Increases of Total Mercury and Methylmercury Releases from

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Increases of Total Mercury and Methylmercury Releases from Municipal Sewage into Environment in China and Implications Maodian Liu, Peng Du, Chenghao Yu, Yipeng He, Haoran Zhang, Xuejun Sun, Huiming Lin, Yao Luo, Han Xie, Junming Guo, Yindong Tong, Qianggong ZHANG, Long Chen, Wei Zhang, Xiqing Li, and Xuejun Wang Environ. Sci. Technol., Just Accepted Manuscript • DOI: 10.1021/acs.est.7b05217 • Publication Date (Web): 07 Dec 2017 Downloaded from http://pubs.acs.org on December 7, 2017

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Environmental Science & Technology

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Increases of Total Mercury and Methylmercury Releases from Municipal Sewage into Environment in China and Implications

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⊥ Maodian Liu†‡, Peng Du†, Chenghao Yu†, Yipeng He†‡, Haoran Zhang†, Xuejun Sun§ , Huiming Lin†, Yao Luo†, Han Xie†, Junming Guoǁ, Yindong Tong#, Qianggong Zhang§∇, Long Chen○◆, Wei Zhang¶, Xiqing Li†, Xuejun Wang†*

6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26

†Ministry of Education Laboratory of Earth Surface Process, College of Urban and Environmental Science, Peking University, Beijing 100871, China ‡Department of Marine Sciences, University of Connecticut, 1080 Shennecossett Rd., Groton, CT 06340, USA §Key Laboratory of Tibetan Environment Changes and Land Surface Processes, Institute of Tibetan Plateau Research, Chinese Academy of Sciences, Beijing 100101, China ⊥Graduate University of the Chinese Academy of Sciences, Beijing 100049, China ǁState Key Laboratory of Cryospheric Science, Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences, Lanzhou 730000, China #School of Environmental Science and Engineering, Tianjin University, Tianjin 300072, China ∇Chinese Academy of Sciences Center for Excellence in Tibetan Plateau Earth Sciences, Beijing 100101, China ○Key Laboratory of Geographic Information Science (Ministry of Education), East China Normal University, Shanghai 200241, China ◆School of Geographic Sciences, East China Normal University, Shanghai 200241, China ¶School of Environment and Natural Resources, Renmin University of China, Beijing 100872, China

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Corresponding authors:

28 29 30

Xuejun Wang. Ministry of Education Laboratory of Earth Surface Processes, College of Urban and Environmental Sciences, Peking University, Beijing 100871, China. Tel: +86-10-62759190. E-mail: [email protected]

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Word count for text: 4,995

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Word count for 6 figures: 6 × 300 = 1,800

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Total word count: 6,795

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ABSTRACT: As a globally transported pollutant, mercury (Hg) released from human

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activity and methylmercury (MeHg) in the food web are global concerns due to their

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increasing presence in the environment. In this study, we found that Hg released from

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municipal sewage into the environment in China is a substantial anthropogenic source

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based on mass sampling throughout China. In total, 160 Mg (140-190 Mg, from the

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20th percentile to the 80th percentile) of Hg (THg) and 280 kg (240-330 kg) of MeHg

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were released from municipal sewage in China in 2015. The quantities of released

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THg and MeHg were the most concentrated in the coastal regions, especially in the

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East, North and South China regions. However, the per capita release of THg and

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MeHg was the highest in the Tibetan region, which is recognized as the cleanest

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region in China. THg released into aquatic environments was mitigated from 2001 to

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2015 in China, but the amounts released into other sinks increased. This study

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provides the first picture of the release of Hg from municipal sewage into various

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sinks in China, and policy makers should pay more attention to the diversity and

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complexity of the sources and transport of Hg, which can lead to Hg accumulation in

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the food web and can threaten human health.

