Effective Removal of Selenite and Selenate Ions from Aqueous

selenite (Se(IV)) and selenate (Se(VI)) ions from aqueous solutions due to the ... aqueous solutions (-2, 0, +4, +6) and dissolved as oxyanions (selen...
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Effective removal of selenite and selenate ions from aqueous solution by barite Kohei Tokunaga, and Yoshio Takahashi Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b01219 • Publication Date (Web): 07 Jul 2017 Downloaded from http://pubs.acs.org on July 7, 2017

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Environmental Science & Technology

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Effective removal of selenite and selenate ions from aqueous solution by barite

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Kohei Tokunaga1, 2* and Yoshio Takahashi1*

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1

Department of Earth and Planetary Science, The University of Tokyo, Bunkyo-ku, Tokyo 113-0033, Japan

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2

Advanced Science Research Center, Japan Atomic Energy Agency, Tokai, Ibaraki 319-1195, Japan

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Correspondence: Email: [email protected], [email protected]

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Abstract

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In the present study, we explore a new application of barite (BaSO4) as a sequestering phase for

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selenite (Se(IV)) and selenate (Se(VI)) ions from aqueous solutions due to the low solubility and

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high stability of barite with its ability to selectively incorporate a large amount of various ions.

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uptake of Se(IV) and Se(VI) during coprecipitation with barite was investigated through batch

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experiments to understand the factors controlling effective removal of Se(IV) and Se(VI) from

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polluted water to barite.

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complexation between barite surface and Se(IV)/Se(VI) ion and (ii) structural similarity related to

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the structural geometry of incorporated ions into the substituted site.

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barite is dependent on pH, coexistent calcium ion, and sulfate concentration in the initial solution,

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possibly due to their effects on the chemical affinity and structural similarity.

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the uptake of Se(VI) by barite was strongly dependent on sulfate concentration in the initial solution,

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which is only related to the structural similarity.

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distribution between barite and water, thereby providing a good estimate of its ability to effectively

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remove Se(IV) and Se(VI) from aqueous solutions under optimized experimental parameters

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examined here.

The

The factors include (i) chemical affinity related to the degree of surface

The uptake of Se(IV) by

On the other hand,

This study describes the mechanisms for Se

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1. Introduction Selenium (Se) is generally a trace element in nature, but frequently occurs in the environment

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by anthropogenic activities such as mining and fossil fuels combustion.

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element but can also a toxic to organisms depending on its concentration and chemical form in water

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(e.g., drinking water limits of 0.05 mg/L and 0.01 mg/L in the United States and Japan,

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respectively).1 In addition, the element is an important radionuclide with a long half-life (Se79:

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about 105 years) found in radioactive wastes.2

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aqueous solutions (-2, 0, +4, +6) and dissolved as oxyanions (selenite: SeIVO32-; selenate: SeVIO42-)

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with high solubility and mobility in an aquatic environment.

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organic Se, and the toxicity of inorganic selenite is higher than inorganic selenate.

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transport of Se in contaminated sites are influenced by the chemical form and speciation of the

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element: hence, Se(IV) is strongly adsorbed by soil particles, whereas Se(VI) is weakly adsorbed and

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leaches easily.3

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It is known as an essential

In nature, Se exists in four oxidation states in

Inorganic Se is more toxic than The fate and

Several techniques can be used to reduce the Se level in solutions such as ion-exchange,

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bioremediation, adsorption, and coprecipitation.4-7

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for the selective separation of Se(IV) or Se(VI), an increasing concentration of competitive ions,

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such as sulfate, significantly reduces adsorption ability during for the ion-exchange separation.4,5

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Retention by adsorption on mineral surface is also unstable in the long run because changes in the

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surrounding environment could release the adsorbed ions back into the water.7

Although ion-exchange resins can be available

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Therefore, this

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study investigated the immobilization of a trace element in mineral during crystal growth, a process

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known as coprecipitation, to develop effective removal methods of Se(IV) and Se(VI) from a

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polluted solution.

