Figure 1). The highest transformation of the initial

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sulfide (250 ± 1µmol L-1) was thus observed for 75 mg C L-1 NR-HA (97.5 µmol L-1, 39 %),

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while 50 and 25 mg C L-1 transformed 30.1 % and 19.8 % of the initial sulfide (Figure 1).

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Starting from a native S/C ratio of the employed HA of 0.0042, the calculated S/C ratio for

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the transformation of sulfide was 0.022 for 25 mg C L-1 and 0.015 for 75 mg C L-1 and thus

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higher for lower carbon concentrations.

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Since Aldrich HA contains significant amounts of iron (1.33%, SI, Table S1), we calculated

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the amount of the sulfide transformation which may be explained by reaction with iron

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(assuming all iron being present as Fe(III)). However, the calculated amount accounted for

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only a maximum of 6 to 9 % for transformed sulfide.

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Regarding the time course of the reaction, concentrations of sulfide sharply decreased during

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the first 12 hours, while thereafter the reaction slowed until 48 hours of incubation (Figure 1).

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A sample collected immediately after addition of sulfide, already 8.7 (25 mg C L-1) to 35.5

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µmol L-1 (75 mg C L-1) of sulfide had been transformed (SI, Figure S6, S7). This

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instantaneous transformation would again only partly be explained by native HA iron contents

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(25 to 34%). There was also a transformation of sulfide by RHA, i.e. by HA pre-reduced by

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H2/Pd ( Figure 1A). Here, 9.0, 18.0, and 22.4 % of the initial sulfide concentration were

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transformed in the 25, 50, and 75 mg C L-1 batches, respectively, equivalent to S/C ratios of

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0.0036, 0.0072 and 0.0090. A sample collected immediately after the addition of sulfide to

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RHA, also 4 to 31.8 µmol L-1 of sulfide had already been transformed, although no Fe(III)

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would be expected here. A test of 72 hours of incubation of NR-HA and RHA yielded no

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further detectable transformation (data not shown). Thus, all following calculations were

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based on the changes observed after 48 hours.

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Inorganic products of sulfide transformation

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In NR-HA samples, the formation of S0 followed sulfide consumption. Within the first 10

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hours, S0 increased to 6.6~35.0 µmol L-1, thereafter the formation of S0 was significantly

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slower (Figure1). After 48 h, S0 levelled off at 20.0 to 53.6 µmol L-1 (Table 3), with

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increasing amounts of S0 formed at higher concentrations of C. Native iron in HA contributed

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at most 15 to 17% to S0 formation.

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Thiosulfate exhibited a different behavior (Figure 1B/C/D). In the first 5 hours, S2O32-

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concentrations increased sharply, reaching temporary maxima (7.5~10.7 µmol L-1), but

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declining again thereafter. After 48 hours, only 3.8, 4.7 and 3.0 µmol L-1 of S2O32- were left in

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the solutions of 25, 50, and 75 mg C L-1, respectively, (2.4 to 3.8 % of initial sulfide).

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Sulfite and polysulfides were analyzed as well (not shown), neither of which were detected. It

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probably due to polysulfides significantly form at pH > 7.32 Based on the S mass balance after

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48h, S0 was the major terminal product, accounting for 40~55 % of the transformed sulfide,

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compared to 15.4~6.1 % recovered as S2O32-.

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While no inorganic transformation products were identified in the RHA batches, it indicated

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reacted sulfide had added to organic matter to form Sorg.

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Formation of organic S and characterization by S-K edge XANES Spectroscopy

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As the inorganic fraction of S accounted for 56~61% of reacted sulfide, 39~44% (21.9~37.9

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µmol L-1) had thus added to NR-HA as Sorg, yielding an S/C ratio of 0.011 to 0.006. For RHA,

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Sorg formation was 22.5~56.0 µmol L-1, equivalent to S/C ratios of 0.011~0.009, and therefore

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similar as for the NR-HA.

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Investigating the species of Sorg in NR-HA and RHA using S K-edge XANES spectroscopy

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on samples before and after reaction yielded two distinct peak ranges, representing two

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groups of S oxidation states (Figure 2 and Table 1). The range from 2471 to 2474 eV

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represents reduced S species, such as inorganic sulfides, elemental S, and around zerovalent

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organic S, such as thiols and S bridging structures involving one or more S atoms (e.g. R-SH

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or R-S-R, R-S-S-R). The peak range from 2475 to 2483 eV is indicative of oxidized organic

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and inorganic S species, e.g. organic sulfoxides, sulfones, sulfonates, and sulfate esters and

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inorganic sulfate S.22 Despite a native S content of 0.45 % as a background and due to

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removal of inorganic S species prior to analysis, S K-edge XANES before and after reaction

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with sulfide differed clearly, enabling us to track the fate of 0.11~0.06 % of newly formed Sorg

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in NR-HA and RHA. We used 5,5’-Dithiobis(2-nitrobenzoic acid) (representing organic

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disulfides, R-SS-R, ~2471.6 eV) and L-cysteine (representing thiols, R-SH, ~2472.6 eV) with

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nominal electronic oxidation states of S between 0 and 1 (Figure 2),23,26,29 as references to 9 ACS Paragon Plus Environment

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reproduce predominant changes of speciation of Sorg before and after reaction. In the NR-HA

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samples, peak intensities at ~2471.6 eV increased after reaction, shifting the predominant

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signal of reduced Sorg from 2473.1 eV to 2471.6 eV.

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We also detected changes in peaks representing oxidized Sorg species in NR-HA, as a minor

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peak at 2475.1 eV (possibly sulfoxide)33 diminished, a new peak at 2478.2 eV occurred, and

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the peak at ~2481 eV obviously separated into two distinct peaks at 2480.1 and 2481.2 eV.