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INTRODUCTION

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Mercury (Hg) can cycle through the atmosphere, hydrosphere and pedosphere;

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bio-magnify in the food web; and threaten the health of wildlife and humans.1-3 Hg is

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a naturally occurring element, but human activities have altered the global

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biogeochemical cycle of Hg.4-6 Quantification of the total Hg (THg) amount released

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into the atmosphere, hydrosphere and pedosphere on a global scale has been

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performed.7-11 Substantial amounts of anthropogenic THg have been emitted into the

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atmosphere from China in recent years.12-14 In total, 530 Mg of anthropogenic THg

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was emitted into the atmosphere by China in 2014,14 and the global THg emissions

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ranged from 2,000 to 2,300 Mg in 2010.9, 15 The release of anthropogenic Hg into

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aquatic environments is also critical since this can directly influence the Hg levels in

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fish and other biota.16-18 The intake of fish contaminated with Hg, primarily as

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methylmercury (MeHg), has already resulted in severe impacts on humans over the

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past century, such as the emergence of Minamata Disease in Japan.19 In total, 100 Mg

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of anthropogenic THg was directly released into aquatic environments in China in

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2012,20 and the annual global THg release in recent years was 1,100 Mg.5 Compared

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with the release of THg into the atmosphere and aquatic environments, the

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quantification of THg released into land is insufficient. Hui et al. indicated that 650

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Mg of anthropogenic THg was released into the land in China in 2010,10 but the study

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lacked details regarding Hg sinks. In China, an abundance of municipal solid waste

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has been applied to croplands and should not be ignored.21 The direct emission of

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THg in China has continuously increased,14 but the amount of THg released into

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aquatic environments in China has decreased since 2001.20 The trend in the amount of

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THg released into land is still unclear in China and should be studied since the release

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of anthropogenic Hg into land may cause an increase in Hg levels in rice, which can

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result in higher levels of Hg exposure in humans.22, 23

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Previous studies have focused on the release of some pollutants associated with

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municipal sewage in China, such as photoinitiators,24 chlorinated paraffins and

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polycyclic aromatic hydrocarbons.25,

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focused mainly on primary industries, such as coal-fired power plants,27 nonferrous

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metal smelting, polyvinyl chloride production and other intentional uses.28-30 In a

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previous paper, we indicated that the release of THg from municipal sewage may be a

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primary source for the direct release of anthropogenic THg into aquatic environments,

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but the data associated with municipal sewage are insufficient.20 THg releases into the

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atmosphere and land from municipal sewage treatment plants (MSTPs) in China are

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still unclear. In total, 30 Tg of sewage sludge was produced from MSTPs in China in

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2015, which is a large increase from the 11 Tg released in 2005.31 In 2015, 20% of the

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sewage sludge produced from MSTPs was applied to croplands31, thereby having the

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potential to increase the exposure of the Chinese population to Hg through rice and

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livestock (e.g., poultry) intake.32, 33 Few studies have focused on the release of MeHg

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from anthropogenic sources at the national level in China. Previous studies have

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indicated that municipal sewage discharge can significantly influence the pollution

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level and the health of fish.34, 35 The MeHg released from municipal sewage and other

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anthropogenic sources should not be ignored.

26

For Hg, previous studies in China have

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In this study, we aim to quantify the release of THg and MeHg from municipal

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sewage into aquatic environments (i.e., rivers, lakes and sea-adjacent waters) in China

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based on measurements of municipal sewage samples (including untreated and treated

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sewage). We also provide a comprehensive understanding of the release of THg from

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municipal sewage into other various sinks (i.e., aquatic environments, landfills,

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croplands, urban areas, natural land and the atmosphere) in China from 2001 to 2015

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based on material flow analysis. This study is motivated by our recognition of the

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potential role of Hg released from municipal sewage into the environment, and it is

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intended to support policy making in China and the implementation of the Minamata

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Convention.

