Speciation of phosphorus zinc and copper in soil and water

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Environmental Measurements Methods

Speciation of phosphorus zinc and copper in soil and water dispersible colloid affected by a long-term application of swine manure compost Kosuke Yamamoto, Yohey Hashimoto, Jihoon Kang, and Kazuki Kobayashi Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.8b02823 • Publication Date (Web): 17 Oct 2018 Downloaded from http://pubs.acs.org on October 22, 2018

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Environmental Science & Technology

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Speciation of phosphorus zinc and copper in soil and water dispersible colloid

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affected by a long-term application of swine manure compost

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Kosuke Yamamoto1), Yohey Hashimoto1)*, Jihoon Kang2), and Kazuki Kobayashi1)

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1)Tokyo University of Agriculture and Technology

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2) University of Texas Rio Grande Valley

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*corresponding author: [email protected]

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Abstract

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The objective of this study was to investigate the concentration and chemical species of Zn,

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Cu and P in the bulk soil and water dispersible colloid (WDC) fraction collected from a field

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where swine manure (SM) compost has been continually applied for 23 years. A filtration

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and ultracentrifugation process was used to separate and collect WDC (20–1000 nm) from

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the soil. The continual application of SM increased soil P from 1.6 to 4.5 g kg-1, Zn from 109

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to 224 mg kg-1 and Cu from 87 to 95 mg kg-1 for 23 years. The continual SM compost

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application also enhanced the formation of soil WDC in which Zn (215 mg kg-1) and Cu (62

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mg kg-1) were highly accumulated and P (25 g kg-1) was greater than the bulk soil.

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According to the result of X-ray absorption spectroscopy (XAS), the continual application of

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SM compost increased P associated with Fe hydroxides in the soil and WDC fraction. Iron

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K-edge XAS revealed the dominance of goethite and ferrihydrite in the WDC fraction,

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suggesting that P were bound to these (oxy)hydroxides. Copper K-edge XAS determined

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the dominance of Cu(II) associated with humus in the soil and WDC fraction. For Zn

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species in the SM compost applied soil, hopeite and Zn associated with humus were

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accumulated in the bulk soil, whereas Zn associated with humus was the primary species in

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the WDC fraction. Our study suggests that the formation of organic complexes in the WDC

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fraction could enhance the mobility of Zn and Cu as the repeated application of SM

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compost continues.

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Environmental Science & Technology

Introduction

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Accumulation of phosphorus (P) and heavy metals of zinc (Zn) and copper (Cu) is a

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common issue in soils receiving a large amount of swine manure (SM) and in farms with pig

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production. Among the various types of livestock, SM or pig slurry contains relatively high

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levels of Zn and Cu [1] due to the extensive use as veterinary medicinal products in pig

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production [2]. Therefore, the continual application of SM in the farmland results in the

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elevation of these elements in soils. Jensen et al. (2018)[2] reviewed the studies of

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long-term field trial of swine manure applications and found that the annual loading rate of

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Zn increases linearly to the annual accumulation of Zn in soils with an accumulation rate of

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0.96 mg kg-1 per year in Denmark. Another monitoring study on pig-slurry applied soils in

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the entire country of Denmark reported that 45% of all soil samples collected in the entire

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country exceeded the predicted no-effect concentrations of Zn for soil organisms [3]. The

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accumulation of Zn in soils receiving manure from piglet production farms may be

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vulnerable to leaching loss of Zn, particularly in sandy soils [2].

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The mobility and potential bioavailability of elements in soils depend on their

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oxidation states and chemical species. According to previous studies using

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synchrotoron-based X-ray absorption spectroscopy (XAFS), chemical species of elements

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have been determined in SM and pig slurry mainly as struvite [4] for P, hopeite [4], Zn

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phosphate [5] and ZnS [6] for Zn and Cu associated with organic matter [5] for Cu. It is

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largely unknown how the chemical species of elements, particularly Zn and Cu in SM will

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have been altered in the soil for a decade or even longer time span. Formentini et al. (2017)

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[6] investigated Zn species in the soil applied continually with pig slurry for 11 years and

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found that ZnS abundant in pig slurry was not detected in the soil but had been transformed

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and accumulated as Zn associated with organic matter. A comprehensive study focusing on

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P, Zn and Cu in SM applied soils is essential because high levels of soil Zn and Cu

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detrimentally affect activity of phosphatases [7] that may affect P species derived from SM

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in the long term. Phosphorus, Zn and Cu in soils are interacted each other in their chemical

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species, eventually impacting mobility and potential availability to biota.

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Water-dispersible colloid (WDC) being representative of readily mobile colloids with

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a size range of 1-1000 nm plays a critical role in transport of elements in soils. Previous

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studies observed a drastic increase of Zn, Cu and P transport in response to the increase of

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colloidal transport [8, 9]. A notable accumulation of P and Zn was found in the WDC fraction

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of soil and SM compost, compared with those bulk samples [4, 10]. With the use of

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synchrotron-based XAFS spectroscopy, these studies revealed the contrasting differences

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in chemical species of P and Zn between bulk soil and WDC phases, suggesting the

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relevance of WDC fraction for elucidating mobility and potential bioavailability of elements 3 ACS Paragon Plus Environment

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in soils. Despite the importance of WDC in transport and bioavailability of elements,

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previous studies have mainly focused on the bulk soil, particulate and dissolved fractions

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(operationally defined as a