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Either the oxidized Sorg initially present in HA would be partially reduced by sulfide, or

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oxidized Sorg may have formed (e.g. sulfonates). However, as these changes could not be

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quantified exactly from XANES spectra we did not consider them any further in the electron

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budgets.

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RHA samples also exhibited most prominent increases of peaks at 2471.6 and 2472.6 eV

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(organic disulfides and thiols, respectively) after reaction with sulfide. The peak maximum of

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RHA at 2473.1 eV did not shift, but broadened towards lower energies, indicating a relative

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increase of species peaking around 2471.6 (organic disulfides). A notable increase of the peak

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at 2478.1 and 2480.1 eV (possibly sulfones and sulfonate, Table 1) occurred, while peaks at

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2475.1 and 2481.1 eV exhibited a relative decrease. A peak at ~2469 eV after reaction may be

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due to monosulfide that had not been completely extracted.

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Transferred electron balance

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To calculate electron budgets, all S transformation products were recalculated into electron

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equivalents (Table 2 B/C). Since XANES data supported Sorg to be approximate zerovalent S

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(0~1 as nominal electronic oxidation state)23,26,29 and the exact proportions of the individual

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organic species cannot be determined exactly, it was conservatively assigned an oxidation

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state of zero for formed Sorg.

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For the budget after 48 hours, we calculated a total electron accepting capacity (EAC) from

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total sulfide consumption (TSC), EACs (TSC), of 114.2~207.0 µmol e- L-1 (4.57~2.76 µmol

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e- (mg C) -1) for the 25~75 mg C L-1 solutions (Table 2, Table 3,SI, Table S3, Figure S3). 10 ACS Paragon Plus Environment

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Thereby, of inorganic sulfur oxidation product formation (ISF), S2O32- accounted for

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30.4~24.0 µmol e- L-1 (1.22~0.32 µmol e- (mg C) -1), and S0 for 40.0~107.2 µmol e- L-1

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(1.6~1.4 µmol e- (mg C) -1). This yielded an EACS(ISF) of 70.4 to 131.2 µmol e- L-1

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(1.82~1.75 µmol e- (mg C) -1). Sorg added another 43.8~75.8 µmol e- L-1 (1.75~1.01 µmol e-

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(mg C) -1. Measured EACH2 for Aldrich humic acid was only 2.48 ± 0.13 µmol e- (mg C) -1, i.e.

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62, 124, and186 µmol e- L-1 in 25, 50, and 75 mg C L-1, respectively (SI, Table S3).

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After 5 hours of reaction, S2O32- concentrations peaked at 7.5, 9.3, 10.7 µmol L-1 (25, 50, and

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74 mg C L-1, respectively). Thus, 60~85 µmol e- L-1, or 2.40~1.13 µmol e- (mg C) -1 of EAC

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was intermittently recovered as S2O32-, exceeding contributions after 48 hours by far.

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Electron accepting capacities from Sorg formation of H2/Pd pre-reduced HA (RHA), i.e. after

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retrieval of EACH2, amounted to 45~112 µmol e- L-1 (1.8~1.5 µmol e- (mg C)-1) for 25~75

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mg C L-1. In NR-HA solution, EACH2 and EACs(TSC) differed by 52.2~21.0 µmol e- L-1

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(2.09~0.28 µmol e- (mg C) -1) for 25~75 mg C L-1, i.e. EACH2 was notably smaller than

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EACs(TSC) (Table 3, SI, Table S3, Figure S3).

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Reaction rates of sulfide transformation by humic acid

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As suggested earlier,18 a two pool model was applied for sulfide transformation kinetics. (SI,

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Eqs. S1, S2 and Table S2). In NR-HA batches, 13.3~19.6 % of the added sulfide (49.5~97.5

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µmol L-1) were transformed by a fast pool at rates of 0.2271~0.3249 h-1; 9.3~11.1% of the

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initial total sulfide (23.3~27.8 µmol L-1) were transformed by a slow pool at rates of

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0.0117~0.0285 h-1. Remaining sulfide was 69.6~77.5% (174.0~193.7 µmol L-1) in solution

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after 48 h. Formation rates of S0 and Sorg see SI, Table S2.

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Fitting resulted in a one pool model only for RHA (SI, Eq. S3 and Table S2). Obtained rates

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were 0.0976~0.1128 h-1 and thus comparable to the slow pool of NR-HA.

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DISCUSSION

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DOM-driven recycling of S

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While little is known about abiotic oxidation of sulfide by DOM, 3,18 a number of studies

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elucidated abiotic oxidation pathways for sulfide by inorganic electron acceptors, e.g.

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oxidation by oxygen, iron, or manganese, across various environments, e.g. aquatic systems

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and sediments under lab and field conditions.10,34,35 In most studies, the observed abiotic

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oxidation pathway of sulfide involved the formation of S0, and possibly of polysulfides.

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10,11,24,34

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under slightly acidic conditions.34 Existing studies of sulfide reacting with DOM reported a

275

formation of S2O32-, but a predominant formation of Sorg (~95 %). 3,18 Contrarily, in our study,

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S0 was the main oxidative product also for the oxidation of sulfide by DOM and Sorg made up

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only 39~44 %. Thiosulfate was an intermediate during this oxidation, peaking after 5 h, but

278

decreasing in its contribution thereafter. This difference may be due to the employment of

279

another DOM material (PP-HA) in the previous studies,18 as it is well recognized that

280

commercially available humic acids span a wide range in characteristics.36,37 Nevertheless, a

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considerably larger fraction of S could be oxidized to inorganic products than previously

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reported. A formation of mainly S0 also compares well to abiotic oxidation of sulfide with

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ferric iron and iron oxides,38,39 while formation of S2O32- or SO42- would typically involve

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further biotic transformation.10,35,40 The elevated native iron content of Aldrich HA (SI, Table

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S1) could potentially explain the formation of S0 as oxidation product. 10,35 However, iron

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contents of Aldrich HA would only yield 6~9 % of the total sulfide transformation and 15~17 %

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of the S0 formation in the NR-HA solutions.