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capable of preserving substituent ions in the crystal lattice for a long time, which makes it work as

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engineered barriers for the retention of various ions, including Se(IV) and Se(VI).

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The advantages of the method are simplicity, short treatment time, low cost, and

In the present study, we designed and optimized methods using barite (BaSO4) for this purpose

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and analyzed their efficiencies in incorporating Se(IV) and Se(VI).

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many geological environments and can be used to remove toxic and/or radioactive elements from

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polluted waters.

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solubility8 (ca. Ksp = 10-9.98 at 25 °C, 1 atm), (ii) incorporation of numerous elements because of the

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large ionic radii of substituted ions9, 10 (Ba2+: 1.68 Å; SO42-: 1.48 Å), (iii) high density compared with

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other minerals (4.5 g/cm3), which is an advantage for rapid sedimentation during coprecipitation

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process, and (iv) high crystal stability under wide ranges of pH, Eh, temperature, and pressure

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conditions.4,11-21

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radioactive elements from polluted solutions.

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Ra2+ in fresh or brine water because of its high stability and larger incorporation of Ra2+ relative to

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other minerals.12-15

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coprecipitation of trace elements with barite has not been conducted in previous studies.

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Barite is a common phase in

Barite as a sequestering phase shows following characteristics: (i) extremely low

Thus, barite serves as a sequestering phase for the removal of toxic and/or For example, barite acts as an ideal host mineral for

However, except for the Ra2+ uptake by barite, an experiment on the

Hence, this study examined and compared the coprecipitation capacities under controlled

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experimental conditions to optimize the effective removal of Se(IV) and Se(VI) by barite.

Even

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though the degree of immobilization depends on various factors, the most critical are the charge and

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the size of the ions relative to the substituted site.22 In the present study, the following two factors

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were mainly investigated: (i) the affinity of the surface complex between barite surface and

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Se(IV)/Se(VI) ion (= i.e., chemical affinity) and (ii) the affinity of the substituent ion in the

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substituted site (= i.e., structural similarity).

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investigated through a series of batch experiments in barite-equilibrated solutions.

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experimental conditions such as pH, saturation state, ionic strength (IS), coexistent cation

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concentrations ([Ca2+] and [Mg2+]), and sulfate concentration ([SO42-]) were investigated.

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constructed method was also applied to Se(IV) and Se(VI) in an artificial seawater (ASW) system.

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The ASW system was compared with a Milli-Q (MQ) water system for its use as a remediation

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technique of Se in the seawater system, because the removal of ions from seawater by

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adsorption/coprecipitation with mineral is not effective in most cases compared with freshwater.23-24

The uptake of Se(IV) and Se(VI) by barite was

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The effects of

The

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2. Materials and Methods

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2.1. Experiment procedure In the present studies, Se(IV) and Se(VI) stock solutions were prepared from NaHSeO3 and

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Na2SeO4 (Wako, Japan), respectively.

Barite was precipitated from a mixture of (i) Na2SO4

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solution and (ii) BaCl2·2H2O solution.25

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Se(IV) or Se(VI) was added to the sulfate solution.

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SI = log(IAP/Ksp), where IAP and Ksp are the ion activity product and solubility product of the

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mineral, respectively), and aqueous concentration of sulfate were fixed at pH 8.0, SI 4.2, and [SO42-]

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= 27 mM, respectively, as a basic system.

Additional experiments were conducted by changing one

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of the parameters from the basic system.

The Se concentration in the initial solution (using 1 mM

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Se solutions) was unsaturated with respect to the solid phases of barium selenite and barium selenate

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to avoid the formation of Ba-Se precipitates in the system.

Right before the addition of the BaCl2·2H2O solution, The pH, saturation index of barite (defined as

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The precipitates of barite and the aqueous phase were separated by filtration with a 0.20 µm

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membrane filter (mixed cellulose ester, Advantec, Tokyo, Japan) and then rinsed three times with

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MQ water.