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MATERIALS AND METHODS

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Sample Collection. Samples were collected from 62 MSTPs in 24 provinces and

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municipalities from July 2014 to Aug 2016 following a technique used in previous

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studies.24, 36 Sample sites were selected based on the population distribution in China

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(“Hu Huanyong Line”, Figure 1) and were concentrated in the eastern regions of

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China,20, 37 in particular, the North, East and South China regions, which are the three

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most developed regions with the largest population densities in China. In each of

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these regions, five or more MSTPs were selected for municipal sewage sample

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collection. Detailed information on the MSTPs is provided in Table S1, Supporting

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Information. In total, the cities where these sample sites were located have a

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combined population of 260 million people (40% of the total urban population of

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China) in 2010 (Figure 1).

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All MSTPs were sampled for two days, i.e., one weekend day and one week day,36

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for THg and MeHg analyses. Influent sewage (untreated sewage) and effluent sewage

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(treated sewage) were collected as 24 h composite samples by autosamplers, FC-9624

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(GRASP Science & Technology, China), ISCO 3000, 3700, 4700 (Teledyne

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Technologies, USA), and GD-24A (Jinpeng Huanyi Technology, China), based on a

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previous study.36 We programed the autosamplers to sample 100 mL of the sewage

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each hour using acid-cleaned Teflon tubing. The samples were collected in

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acid-cleaned glass or polycarbonate bottles.38,

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avoided during sampling.36 Following the collection, the samples were preserved by

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adding 4 ml/L of pre-tested 11.6 M trace metal-grade HCl and stored under cool and

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dark conditions following U.S. EPA methods 1631E and 1630, and they were then

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express-delivered to labs as soon as possible (within 24 h).24, 39 Samples from each

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site were filtered through 0.45-µm pore size cellulose nitrate membranes (Whatman,

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product code 10401170) to analyze the particulate THg and MeHg and were preserved

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by freezing.38, 39

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Heavy precipitation days were

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Analytical Methodology. Sewage samples were taken in triplicate and analyzed for

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THg and MeHg following U.S. EPA methods 1631E and 1630. Briefly, for dissolved

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THg, all the samples were oxidized to Hg(II) with BrCl; the free halogens were

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destroyed by NH2OH·HCl, and Hg(II) was converted to Hg(0) using SnCl2. The

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samples were analyzed by cold vapor atomic fluorescence spectrometry (CVAFS,

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Tekran model 2600). Analysis of dissolved THg was completed at the Institute of

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Tibetan Plateau Research of the Chinese Academy of Sciences. For dissolved MeHg,

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the samples were placed in fluoropolymer distillation vessels and distilled into

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receiving vessels at 125 °C under a N2 flow. After the distillation, the samples were

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adjusted to pH 4.9 with an acetate buffer and ethylated by the addition of sodium

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tetraethyl borate (NaBEt4). The samples were analyzed by cold vapor atomic

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fluorescence spectrometry (GC-AFS, Tekran model 2700) at Peking University.

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For particulate THg, filters containing particles from filtering 50 to 500 mL of

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municipal sewage were analyzed by a DMA-80 (U.S. EPA method 7473) at Peking

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University based on a previous study.40 For particulate MeHg, filters containing the

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particles were digested with 4.57 M of trace metal-grade HNO3 in a water bath (60 °C)

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for 12 h, neutralized with KOH, buffered with acetate, and ethylated with NaBEt4

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based on previous studies.39, 40 The particulate MeHg samples were analyzed by cold

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vapor atomic fluorescence spectrometry (GC-AFS, Tekran model 2700). We analyzed

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the dissolved THg and dissolved MeHg of each sample in triplicate and the particulate

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THg and particulate MeHg of each sample in duplicate. The detection limits for the

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dissolved THg, particulate THg, and both the dissolved and particulate MeHg

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analyses were 0.1 ng/L, 0.1 ng/g and 0.01 ng/L, respectively, which were calculated

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based on the average concentrations of the method blanks plus triple the standard

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deviation of the blanks. The individual internal standard spike recoveries for the

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dissolved THg, particulate THg, dissolved MeHg and particulate MeHg analyses were