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An instantaneous formation of S2O32-, as observed earlier 18 and in current study at the

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beginning of the reaction, hints at a catalytic action of non-reduced DOM to form S2O32- from

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sulfide oxidation. We found some experimental support that the formation of high amounts of

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S2O32- may be triggered by traces of residual oxygen (SI, Figure S6, S7), which could be

292

successfully excluded in this approach. Nevertheless, S2O32- must have been further

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transformed. A disproportionation of S2O32- into sulfide and sulfate was suggested to require

Direct oxidation of sulfide by oxygen in water yields S0 as the first oxidative product

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microbial catalysis, 40 but S2O32- may also have reacted abiotically with organic matter (see

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below).41 We also did not detect polysulfides, presumably as they are stable only at pH > 7, 32

296

although they could be expected in the presence of sulfide and S0 and would be precursors to

297

form organic polysulfides. 42,43

298

RHA also exhibited a transformation of sulfide, but could not detect inorganic transformation

299

products. A detection of S2O32- is, however, constrained by a limit of detection of 0.5 µmol L-

300

1

301

transformation product of sulfide within 48 h was thus Sorg.

302

Formation of organic S

303

Sulfur incorporation into natural organic matter has so far mostly been considered in marine

304

diagenetic studies, involving a formation of organic polysulfide or sulfide linkages.6,43–45 The

305

‘Michael addition’ was suggested as a reaction pathway, yielding sulfhydryl groups in the

306

carbonyl β-position of unsaturated carbon double bonds 20 or of quinones.17 These may

307

subsequently react to thioethers or organic polysulfides by inter- or intramolecular reaction

308

with a second electrophile.17,22,43 However, these studies provide little information of the time

309

scales organic sulfur formation and the respective implications for S recycling under anoxic

310

conditions. A rapid and irreversible addition of sulfide into the DOM structure would provide

311

a long term sink for S, while inorganic S species could sustain a biogeochemical recycling of

312

sulfur in anoxic systems.3,18

313

As proposed in recent studies,22,23,25,26,29,30 XANES spectroscopy was employed to evaluate

314

the oxidation states of S in organic matter and thus the fate of sulfide upon reaction with

315

DOM. In this study, we found an increase in peak intensity in the XANES spectra at

316

2471~2473 eV for both NR-HA and RHA, supporting formation of sulfhydryl groups (R-SH)

317

thioethers or organic polysulfides (R-Sx-R) upon reaction with sulfide, as suggested.20,42

in our analytical approach. Due to mass balance considerations, in case of RHA, the major

13 ACS Paragon Plus Environment

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318

Besides a formation of reduced Sorg species, spectral changes at 2475.1 eV, 2478.1 eV, and

319

the splitting of the peak at 2480~2481 eV also indicated changes in oxidized Sorg species. A

320

decrease of sulfoxide S (R-SO-R) may be due to reduction to thiols,27 and an increase of

321

sulfones could results from reduction of sulfonate S (R-SO3-R).22 A transformation of sulfate

322

esters to sulfonate S or sulfone S (R-SO2-R) was suggested as biotic transformation, 46 but an

323

abiotic formation of sulfonates was reported for a reaction of thiosulfate with organic

324

matter.41 This may have increased the relative contribution of sulfonates and thus led to the

325

splitting at 2480~2481 eV, and would provide an explanation for the transformation of

326

thiosulfate.

327

Changes of RHA in the peak intensities at 2471.6 and 2480.1eV were most pronounced.

328

Assuming quinones to be hydrogenated after H2/Pd pre-reduction at pH 6, organic S

329

formation with RHA should not involve addition to quinones.17,27 Here, addition of S to non-

330

quinone moieties must have occurred. As Sorg formation per carbon was similar for NR-HA

331

(S/C 0.011 to 0.006) and RHA (S/C 0.011~0.009), this supports that the formation of Sorg by

332

addition of S to oxidized quinone moieties is rather small. S addition may thus occur at

333

unsaturated C-C bonds 20 that are only little affected by the H2/Pd pretreatment, by formation

334

of organic polysulfides in presence of S0, or by sulfurization of carbohydrates.21 Moreover,

335

the relative increase at 2480.1 eV for both NR-HA and RHA suggests that a formation of

336

sulfonates through reaction of S2O32- with DOM is likely.41

337

Quantification of oxidized Sorg species from XANES spectra is difficult. Such species would

338

result from further reaction with thiosulfate and elemental sulfur and tracers would be needed

339

to understand pathways of formation. Thus we could not consider the oxidized Sorg fraction

340

separately in the electron budget, instead kept the assumption that Sorg is zerovalent.

341

Nevertheless, newly formed oxidized Sorg species would mean additional EAC of DOM from

342

sulfide reaction, but eventually reduce the amount of oxidized Sorg that may be available for

343

biotic reduction.46 14 ACS Paragon Plus Environment

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344

Electron accepting capacities of DOM from sulfide reaction

345

The EAC of NR-HA from H2/Pd reduction (EACH2) of 2.48 µmol e- (mg C)-1 was

346

comparable to electrochemically determined EACs reported for DOM in other studies: 1.7 to

347

2.5 µmol e- (mg C)-1 for Adrich HA 13,47 and 0.6 to 2.9 µmol e- (mg C)-1 for PP-HA,3,13

348

determined at pH 6 and 7 13, but much higher compared to results of 0.29~0.39 µmol e- (mg

349

C)-1 from wet chemical determination.27 From all inorganic transformation products we also

350

obtained an EACs(ISF) in a similar range (2.88~1.75 µmol e- (mg C)-1). In contrast, the