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X-ray diffractometer (MultiFlex, Rigaku Co., Tokyo, Japan), in which the mineral phase was

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identified by comparing the XRD patterns with those in the International Center for Diffraction Data

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file.

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plasma-mass spectrometry (7700cs, Agilent, Tokyo, Japan) after dilution by a 2 wt.% HNO3 solution.

The X-ray diffraction (XRD) patterns of the precipitates were measured using a powder

The total Se concentrations in the solution and solids were analyzed by inductively coupled

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A part of the solid sample was dried in an oven at 60 °C and then dissolved in water by adding

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sodium carbonate to determine the Se concentration in the precipitates.26

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coefficient of Se between barite and water was calculated on the basis of the Se concentrations in the

The distribution

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aqueous and solid phase.

In order to evaluate the stabilities of Se(IV) and Se(VI) sorbed on barite,

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the extraction experiment was also carried out.

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phosphate and Se oxyanions on adsorption sites, and adsorption capacity can be calculated based on

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the amount of Se released into solution using phosphate as an extractant.3,7

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of each sample was added to 10 mL of 1.0 M Na2HPO4 solution and shaken for 24 hours prior to

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measurement of Se concentration using ICP-MS.

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measurements are described in detail in Supporting Information.

Previous studies showed the competition between

Approximately 10 mg

The analytical methods for XAFS and XRD

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2.2. Effect of pH, SI, IS, coexistent ions, and sulfate concentration The effect of pH on coprecipitation was studied by determining the amount of Se with barite

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within the pH range of 2.0-10.0 (fixed at SI = 4.2, [SO42-] = 27 mM).

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solution was initially adjusted with a HCl or NaOH solution.

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experiments was examined to account for the pH dependence of Se species: Se(IV) is mainly

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dissolved as H2SeO30 at pH 2.0, HSeO3- in the pH range of 2.0-8.0, and SeO32- at pH above 8.0,

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whereas Se(VI) is mainly dissolved as HSeO4- and SeO42- at pH 2.0, SeO42- above at pH 2.0,

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respectively (see Figure SI1 of Supporting Information).

The pH of the starting

The pH condition during the

The procedure was carried out for the MQ

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water and ASW systems.

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[Na+] = 54 mM, [SO42-] = 27 mM, [CO32-] = 2.2 mM) and ASW (IS = 0.534; [Na+] = 440 mM,

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[Mg2+] = 50 mM, [Ca2+] = 9.6 mM, [Cl-] = 440 mM, [SO42-] =27 mM, [CO32-] = 2.2 mM).

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The chemical compositions of the solutions were MQ water (IS = 0.076;

The effect of saturation state on the coprecipitation in the MQ water and ASW systems was

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studied within the SI range of 2.9-4.2 (fixed at pH = 8.0, [SO42-] = 27 mM).

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initial solution was adjusted with initial Ba2+ concentration.

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The SI of barite in the

The effect of the IS on the coprecipitation in the MQ water system was investigated within the

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IS range of 0.08-0.52 M (fixed at pH = 8.0, SI = 4.2, [SO42-] = 27 mM).

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adjusted by adding NaCl.

The IS was initially

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The effect of coexistent cations on coprecipitation in the MQ water system was studied at

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different [Ca2+] and [Mg2+] from 0.1-10 mM (fixed at pH = 8.0, SI = 4.2, [SO42-] = 27 mM), because

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of the larger concentrations of Mg2+ and Ca2+ in the seawater system.

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The effect of SO42- on coprecipitation in MQ water was also investigated at different [SO42-]

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from 1-27 mM (fixed at pH = 8.0).

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barium concentration was also changed as a function of [SO42-].

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The SI of barite in the initial solution was fixed at 4.2.

Thus,

The effect of reaction time was also examined in this study, which was described in the Supporting Information.