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94 ± 5%, 97 ± 3%, 83 ± 9% and 87 ± 9%, respectively. All the concentration data

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were adjusted using the individual internal standard spike recoveries.38

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We divided mainland China into 8 regions (Figure S1, Supporting Information). In

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some provinces, municipal sewage samples were unavailable, and we used the

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concentration data from other provinces in the same region to estimate the data in

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these provinces based on a population-weighted method.41,

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effluent sewage samples were unavailable (Table S1, Supporting Information);

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therefore, we modeled the samples based on a fitting model for the Hg concentration

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data of the influent and effluent sewage of the other MSTPs. The fitting error of each

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model was considered in the uncertainty analysis. Statistical analysis was conducted

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using R version 3.3.2 (R Foundation for Statistical Computing, Vienna, Austria).

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Significant levels were determined to be at the P < 0.05 level.

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For some MSTPs,

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Hg Released from Municipal Sewage. We applied a model that was developed in

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a previous study to estimate the primary release of anthropogenic aquatic Hg to model

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the release of THg and MeHg from municipal sewage in China.20 Parameterization of

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the model was accomplished using Monte Carlo simulations.20 The concentrations of

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THg

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(Kolmogorov-Smirnov test, P > 0.05). In the model, aquatic Hg released from

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different anthropogenic sources was divided into two groups.20 The first group was

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based on measured Hg concentration data, and the second group was based on a

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method developed by AMAP/UNEP.43 In this study, we used the first group to

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estimate the probabilistic distribution of the release of THg and MeHg from municipal

and

MeHg

in

this

study

followed

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log-normal

distributions

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sewage, as given below:20

   =   , ×  ×   1 

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where  is the probabilistic distribution of the flux of THg (i=1) (Mg/yr) or

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MeHg (i=2) (kg/yr) released from municipal sewage for all of China,  , is the

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probabilistic distribution of the concentration of THg or MeHg (ng/L) in the untreated

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sewage of province j,  is the total annual volume (104 m3/yr) of municipal sewage

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produced from province j (Figure S2, Supporting Information), and  is the unit

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conversion factor for THg (10-8) or MeHg (10-5). Data for the municipal sewage

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discharge in each province were collected from the China Environmental Statistical

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Yearbook (Figure S2, Supporting Information).44

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Material Flow Analysis. As an effective tool to provide a system-oriented view of

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the interlinked processes and to support policy decisions,45, 46 material flow analysis

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was applied to provide a better understanding of THg and MeHg transport in the

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sewage-environment systems in this study. Parameterization of the analysis model

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was accomplished using Monte Carlo simulations. The concentrations of THg and

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MeHg in this study follow log-normal distributions. Similar to Allesch and Brunner’s

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study,45 we began the Hg material flow with a municipal sewage input into the system,

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continued with the treatment and transport (i.e., MSPT, sewage sludge and

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incineration), and ended with the release into various sinks (i.e., aquatic environments,

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land and atmosphere). The method was established based on the mass balance

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principle to ensure that the amount in the sources was equal to the amount in the sinks,

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and the temporary storages changes and the mass balance is provided below:45 

 =   , ×  , ×   + , × , ×   2 





#







 =  !"# × $#  3 #

)





 !"# × $#  = &'() × $)  4

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where  is the probabilistic distribution of source l of THg (Mg/yr) or

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MeHg (kg/yr) released from municipal sewage in province j. We divided the source

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into two groups (g). One is the release of THg or MeHg associated with untreated

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sewage, and the other one is associated with treated sewage based on a previous

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study.20  , and , are the probabilistic distributions of the THg or MeHg

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concentrations (ng/L) in untreated sewage and treated sewage from province j,

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respectively;  , and , are the annual volumes (104m3/yr) of the untreated

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sewage and treated sewage in province j, respectively (Figure S3, Supporting

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Information);  !"# is the probabilistic distribution of the temporary

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storage, n (i.e., MSTP, sewage sludge and incineration), of THg (Mg/yr) or MeHg

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(kg/yr) in province j; &'() is the probabilistic distribution of sink m (i.e.,

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rivers, lakes, oceans, landfills, croplands, natural lands, atmosphere and urban areas)

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for THg (Mg/yr) or MeHg (kg/yr) in province j; and P is the percentage of sewage or

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sewage sludge transported from the last tier into the source or temporary storage (%).