351

earlier study with a predominant formation of S2O32- obtained lower EACs of 0.1~0.6 µmol e-

352

(mg C)-1 for Pahokee-Peat HA at pH 6.18

353

To close the budget, we included the formation of Sorg. The nominal oxidation state of

354

reduced Sorg was reported to be between 0~1.30 We thus regarded all newly formed Sorg to be

355

zerovalent, providing a minimum estimate of EACs of DOM from sulfide reaction;

356

transformation of oxidized S would even increase EACs.22 In comparison to EACH2,

357

EACs(TSC) of NR-HA from sulfide reaction was considerably larger, mainly due to

358

formation of Sorg, although neglecting formation of oxidized species of Sorg.41 Also H2/Pd pre-

359

reduced HA still transformed significant amounts of sulfide into Sorg, reaching 60~80 % of

360

EACH2 determined by H2/Pd reduction of DOM and thus questioning the significance of EAC

361

determined by H2/Pd in sulfidic systems. The reduction of HA by H2/Pd obviously did not

362

affect all sites that may potentially transfer electrons to sulfide. It is in a way surprising,

363

though, given the fact that hydrogen is a stronger reductant.47

364

To estimate their contribution to the EAC, we estimated the content of quinones of Aldrich

365

HA in our solutions, using data from Ratasuk & Nanny (0.32 µmol e- (mg C)-1,27 i.e. 4~12

366

µmol e- L-1) and from Aeschbacher et al. (1.70 µmol e- (mg C)-1,13 assuming all reversible

367

sites to be quinones, i.e. 21~65 µmol e- L-1). These numbers could either explain the amount

368

of inorganic oxidation products formed (70.4~131.2 µmol e- L-1) or also the amount of Sorg 15 ACS Paragon Plus Environment

Environmental Science & Technology

369

formation, if happening via Michaels addition to quinones 17 (21.9~56.0 µmol Sorg L-1), but

370

not both. As Sorg formation via Michael addition to quinones seems to be negligible, one may

371

hypothesize that the contribution of quinones is mainly as EAC for inorganic sulfide oxidation

372

product formation. The amount of S to be incorporated may on the other hand be limited by

373

the number of unsaturated C-C bonds reactive towards sulfide. 19

374

Kinetics of sulfide transformation by DOM.

375

Modeled rate constants for the fast pool compared well to the same pool in the study of

376

Heitmann and Blodau 18 (0.206 h-1). The slow pool rate constant in the latter study (0.176 h-1),

377

ascribed to Sorg formation, also compared well to Sorg formation rates for NR-HA in our study.

378

The one pool model for Sorg formation with RHA yielded again comparable rate constants

379

based on sulfide transformation (0.103 h-1). As already reported,18 these numbers support that

380

the oxidation rates of sulfide upon reaction with DOM, both for S0 and organic S formation,

381

are competitive to sulfide oxidation on poorly crystalline iron oxides 10,35 and faster than

382

sulfide oxidation by more crystalline iron oxides 35 or by molecular oxygen.48

383

The native iron content of Aldrich HA did not explain the fast initial rates of sulfide

384

transformation after injection of sulfide into the HA solution, as iron contents would only

385

explain 21~34 % of this initial transformation (SI, Figure S8, S9). This indicates that the

386

contribution of the native iron content to sulfide oxidation cannot be separated, neither based

387

on the obtained transformation product S0 (see above), nor based on the kinetics. We therefore

388

conclude that the reactivity of iron in DOM is probably to a large extent controlled by DOM

389

properties. Natural DOM samples may contain significant amounts of iron held in strong

390

complexes that can also prevent iron from hydrolysis.49,50 A separate investigation of purified

391

humic substances and pure iron phases or complexes may thus not be appropriate.

392

Implications for S cycling in anoxic environments

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393

To relate our results to known biogeochemical processes and rates, we sought to compare the

394

amount of transferred electrons to in situ data from earlier studies.3,15 We chose data from an

395

ombrotrophic bog, using an average peat carbon content of 40% and a peat bulk density of 0.1

396

g cm-3at 60 cm depth.51 Assuming an EAC of particulate organic matter of 5% of dissolved

397

HA 15,16 and using an EAC of HA of 2.2 µmol e- (mg C)-1 from 50 mg C L-1 solutions. The

398

obtained value of EAC from sulfide reaction of bulk peat could reach 4.51 mmol e- L-1,

399

coinciding with EAC calculated by Roden et al. (7.67 mmol e- L-1)15, but lower than the

400

numbers obtained by Lau et al. (61.1 mmol e- L-1).52 Assuming this capacity to be available in

401

48 h, this yields electron transfer rates of 2.3 µmol e- cm-3 day-1. Keeping in mind that many

402

sulfate reducing bacteria can also reduce the observed intermediates S0 and S2O32-,40 such

403

capacities may help to explain high sulfate reduction rates summarized by Pester et al.,4

404

although such numbers for bulk peat EAC provide only first estimates.

405

Abiotic oxidation of sulfide by DOM could thus explain sulfide re-cycling under anaerobic

406

conditions within timescales of hours, regenerating more oxidized inorganic or organic forms

407

of S. However, this mechanism would be limited due to a finite capacity of DOM, if DOM is

408

not cycled back to an oxidized state. Such replenishment of capacities may e.g. be induced by

409

water table fluctuations or by inflow of non-reduced DOM.3,16 Biotic and abiotic redox

410

transformations of S are known for different species. On the long term, Sorg may provide a

411

sink for S and ongoing abiotic sulfide re-cycling via S0 and S2O32- would depend on external

412

sources of sulfate (e.g., atmospheric deposition ).1,18 EAC of DOM from sulfide reaction was

413

nevertheless higher than previous results from electrochemical determination, mainly due to

414

the large contributions of Sorg. As HA from soil/peat environments also interact with iron, and

415

as the contributions of iron could not be separated from bulk EAC of the HA, future work

416

should involve studying the ternary system of Fe, S and DOM.