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3. Results

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3.1. Effect of pH on Se removal by coprecipitation

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Batch experiments were conducted under different pH conditions to understand the pH effect on

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the distribution coefficients of Se(IV) and Se(VI) between barite and water.

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that the uptake of Se(IV) by barite increased to 20.8 mmol/kg (MQ water system) and 239.5

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mmol/kg (ASW system) as the pH was increased from 2.0 to 10.0 (Fig. 1 and Table SI1 of

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Supporting Information).

However, the uptake of Se(VI) by barite was almost constant in both

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systems regardless of pH.

Barite had greater incorporation of Se(IV) than that of Se(VI) at the

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range of pH 2.0-10.0.

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The results showed

In the present study, we mainly studied coprecipitation capacity of barite for developing the

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direct Se removal technique from solution instead of adsorption method.

The solubility of BaSO4

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(Ksp= 10-9.97) is significantly lower than BaSeO3 (Ksp = 101.8) and BaSeO4 (Ksp = 10-7.5), thus barite

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with selenite/selenite can be readily recovered from solution than precipitations of pure solids of

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BaSeO3 and BaSeO4.

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for the immobilization of Se, suggesting the high applicability of barite coprecipitation method.

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Coprecipitation is a structural incorporation process during crystal growth, and the precipitates do

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not release the immobilized ions unless the host mineral is dissolved, whereas adsorption is a surface

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accumulation process that easily releases the adsorbed ions back to water.

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both mechanisms can be distinguished whether Se is released into the solution or not using

In addition, barite is resistant to dissolution and has strong crystal stability

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In the present study,

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phosphate as an extraction agent.

To identify the amount of Se adsorption on surface site in

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comparison to coprecipitation into the crystal lattice, the adsorption capacity was also determined.

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The results showed the similar trend in removal efficiency between adsorption and coprecipitation

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experiments, although the amount of Se coprecipitated with barite was relatively larger compared

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with that adsorbed on the surface because of the incorporation of target ions within the crystal

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structure (Fig. 1).

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crystal lattice of barite rather than by adsorption at the surface site.

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fixed Se was more resistant to release than those adsorbed at the mineral surface, suggesting that

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adsorption is less effective as a Se removal mechanism compared with coprecipitation.

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difference in distribution behavior between Se(IV) and Se(VI) shows the importance of chemical

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affinity on the Se incorporations to barite, which is related to the degree of proton dissociation of

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Se(IV) and Se(VI) in water.

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ions than for monovalent ones, because of the high stability of the surface complex to ions with large

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charges. 3 Selenium(IV) is dissolved as monovalent (HSeO3-) and divalent (SeO32-) species from pH

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2.0 to 10.0 (Fig. SI1).

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mainly dissolved as divalent species.

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constant because Se(VI) is mainly dissolved as a divalent (SeO42-) species in the experimental pH

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range.

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depending on pH, which is controlled by the affinity for the adsorption site on the surface rather than

Most of Se in the solutions can be removed by coprecipitation possibly into the In addition, the structurally

The

Previous studies showed the higher adsorption affinity for divalent

Thus, the amount of Se(IV) in barite increased at higher pH where Se(IV) is Conversely, the amount of Se(VI) in barite was almost

The uptake of Se(IV) by barite was affected by the degree of dissociation of Se(IV) in water

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structural similarity in the crystal lattice.

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at pH 10.0.

Thus, we can efficiently remove Se(IV) from the solution

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3.2. Effect of saturation state on Se removal by coprecipitation Batch experiments were conducted to understand the effect of precipitation rate on the

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distribution coefficients of Se(IV) and Se(VI) between barite and water.

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that the precipitation rate is correlated with the degree of SI in solutions.26, 27

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study, the SI values of barite in the initial solution were changed (SI = 2.9, 3.2, 3.5, 3.8, or 4.2) to

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understand the incorporation mechanism associated with structural geometry between substituted

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(SO42-) and substituent (SeO32- or SeO42-) ions.