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The material flow analysis was run from 2001 to 2015 in this study. In the

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sewage-environment system, the THg and MeHg concentrations transported into

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different temporary storage locations or sinks were estimated based on the transport

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process and the sewage or sewage sludge sinks in different provinces (Figure S2,

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Supporting Information). Municipal sewage originates from urban areas, but urban

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areas can also serve as sinks and accept flows, such as reused treated sewage (e.g.,

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reuse in industry, municipal services and landscape water) and sewage sludge (e.g.,

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building material). The MeHg flows ended being transported into sewage sludge in

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the MSTP since the mechanisms of Hg methylation and MeHg demethylation in

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sewage sludge are unclear. THg emissions from sewage sludge (after being released

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into land) were considered legacy sources for the atmosphere. The annual emission

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rates of THg from landfills and from the irregular dumping of sewage were referenced

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from a previous study,47 ranging from 3.0×10-6 to 9.0×10-6 and 1.0×10-3 to 2.0×10-3 g

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per ton of annual mass of disposed wastes, respectively. The mean values (6.0×10-6

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and 1.5×10-3) were estimated based on the ranges,11 and we reran them using the

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Monte Carlo method to get the median values and P20-80 confidence intervals. The

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THg emission rate from sewage sludge after its application to croplands was assumed

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to be the same as that for the emission from landfills due to the lack of data. The

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percentage of THg emissions from the incineration of sewage sludge was set at 48%

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(29%-75%, P20-80 confidence interval) based on previous studies.48-52 The large

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uncertainty in this section is due to unknown pollution emissions from the

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incineration of sewage sludge in China.48-52 We used the median value to avoid

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overestimating this portion and considered the range in the uncertainty analysis based

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on the Monte Carlo simulation.20 Most THg in influent sewage can transfer into the

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sewage sludge in the treatment process48, 49 based on the mass balance principle. We

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modeled the median THg concentrations in the sewage sludge for the MSPTs in each

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province and compared them with published measurement data to ensure that the

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material flow analysis was reasonable. The modeling process is provided below:

+, =

   , × , ×  − , × , ×   5 -

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where +, is the probabilistic distribution of the THg concentration (µg/g) in

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sewage sludge in province j, and - is the annual mass of sewage sludge (104 Mg/yr)

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yielded by province j.

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Uncertainty Analysis. A Monte Carlo simulation (10,000 runs) was applied to

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analyze the robustness of the inventories and material flow analyses of THg and

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MeHg.20, 53 The concentrations of THg and MeHg in this study followed log-normal

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distributions. The municipal sewage discharge data and other activity levels (such as

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sewage sludge production data) were all obtained from official statistics.31 A uniform

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distribution with a fixed coefficient of deviation (5%) was assumed for the official

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statistical data based on previous studies.20, 42 The median values and the P20-80

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confidence intervals of the statistical distributions were modeled to quantify the THg

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and MeHg fluxes and to characterize the uncertainty.20, 53

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RESULTS AND DISCUSSION

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THg and MeHg Released from Municipal Sewage. The average THg

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concentration

in

untreated

sewage

in

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(population-weighted average ± standard deviation) in recent years, and this is nearly

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one thousand times higher than THg concentrations in general freshwater systems in

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China.54-56 The highest THg concentration in untreated sewage was found in Tibet

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(15,000 ± 4,400 ng/L), followed by the Heilongjiang province (8,900 ± 4,000 ng/L)

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and Beijing city (5,700 ± 3,000 ng/L) (Figure 2). The highest THg concentration in