417

ACKNOWLEDGMENT

17 ACS Paragon Plus Environment

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418

We thank student assistants Daniela Braun and Sarah Hofmann for lab work support, and

419

Jutta Eckert, Silke Hammer, Heidi Zier and Martina Rohr for technical support. Energy-

420

dispersive X-ray fluorescence spectrometry of the humic acid was performed by Dr. Andreas

421

Voegelin. The study was funded by the German Research Foundation, research group

422

‘electron transfer processes in anoxic aquifers’ (FOR 580, KN 929/2-1). We acknowledge the

423

Synchrotron Light Source ANKA for providing us with the instrumentation at their beamlines

424

and we thank Dr. Ralph Steininger for assistance in using beamline SUL-X within proposal

425

ENV-236. Finally, we thank the anonymous reviewers for their constructive comments.

426 427

SUPPORTING INFORMATION AVAILABLE

428

Additional information as noted in the text. This material is available free of charge via the

429

Internet at http://pubs.acs.org.

430

AUTHOR INFORMATION

431

*Corresponding author

432

E-mail: [email protected] Phone: +49-251-8330207

433

Notes

434

The authors declare no competing financial interest.

435 436

REFERENCES

437 438

(1)

Wieder, R. K.; Lang, G. E. Cycling of inorganic and organic sulfur in peat from Big Run Bog, West Virginia. Biogeochemistry 1988, 5, 221–242.

439 440

(2)

Wieder, R. K.; Yavitt, J.; Lang, G. Methane production and sulfate reduction in two Appalachian peatlands. Biogeochemistry 1990, 10, 81–104.

441 442 443

(3)

Heitmann, T.; Goldhammer, T.; Beer, J.; Blodau, C. Electron transfer of dissolved organic matter and its potential significance for anaerobic respiration in a northern bog. Glob. Chang. Biol. 2007, 13, 1771–1785.

18 ACS Paragon Plus Environment

Page 18 of 27

Page 19 of 27

Environmental Science & Technology

444 445 446

(4)

Pester, M.; Knorr, K.-H.; Friedrich, M. W.; Wagner, M.; Loy, A. Sulfate-reducing microorganisms in wetlands - fameless actors in carbon cycling and climate change. Front. Microbiol. 2012, 3, 72.

447 448 449

(5)

Lovley, D. R.; Phillips, E. J. P. Novel processes for anaerobic sulfate production from elemental sulfur by novel processes for anaerobic sulfate production from elemental sulfur by sulfate-reducing bacteria. Appl. Environ. Microbiol. 1994, 60, 2394–2399.

450 451

(6)

Ferdelman, T. G.; Church, T. M.; Luther III, G. W. Sulfur enrichment of humic substances in a Delaware salt marsh sediment core. Geochim. Cosmochim. Acta 1991, 55, 979–988.

452 453

(7)

Blodau, C.; Mayer, B.; Peiffer, S.; Moore, T. R. Support for an anaerobic sulfur cycle in two Canadian peatland soils. J. Geophys. Res. 2007, 112, 1–10.

454 455 456

(8)

Canfield, D. E.; Boudreau, B. P.; Mucci, A.; Gundersen, J. K. The early diagenetic formation of organic sulfur in the sediments of mangrove lake, bermuda. Geochim. Cosmochim. Acta 1998, 62, 767–781.

457 458 459

(9)

Novák, M.; Vile, M. A.; Bottrell, S. H.; Štěpánová, M.; Jačková, I.; Buzek, F.; Přechová, E.; Newton, R. J. Isotope systematics of sulfate-oxygen and sulfate-sulfur in six European peatlands. Biogeochemistry 2005, 76, 187–213.

460 461

(10)

Peiffer, S.; dos Santos Afonso, M.; Wehrli, B.; Gaechter, R. Kinetics and mechanism of the reaction of hydrogen sulfide with lepidocrocite. Environ. Sci. Technol. 1992, 26, 2408–2413.

462 463 464

(11)

Hellige, K.; Pollok, K.; Larese-Casanova, P.; Behrends, T.; Peiffer, S. Pathways of ferrous iron mineral formation upon sulfidation of lepidocrocite surfaces. Geochim. Cosmochim. Acta 2012, 81, 69–81.

465 466

(12)

Lovley, D. R.; Coates, J. D.; Blunt-Harris, E. L.; Phillips, E. J. P.; Woodward, J. C. Humic substances as electron acceptors for microbial respiration. Nature 1996, 382, 445–448.

467 468

(13)

Aeschbacher, M.; Sander, M.; Schwarzenbach, R. P. Novel electrochemical approach to assess the redox properties of humic substances. Environ. Sci. Technol. 2010, 44, 87–93.

469 470

(14)

Uchimiya, M.; Stone, A. T. Reversible redox chemistry of quinones: impact on biogeochemical cycles. Chemosphere 2009, 77, 451–458.

471 472 473

(15)

Roden, E. E.; Kappler, A.; Bauer, I.; Jiang, J.; Paul, A.; Stoesser, R.; Konishi, H.; Xu, H. Extracellular electron transfer through microbial reduction of solid-phase humic substances. Nat. Geosci. 2010, 3, 417–421.

474 475

(16)

Klüpfel, L.; Piepenbrock, A.; Kappler, A.; Sander, M. Humic substances as fully regenerable electron acceptors in recurrently anoxic environments. Nat. Geosci. 2014, 7, 195–200.

476 477

(17)

Perlinger, J. A.; Kalluri, V. M.; Venkatapathy, R.; Angst, W. Addition of hydrogen sulfide to juglone. Environ. Sci. Technol. 2002, 36, 2663–2669.