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Previous studies showed Thus, in the present

The results showed that the amounts of Se(IV) and Se(VI) in barite were relatively unaffected

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by the change in SI (Fig. 2 and Table SI2).

Previous studies showed the dependence of structural

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similarity between substituted- and substituent-ion on the partition behavior of trace elements,

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resulting in differences in the amount of incorporation as a function of the precipitation rate. 21, 27-32

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However, in the present study, the difference in geometry between SeO32- and SeO42- had little

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influence on the amount of their incorporations, possibly because of the minimal crystal lattice

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distortion in the SI-changed system (Fig. SI2, discussed in 4.1).

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the amount of Se removal from the solution by adjusting SI in the initial solution when SI is lower.

Thus, it is not effective to increase

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3.3. Effect of IS on Se removal by coprecipitation Batch experiments were conducted at different IS (0.08, 0.15, 0.32, or 0.52 M) to understand the

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effect of IS on the distribution coefficients of Se(IV) and Se(VI) between barite and water.

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results showed that the amounts of adsorbed- and coprecipitated-Se(IV) and Se(VI) were relatively

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unaffected by the change in IS by one order of magnitude (0.05-0.6 M) (Fig. 3, Table SI3).

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effect of IS on the partitions can be explained by distinguishing inner-sphere and outer-sphere

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surface complexes.33, 34 For example, Hayes and Leckie (1988)33 showed that the adsorption of

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Se(IV) on hydrous ferric oxide is slightly influenced by IS because Se(IV) forms an inner-sphere

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complex, whereas that of Se(VI) is markedly decreased by increasing IS because Se(VI) forms an

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outer-sphere complex. In the present study, the uptake of Se(IV) and Se(VI) by barite was not

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affected by IS, possibly owing to the strong specific binding as an inner-sphere complex between

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Se(IV) or Se(VI) and barite.

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The

The

Extended X-ray absorption fine structure (EXAFS) was performed to characterize the local

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coordination structure of adsorbed- and incorporated-metals in a host mineral.

The Se K-edge

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EXAFS and the Fourier transforms (FTs) of the barite samples are shown in Fig. SI3.

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the positions and intensities of peaks roughly correspond to the interatomic distances and

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coordination numbers (CNs), respectively.

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barite can be explained by the three shells of one Se-O and two Se-Ba shells named as Se-Ba1 and

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Se-Ba2 shells (Table SI4).

In the FTs,

Fitting results showed that both Se(IV) and Se(VI) on/in

The CN and distance of Se-O shows that Se(IV) or Se(VI) is

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incorporated into barite as SeO32- in a trihedral coordination with oxygen or SeO42- in a tetrahedral

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coordination with oxygen, respectively.

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and Se(VI) are similar to those of S-Ba in barite,35 suggesting that Se is incorporated into the barite

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structure by substitution in the sulfate site.

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adsorption samples, indicating the strong specific binding of Se(IV) or Se(VI) with barite as an

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inner-sphere complex. An inner-sphere surface complex has no water molecule interposed between

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the adsorbed species and adsorption site.

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between adsorption and coprecipitation, suggesting similar bonding of Se with barite and there is no

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water molecules present between the ions and the surface or crystal lattice of barite.

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of CNs in the second shell (Se-Ba2) between adsorption and coprecipitation samples also suggests

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that we can distinguish adsorption/coprecipitation reactions in the experiments.

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Se(IV) and Se(VI) by barite was not affected by IS variation because of the formation of the

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inner-sphere complex.

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using the present method.

The CNs and distances of Se-Ba1 and Se-Ba2 for Se(IV)

The Se-Ba1 and Se-Ba2 shells were also observed in the

The observed Se-O interatomic distances are nearly equal

The difference

The uptake of

Thus, we can remove Se(IV) and Se(VI) from solution regardless of IS by

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3.4. Effect of coexistent cations on Se removal by coprecipitation

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Artificial seawater contains larger amounts of Mg2+ and Ca2+ ions compared with MQ water.