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untreated sewage in Tibet might be explained by traditional Tibetan medicines,

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cinnabar or gold amalgam (please see details below). The THg concentrations in most

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provinces in China were typically higher than those in other countries (such as Brazil,

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Canada and the U.S., ranging from 61 to 310 ng/L),49, 57-59 but they were similar to

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previous measurement results in China (ranging from 260 to 14,000 ng/L, Figure 2,

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Table S2, Supporting Information).60,

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municipal sewage in China are complicated. In addition to household contributions,

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the THg in municipal sewage partly originates from industrial wastewater and

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road-deposited sediment input associated with rainfall.31,

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concentration in treated sewage in China was 160 ± 130 ng/L. Approximately 95% of

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the THg in the influent sewage transferred into the sewage sludge.

61

China

was

3,400

±

2,600

ng/L

This is because the sources of THg in

62

The average THg

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For MeHg, the average concentration in untreated sewage in China was 6.5 ± 5.5

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ng/L, which is tens of times higher than MeHg concentrations in general freshwater

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systems in China.54-56 The highest MeHg concentration in untreated sewage was also

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found in Tibet (17 ± 1.8 ng/L), followed by the Sichuan province (14 ± 13 ng/L) and

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Shanghai city (13 ± 8.1 ng/L) (Figure 2). The MeHg concentrations in the untreated

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sewage were similar to data from other countries and previous studies in China (Table

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S2, Supporting Information).49, 57-61 The average concentration in treated sewage in

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China was 1.0 ± 0.82 ng/L. Approximately 85% of the MeHg in influent sewage was

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removed by MSTPs in China.

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In total, 160 Mg (140-190 Mg of the P20-80 confidence interval, Figure S4,

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Supporting Information) and 280 kg (240-330 kg) of THg and MeHg, respectively,

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were released from municipal sewage in 2015. As an important anthropogenic source

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that has previously been ignored,10,

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constituted 12% of the total anthropogenic THg released (including direct and

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secondary anthropogenic releases) in China.10 There is no total anthropogenic release

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data for MeHg. The substantial contribution of THg in municipal sewage in China is a

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result of the following: 1) a large amount of municipal sewage was generated in

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recent years due to the rapid increase in the urban population and improvement in

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living standards,63 and 2) high THg levels were found in untreated sewage, as

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mentioned above (Figure 2).

13

THg released from municipal sewage

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We constructed high-resolution inventories of THg and MeHg released from

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municipal sewage in China in 2015 based on the fitting models (Figure 3). The results

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show that the release of THg and MeHg was concentrated in the eastern regions of

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China, especially in the coastal regions. The Beijing-Tianjin-Hebei (North China),

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Yangtze River delta (East China), Pearl River delta (South China) and Sichuan

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province regions were among the top contributors to the THg and MeHg

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concentrations in municipal sewage (Figure 3a and b) due to their high population

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densities. This is similar to previous studies, which indicated that other anthropogenic

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emissions, such as black carbon,42 phosphorus and antibiotics, are also high in these

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regions.37, 64 The proportion of the MeHg to the THg released in the coastal regions

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(0.35%) was significantly higher than that in the inland regions (0.22%) (P < 0.05),

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which was partly due to the high rates of fish consumption in the coastal regions,

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especially in North (such as Beijing) and East China (such as Shanghai).63 The

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amount of THg released from municipal sewage was also high in Northeast China, but

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the amount of MeHg released was not. In the western regions of China, high release

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intensities of THg and MeHg were found in major urban areas such as Lanzhou in

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Gansu province.