478 479

(18)

Heitmann, T.; Blodau, C. Oxidation and incorporation of hydrogen sulfide by dissolved organic matter. Chem. Geol. 2006, 235, 12–20.

480 481 482

(19)

Adam, P.; Schneckenburger, P.; Schaeffer, P.; Albrecht, P. Clues to early diagenetic sulfurization processes from mild chemical cleavage of labile sulfur-rich geomacromolecules. Geochim. Cosmochim. Acta 2000, 64, 3485–3503. 19 ACS Paragon Plus Environment

Environmental Science & Technology

483 484

(20)

Vairavamurthy, A.; Mopper, K. Geochemical formation of organosulphur compounds (thiols) by addition of H2S to sedimentary organic matter. Nature 1987, 329, 623–625.

485 486 487

(21)

Van Dongen, B. E.; Schouten, S.; Baas, M.; Geenevasen, J. A. J.; Sinninghe Damstéa, J. S. An experimental study of the low-temperature sulfurization of carbohydrates. Org. Geochem. 2003, 34, 1129–1144.

488 489 490

(22)

Hoffmann, M.; Mikutta, C.; Kretzschmar, R. Bisulfide reaction with natural organic matter enhances arsenite sorption: insights from X-ray absorption spectroscopy. Environ. Sci. Technol. 2012, 46, 11788–11797.

491 492 493

(23)

Xia, K.; Weesner, F.; Bleam, W. F.; Helmke, P. A.; Bloom, P. R.; Skyllberg, U. L. XANES studies of oxidation states of sulfur in aquatic and soil humic substances. Soil Sci. Soc. Am. J. 1998, 62, 1240–1246.

494 495 496

(24)

Wan, M.; Shchukarev, A.; Lohmayer, R.; Planer-Friedrich, B.; Peiffer, S. Occurrence of surface polysulfides during the interaction between ferric (hydr)oxides and aqueous sulfide. Environ. Sci. Technol. 2014, 48, 5076–5084.

497 498 499

(25)

Einsiedl, F.; Mayer, B.; Schäfer, T. Evidence for incorporation of H2S in groundwater fulvic acids from stable isotope ratios and sulfur K-edge X-ray absorption near edge structure spectroscopy. Environ. Sci. Technol. 2008, 42, 2439–2444.

500 501 502

(26)

Prietzel, J.; Thieme, J.; Salomé, M.; Knicker, H. Sulfur K-edge XANES spectroscopy reveals differences in sulfur speciation of bulk soils, humic acid, fulvic acid, and particle size separates. Soil Biol. Biochem. 2007, 39, 877–890.

503 504

(27)

Ratasuk, N.; Nanny, M. A. Characterization and quantification of reversible redox sites in humic substances. Environ. Sci. Technol. 2007, 41, 7844–7850.

505 506

(28)

Cline, J. D. Spectrophotometric determination of hydrogen sulfide in natural waters. Limnol. Oceanogr. 1969, 14, 454–458.

507 508 509

(29)

Prietzel, J.; Botzaki, A.; Tyufekchieva, N.; Brettholle, M.; Thieme, J.; Klysubun, W. Sulfur speciation in soil by S K-Edge XANES spectroscopy: comparison of spectral deconvolution and linear combination fitting. Environ. Sci. Technol. 2011, 45, 2878–2886.

510 511

(30)

Manceau, A.; Nagy, K. L. Quantitative analysis of sulfur functional groups in natural organic matter by XANES spectroscopy. Geochim. Cosmochim. Acta 2012, 99, 206–223.

512 513

(31)

Ravel, B.; Newville, M. ATHENA, ARTEMIS, HEPHAESTUS: data analysis for X-ray absorption spectroscopy using IFEFFIT. J. Synchrotron Radiat. 2005, 12, 537–541.

514

(32)

Rickard, D.; Luther III, G. W. Chemistry of iron sulfides. Chem. Rev. 2007, 107, 514–562.

515 516

(33)

Urban, N. R.; Ernst, K.; Bernasconi, S. Addition of sulfur to organic matter during early diagenesis of lake sediments. Geochim. Cosmochim. Acta 1999, 63, 837–853.

517 518

(34)

Chen, K. Y.; Morris, J. C. Kinetics of oxidation of aqueous sulfide by oxygen. Environ. Sci. Technol. 1972, 6, 529–537.

519 520 521

(35)

Poulton, S. W.; Krom, M. D.; Raiswell, R. A revised scheme for the reactivity of iron (oxyhydr)oxide minerals towards dissolved sulfide. Geochim. Cosmochim. Acta 2004, 68, 3703–3715. 20 ACS Paragon Plus Environment

Page 20 of 27

Page 21 of 27

Environmental Science & Technology

522 523 524

(36)

Rodríguez, F. J.; Schlenger, P.; García-Valverde, M. A comprehensive structural evaluation of humic substances using several fluorescence techniques before and after ozonation. Part I: Structural characterization of humic substances. Sci. Total Environ. 2014, 476-477, 718–730.

525 526

(37)

Malcolm, R. L.; MacCarthy, P. Limitations in the use of commercial humic acids in water and soil research. Environ. Sci. Technol. 1986, 20, 904–911.

527 528

(38)

Evangelou, V. P.; Zhang, Y. L. A review: pyrite oxidation mechanisms and acid mine drainage prevention. Crit. Rev. Environ. Sci. Technol. 1995, 25, 141–199.

529 530

(39)

Moses, C. O.; Nordstrom, D. K.; Herman, J. S.; Mills, A. L. Aqueous pyrite oxidation by dissolved oxygen and by ferric iron. Geochim. Cosmochim. Acta 1987, 51, 1561–1571.

531 532

(40)

Jørgensen, B. B. The sulfur cycle of freshwater sediments: Role of thiosulfate. Limnol. Oceanogr. 1990, 35, 1329–1342.