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Batch experiments were conducted at different coexistent ion concentrations ([Mg2+] or [Ca2+]) to

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understand their effects on the distribution coefficients of Se(IV) and Se(VI) between barite and

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water (Fig. 4, Table SI5).

The results showed that the uptake of Se(IV) by barite greatly increased

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in the presence of Ca2+ in the solution, whereas that of Se(VI) was almost constant.

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presence of Mg2+ in the solutions had little effect on its partitions of Se(IV) and Se(IV) to barite.

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The uptake of Se(IV) by barite was only affected by the variation of [Ca2+] in the solutions.

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present study, we can ignore the removal of Se(IV) by calcium selenite precipitate because of the

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high solubility of calcium selenite precipitate (Ksp = 102.8) and undersaturated in experimental

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solutions.

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Ca-added barite and there is no Ca-Se shell in all samples (Fig SI3 and Table SI4), suggesting that

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Se(IV) is removed from solution by coprecipitation with barite, but not as calcium selenite

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precipitate.

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the solutions.

By contrast, the

In the

The Se K-edge EXAFS and the FTs spectra were generally similar between pure and

Thus, we can efficiently remove Se(IV) from solution in the presence of high [Ca2+] in Further information will be discussed in 4.1.

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3.5. Effect of sulfate concentration on Se removal by coprecipitation Our present study showed that both Se(IV) and Se(VI) are substituted to the sulfate site in the

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barite structure as a trihedral or tetrahedral coordination with oxygen, respectively.

In other words,

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sulfate works as a substituted ion for Se(IV) and Se(VI) in the barite structure and may control the

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extent of trace element incorporation in barite.

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[SO42-] to understand the effect on the distribution coefficients of Se(IV) and Se(VI) between barite

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and water.

Batch experiments were conducted at different

The SI of barite in the initial solution was fixed at 4.2, thus barium concentration was

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also changed as a function of [SO42-] ([Ba2+] = 0.7~6.4 mM; [SO42-] = 1~27 mM). The results showed that both Se(IV) and Se(VI) were incorporated to a large degree into barite

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when the sulfate level was low (Fig. 5, Table SI6).

The removal of Se(IV) and Se(VI) by barite was

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relatively higher compared with those under other conditions, suggesting that we can efficiently

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remove Se from the solution by adjusting sulfate level in the solutions. XRD analysis showed that

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the barite transformed to barium selenate at lower sulfate levels on the basis of based on the larger

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peak shift in XRD patterns to low 2θ (KBaSeO3 = 101.8 and KBaSeO4 = 10-7.5, at 25 °C, 1 atm) (Fig. SI4).

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However, the amount of released Se in 1 M Na2HPO4 solution was significantly lower in these

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samples, suggesting that Se(IV) and Se(VI) were structurally fixed in the precipitates, thereby

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preventing the release of Se to the solution when the surrounding environment was changed.

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4. Discussion

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4.1. Se removal by coprecipitation in artificial seawater system

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The degree of Se uptake during coprecipitation with barite showed significant difference

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between the MQ water and ASW systems (Fig. 1 and 2). Results showed that (i) the uptake of

261

Se(IV) by barite in ASW was relatively higher compared with that in MQ water, but (ii) that of

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Se(VI) was similar between the two systems.

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on its partitions to minerals, such as goethite24 and apatite36.

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from seawater is negligible compared with that in freshwater because of the inhibition of

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sorption/crystallization by high IS or competitive ions in the ASW system.

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study showed that the uptake of Se by barite was enhanced in the presence of [Ca2+] in the solution,

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causing the greater incorporation of Se(IV) by barite from ASW compared with that from MQ water.

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To validate the result, we investigated the cause of the greater incorporation of Se in the presence of

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[Ca2+] in the solution by using XRD analysis to determine the unit-cell dimensions of barite and to

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understand the dependence of the degree of structural distortion caused by substituent ion in the

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barite structure.