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However, Tibet had the highest per capita release of THg and MeHg in 2015,

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followed by Shanghai and Beijing (Figure 3c and d). In Tibet, households may be the

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major contributors to the release of THg and MeHg from municipal sewage due to the

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lack of industry and business activities in this area. One explanation could be the

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intake of traditional Tibetan medicines by Tibetan inhabitants. Traditional Tibetan

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medicines, i.e., medicine commonly used by Tibetans, contain abundant quantities of

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inorganic Hg because pharmacists have intentionally added heavy metals, including

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Hg, into medicine as therapeutic ingredients for more than 1,000 years in the Tibetan

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region.65 A previous study found that the THg concentrations in medicines ranged

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from 0.37 to 15 mg/g,65 which are ten thousand times higher than the THg

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concentrations in fish. A previous study indicated that most of the inorganic Hg in the

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medicines does not accumulate in the human body.65 Therefore, the excretion of

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inorganic Hg from the human body may result in high levels of inorganic Hg in

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municipal sewage in Tibetan urban areas.65, 66 In addition, cinnabar, which is used for

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their cloths and tapestry, and gold amalgam, which is used for their religious items,

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might also contribute to the high THg concentration in Tibetan municipal sewage. In

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total, 3.5 Mg of THg was released from municipal sewage in the urban areas in the

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Tibetan region. The measurement of MeHg levels in traditional Tibetan medicine is

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still lacking. Fish consumption is low in the Tibetan region (approximately 10-fold

329

lower than the average consumption in China).63 The highest per capita release of

330

MeHg in the Tibetan region may be mainly attributed to medicine usage. Further

331

studies on the MeHg levels in traditional Tibetan medicines should be carried out.

332

THg and MeHg Material Flows from Municipal Sewage to Sinks. We

333

determined that both the THg and MeHg released from municipal sewage rapidly

334

increased from 2001 to 2015 (Figure 5b and c), which corresponded to an increase in

335

the Chinese population during this period.63 The results of the material flow analysis

336

indicate that 23 (14% of the THg released from municipal sewage), 120 (77%) and 15

337

Mg (9.4%) of THg from municipal sewage was released into aquatic environments,

338

land and the atmosphere, respectively, in 2015 in China (Figure 5a). This is different

339

from the amounts of other major pollutants, such as nonferrous smelting and

340

polyvinyl chloride production, in China, in which the atmosphere is their primary sink

341

(more than 50% of the total release).28, 29 East China was the primary contributor to

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the total THg released from the municipal sewage during this period, followed by

343

Northeast China (Figure 6a). For MeHg, 63 kg was directly released into aquatic

344

environments in China in 2015. The proportion of MeHg released to land is unclear.

345

High-resolution inventories of the THg and MeHg released into aquatic environments

346

and THg released into the land and atmosphere from municipal sewage in 2015 are

347

provided in Figure S5 to S8, respectively (Supporting Information).

348

A previous study divided the sinks for anthropogenic THg into aquatic

349

environments, land and the atmosphere in China.10 In this study, we determined that

350

the role of land as a sink for THg and possibly for MeHg is more complicated. As a

351

sink, land contains various sub-sinks, e.g., natural lands, landfills, croplands and

352

urban areas (Figure 5). Some part of the THg generated from the incineration of

353

sewage sludge will become ash and will be released into the land.31 Landfills received

354

64% of the total THg release into land in 2015. Croplands received 21% of the total

355

THg release into land in 2015, which can be absorbed by crops such as rice and can

356

directly threaten local human health.23 Previous studies also indicated that the use of

357

sewage sludge as an agricultural fertilizer can spread large amounts of THg into

358

cropland.5 A portion of the THg associated with sewage sludge was irregularly

359

dumped into natural land, but this amount was less substantial (0.67% in 2015). The

360

THg stored in landfills and building materials may be released into the environment in

361

the future.