533 534

(41)

Vairavamurthy, A.; Zhou, W.; Eglinton, T.; Manowitz, B. Sulfonates: a novel class of organic sulfur compounds in marine sediments. Geochim. Cosmochim. Acta 1994, 58, 4681–4687.

535 536

(42)

Francois, R. A study of sulfur enrichment in the humic fraction of marine-sediments during early diagenesis. Geochim. Cosmochim. Acta 1987, 51, 17–27.

537 538 539

(43)

Vairavamurthy, A.; Mopper, K.; Taylor, B. F. Occurrence of particle-bound polysulfides and significance of their reaction with organic matters in marine sediments. Geophys. Res. Lett. 1992, 19, 2043–2046.

540 541

(44)

Brown, K. A. Formation of organic sulphur in anaerobic peat. Soil Biol. Biochem. 1986, 18, 131–140.

542 543 544

(45)

Brüchert, V.; Pratt, L. M. Contemporaneous early diagenetic formation of organic and inorganic sulfur in estuarine sediments from St. Andrew Bay, Florida, USA. Geochim. Cosmochim. Acta 1996, 60, 2325–2332.

545 546

(46)

Kertesz, M. A. Riding the sulfur cycle-metabolism of sulfonates and sulfate esters in Gramnegative bacteria. FEMS Microbiol. Rev. 2000, 24, 135–175.

547 548

(47)

Jiang, J.; Kappler, A. Kinetics of microbial and chemical reduction of humic substances: implications for electron shuttling. Environ. Sci. Technol. 2008, 42, 3563–3569.

549 550 551

(48)

Zhang, J.-Z.; Millero, F. J. Environmental Geochemistry of Sulfide Oxidation; Alpers, C. N.; Blowes, D. W., Eds.; ACS Symposium Series; American Chemical Society: Washington, DC, 1993; Vol. 550, pp. 393–409.

552 553

(49)

Karlsson, T.; Persson, P. Complexes with aquatic organic matter suppress hydrolysis and precipitation of Fe(III). Chem. Geol. 2012, 322-323, 19–27.

554 555 556

(50)

Karlsson, T.; Persson, P.; Skyllberg, U.; Mörth, C.-M.; Giesler, R. Characterization of iron(III) in organic soils using extended X-ray absorption fine structure spectroscopy. Environ. Sci. Technol. 2008, 42, 5449–5454.

557 558

(51)

Blodau, C.; Moore, T. R. Macroporosity affects water movement and pore water sampling in peat soils. Soil Sci. 2002, 98–109.

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559 560

(52)

Lau, M. P.; Sander, M.; Gelbrecht, J.; Hupfer, M. Solid phases as important electron acceptors in freshwater organic sediments. Biogeochemistry 2014.

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250

A. RHA 50 mg C L-1

250 200 150 100 50 0

200 150 100 50 0 0

10

20

S0, S2O32-, Sorg (µmol S L-1)

Total sulfide

30

40

50 Sorg

Sulfide control -1

B. NR-HA 25 mg C L

45

250 200 150 100 50 0

30 15 0 -1

C. NR-HA 50 mg C L

80

250 200 150 100 50 0

60 40 20 0 90

D. NR-HA 75 mg C L-1

250 200 150 100 50 0

60 30 0 0

10

20 30 Time (h)

Total sulfide

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Total sulfide (µmol L-1)

Page 23 of 27

S0

S2O32-

40

50

Sulfide control Sorg

563

Figure 1. Transformation of sulfide over time upon reaction with Aldrich HA. A.RHA 50 mg

564

C L-1 DOC: transformation of total sulfide (left y-axis) into organic S (right y-axis) species by

565

50 mg C L-1 of H2/Pd reduced Aldrich HA (see SI, Figure S6 for 25, 75 mg C L-1 of RHA); B,

566

C and D represent sulfide (left y-axis) transformation of non-reduced Adrich HA solutions

567

(NR-HA, A: 25, B: 50, and C: 75 mg C L-1) into inorganic S species (S0, S2O32-) and organic

568

S (right axis). The abiotic incubations lasted for 48 hours at pH 6, 25° C, under anoxic

569

conditions. Values are means ± SD (n=3).

570 23 ACS Paragon Plus Environment

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A

R-S-S-R R-SH NR-HA (1) RHA (1)

B

R-S-S-R R-SH

Norm m(E)x

NR-HA (1) NR-HA (2)

C

R-S-S-R R-SH RHA (1) RHA (2)

2460

2470

2480

2490

2500

Energy (eV)

571 572

Figure 2. S-K-edge XANES spectra of non-reduced (NR-HA) and reduced Aldrich humic

573

acid (RHA) before and after reaction upon sulfide. RHA (1) and NR-HA (1) is prior to, RHA

574

(2) and NR-HA (2) after reaction with sulfide. The difference in the spectra only gives

575

information for relative changes of individual electronic oxidation states. Markers (vertical

576

dottet lines) are at 2469, 2471.6, 2472.6, 2473.7, 2475.2, 2478.1, 2480.2 and 2481.2 eV. See

577

Table 1 for corresponding references.

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Table 1. Measured sulfur model compounds with different electronic oxidation states (EOS) and predominant S-K edge XANES peaks as observed for non-reduced (NR-HA) and reduced humic acid (RHA) samples before and after reaction towards sulfide

Compounds; Molecular formula

Peak max.

Iron mono-sulfides: FeS Pyrite: FeS2 Elemental sulfur: S0 5,5’-Dithiobis (2-nitrobenzoic acid); ( [-SC6H3(NO2)CO2H]2) * L-cysteine: C6H12N2O4S2 ** Dibenzothiophene: C12H8S Methyl phenyl sulfoxide: CH3SOC6H5 Dimethyl sulfone: (CH3)2SO2 Sodium methanesulfonate: CH3SO3Na Sulfuric acid mono(2-aminoethyl) ester: C2H7NO4S Sodium sulfate: Na2SO4

EOS

Ref.