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cell, relative angles of sides to each other and the volume of the cell, which describes the degree of

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substitution of foreign ions into the crystal lattice.

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greater expansion/shrinkage of unit-cell volume in the crystal structure, which is related to the ionic

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size of the substitution atom.

Previous studies showed the effect of seawater matrix They reported that the removal of ions

However, the present

The unit-cell dimension is defined by three parameters: length of the sides of the

At higher level of ion incorporation causes

In the present study, the shrinkage in the unit-cell parameters by the

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incorporation of foreign ions (SeO32-, SeO42-, and Ca2+) was observed in the crystal structure of

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barite (Fig. SI5).

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barite35 to calculate the unit-cell dimensions of a-, b-, and c-axes for each sample (which are defined

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as ka, kb, and kc) by the difference between pure and Ca-added barite.

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The initial unit-cell parameter was determined based on the Pnma space group of

The unit-cell parameters of the non-substituted, Se(IV)-substituted, and Se(VI)-substituted

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samples in the presence of [Mg2+] or [Ca2+] are listed in Table SI7.

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changes in the b-axis but considerable differences in the a- and c-axes.

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the solution, the ka values of these samples changed as a function of [Ca2+], and the order of degree

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of distortion is as follows: non-substituted < Se(VI)-substituted < Se(IV)-substituted sample (Fig. 4a).

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On the other hand, in the presence of Mg2+ in solution, the ka values were constant regardless of

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[Mg2+] (Fig. 4b).

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behavior of Se(IV) and Se(VI) to barite.

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the barite structure with varying degrees of crystal distortion, and the shrinkage of the unit cell

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volume controls the amounts of Se(IV) and Se(VI) in barite.

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strongly increased in the presence of [Ca2+] in the solution possibly because of the larger crystal

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lattice distortion by Ca2+ than by Mg2+ into the barite structure.

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with Ca2+ promoted the incorporation of Se(IV) into the barite structure.

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Se(VI) in barite was almost constant with increasing [Ca2+].

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between Se(IV) and Se(VI) can be explained by the lattice mismatch between substituted- and

These parameter shows little In the presence of [Ca2+] in

These findings show the dependence of structural distortion on the partition It is considered that Ca2+ and Mg2+ are incorporated into

Thus, the amount of Se in barite

This structural distortion associated However, the amount of

The difference in the distribution

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It is considered that SeO32-, which has different geometry from SO42-, is

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substituent-ion.

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incompatibly substituted to the SO42- site in the barite structure, thereby inducing larger

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incorporation when the crystal lattice is distorted by Ca2+.

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substituted to the SO42- site because of the similar geometry, which has little influence on the amount

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of its incorporation regardless of structural distortion.

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SeO32- -substituted samples were changed by the degree of incorporations (Fig. SI5).

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showed that the distortion effect of Ca2+ was stronger than that of SeO32- or SeO42-, indicating that

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the structure of barite became more distorted in the presence of Ca2+.

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distortion was observed in the coexistent system of Ca and Se than that in the single system of Ca or

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Se (Fig 4a and SI5).

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the SI, but the extent of change was smaller in the SI-change system compared with the Ca2+-added

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system (Fig. SI2).

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Se by barite because of the minimal crystal lattice distortion in the SI-change system.

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By contrast, SeO42- is compatibly

The unit-cell dimensions of Ca2+, SeO32-, and The results

A larger degree of crystal

The unit-cell dimension of non-substituted barite was also linearly changed by

Thus, we can ignore the effect of SI in the present study for effective removal of

Similar phenomena were observed in other oxyanions (H2AsO3-, HAsO42-, TeO32-, HTeO4-,

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MoO42-, and WO42-) coprecipitated with barite at various [Ca2+] (Fig. 6, Table SI7).

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showed the large incorporation and distortion of incompatible elements (H2AsO3-, HAsO42-, TeO32-)

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with varying degree of [Ca2+], and the order of distortion is as follows: Mo(VI)-substituted