Peak max. (eV) Non-reduced HA Reduced HA

(eV) Before After -2 26 2470.2 -1 26 2471.1 0 26 2471.5 2471.6 +0∼1 23,27 2471.6 2473.7 2473.1 2473.1 2472.6 +0.2 26,27 2472.6 2472.9 +0∼1 23,27 2475.2 +2 23,26,27 2475.1 2479.1 +4 23,26,27 2478.2 2480.2 +5 23,26,27 (~2480) 2480.2 2481.5 +6 23,26,27 2481.3 2481.5 +6 23,26,27

Before

After

2473.1

2471.6 2473.1 2472.6

2475.1 (~2480)

2478.2 2480.2 2481.3

* Representing organic disulfides (R-SS-R bridging structures); two peaks were observed; one at 2471.6 eV had a higher relative intensity than the one at 2473.7 eV. ** Representing thiols (R-SH) Note: the value in set brackets may not only represent one peak.

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Table 2. Calculation of the S mass balance and electron accepting capacities (EAC) of NRHA and RHA A: Calculation of the Sulfur mass balance IS(-II)

Initial sulfide in solution

RS(-II)

Remaining sulfide in solution after 48-h reaction time

TSC= IS(-II) - RS(-II)

Total sulfide transformation

0

2-

ISF = ISF (S ) + ISF (S2O3 )

Inorganic sulfur product formation; identified inorganic oxidation Products S0 and S2O32-

Sorg = TSC - ISF

Organic sulfur formation

B: Electron accepting capacity (EAC) of NR-HA and RHA Total EAC of humic acid towards reaction with sulfide

EACS(TSC) = EAC(ISF) + EAC(Sorg) -

2-

EACS(ISF) = ISF(S0) · 2e + ISF(S2O3 ) · 8e -

EACS(Sorg) = Sorg · 2e

-

EAC from inorganic sulfur product formation EAC from organic sulfur formation (assuming Sorg to be zerovalent, see section “Formation of organic S and characterization by S-K edge XANES Spectroscopy”)

-

EACH2(HA) = UH2 (48 h) · 4e

EAC of NR-HA as obtained from H2 uptake (UH2) after 48 hours reduction with H2 and Pd catalyst

C: Stoichiometries and electron transfer for sulfide oxidation by HA 1) Formation of S2O32- and S0 Eq. 1 4 DOM-Q + 2 H2S + 3 H2O → 4 DOM-QH2 + S2O32- + 2 H+

Eq. 2 (2H2Sሱۛሮ S2O32-)

Eq. 3 DOM-Q + H2S → DOM-QH2 + S0

Eq. 4 (S2-ሱۛሮ S0)

ି଼௘

ିଶ௘

2) Formation of organic sulfur Eq. 5 DOM-Q + S2- → Sorg *

ିଶ௘

Eq. 7 (S2-ሱۛሮ Sorg) ***

Eq. 6 DOM + S2- → Sorg ** #

-Q and –Q-H2 denote oxidized and reduced quinone moieties (most important redox active functional group in

DOM ), respectively *As suggested by Perlinger et al. 17 for juglone and other oxidized quinones; **Addition of sulfur to non-quinone moieties of organic matter ***see section “Formation of organic S and characterization by S-K edge XANES Spectroscopy,” organic sulfur formed assumed to be zerovalent.

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Table 3. Sulfur and hydrogen mass balance and electron balance for reactions of non-reduced (NR-HA) and H2/Pd pre-reduced Aldrich humic acid (RHA) with sulfide. For terms and definitions, see methods section

Mass balance in µmol L-1

Factor(b) Electron balance in µmol e- L-1

batch NR-HA 25 mg C L-1 NR-HA 50 mg C L-1 NR-HA 75 mg C L-1 RHA 25 mg C L-1 RHA 50 mg C L-1 RHA 75 mg C L-1

H2(a) 15.5 ± 1.0

TSC 49.5 ± 3.5

ISF(S0) 20.0 ± 0.7

ISF(S2O32-) 3.8 ± 0.4

Sorg 21.9 ± 3.1

31.0 ± 1.2

76.0 ± 5.1

36.0 ± 2.7

4.7 ± 0.2

30.6 ± 2.1

46.5 ± 2.1

97.5 ± 6.9

53.6 ± 3.1

3.0 ± 0.7

37.9 ± 2.4

-

22.5 ± 1.1

-

-

22.5 ± 1.1

-

44.9 ± 3.4

-

-

49.9 ± 3.4

-

56

-

-

56

40.0 ± 1.3

8 30.4 ± 3.1

2 43.8 ± 5.8

72.0 ± 5.5

37.6 ± 1.2

61.2 ± 4.3

207.0 ± 11.2 107.2 ± 7.0

24.0 ± 5.2

75.8 ± 4.6

4 NR-HA 25 62.0 ± 3.1 C mg L-1 NR-HA 50 124.0 ± 5.2 C mg L-1 NR-HA 75 186.0 ± 8.7 C mg L-1 RHA 25 C mg L-1 RHA 50 C mg L-1 RHA 75 C mg L-1

± 6.2

(2-2.3)(d) 114.2 ± 6.3

2

170.8 ± 9.2

± 6.2

45.0 ± 1.9

-

-

45.0 ± 1.9

99.8 ± 6.5

-

-

99.8 ± 6.5

112 ± 8.3

-

-

112 ± 8.3

(a)

determined in a 150 mg L-1 stock solution and recalculated for 25, 50, and 75 mg C L-1

(b)

electron transfer per species formed/consumed

(c)

calculated from ISF(S0), ISF(S2O32-) and Sorg

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