362

In total, 15 Mg of THg was emitted from the lifecycle of municipal sewage into the

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atmosphere in China in 2015. The THg in landfills and croplands is a legacy source

364

for the atmosphere, but it is less significant (< 0.10 Mg in 2015). However, the THg

365

emission from the incineration of sewage sludge showed the highest contribution to

366

the total THg emission associated with municipal sewage. Zhang et al. indicated that

367

12 Mg of THg was emitted from municipal solid waste incineration (including sewage

368

sludge and other municipal solid waste) in 2010,67 and Tian et al. estimated 37 Mg in

369

2010.68 The disparity between the different studies can be attributed to the selection of

370

different emission factors and methods used for estimations.67 In this study, we

371

estimated THg emissions from the incineration of sewage sludge based on the THg

372

concentrations of the sewage sludges in different provinces, which better represents

373

China than the emission factor given by the UNEP.43 The THg concentrations in the

374

sewage sludge are critical in this estimation. We compared the modeling results for

375

the THg concentrations in the sewage sludges from different provinces with data from

376

previous literature (Figure S9, Supporting Information). The results show that our

377

modeling results are reasonably good.

378

We updated the inventory of anthropogenic THg released into aquatic environments

379

in China in a previous study (Figure S10, Supporting Information)20 based on the

380

municipal sewage measurements in this study. The results show that 23 Mg of THg

381

was released from municipal sewage into aquatic environments (17 Mg and 6.2 Mg

382

from untreated and treated sewage, respectively), which is a decrease from the 63 Mg

383

released in 2004 (63 Mg and 0.43 Mg, respectively). Other anthropogenic sources

384

released 88 Mg of THg in 2015, which is a decreased from 97 Mg released in 2004.

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These results can be attributed to the improvement in municipal sewage and industrial

386

wastewater management by the Chinese government.20, 44 In China, the government

387

suggested that municipal sewage and industrial wastewater should be treated in two

388

separate systems,20,

389

wastewater.31 The industrial wastewater in the municipal sewage system was not

390

double counted with other industrial releases in the THg estimation in our study.20 The

391

MeHg released from municipal sewage into aquatic environments also decreased

392

during this period (Figure 5c).

44

but municipal sewage still contains some industrial

393

As an important factor that has been previously ignored,10 the THg released into

394

land increased rapidly from 2001 to 2015. In total, 120 Mg of THg was released into

395

land in China in 2015, which is a 15-fold increase from 2001 (Figure 5b). This rapid

396

increase can be attributed to the increase in the percent of treated municipal sewage

397

(Figure S3, Supporting Information) and the high pollution removal efficiency of

398

MSPTs in China (Table S1, Supporting Information). The treatment ratio was 92% in

399

China in 2015, which increased from 18% in 2001.44 The THg released into the

400

atmosphere from the incineration of sewage sludge also increased rapidly from 2001

401

to 2015. East China contributed most of the THg emissions from this part during this

402

period (Figure 6d) since this region has the highest generation of sewage sludge and

403

the highest incineration percentage of sewage sludge (43% in 2015, while the other 7

404

regions ranged from 0% to 8.9%).

405

Implications. We constructed the first complete evaluation system for Hg released

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from municipal sewage into various sinks in China based on measurement data and

407

material flow analysis. We determined that the THg released from municipal sewage

408

into the environment, which has been previously ignored or underestimated,10, 20 is a

409

substantial part of the anthropogenic THg release in China. The THg released from

410

municipal sewage into aquatic environments decreased after 2004, but the release to

411

both land and the atmosphere increased rapidly from 2001. The total THg released

412

from municipal sewage increased from 2001, but the quantities of THg released into

413

different sinks fluctuated significantly every year. This phenomenon may also occur

414

for other anthropogenic sources of Hg in China and other countries. Zhang et al.

415

explained the observed decrease in atmospheric THg based on the decline of

416

anthropogenic emissions in recent years,69 and Streets et al. determined that the

417

release of anthropogenic THg into aquatic environments and land was increasing.9, 70

418

This means that more anthropogenic THg may be accumulating in the local food web.

419

Hui et al. indicated that anthropogenic THg emissions in China may have peaked in

420

2012,10 while our study indicated that the release of anthropogenic THg into aquatic

421

environments peaked before 2004. This means that the government should pay

422

attention to the aggravation of land contaminated by Hg, such as cases in which

423

municipal sewage has been released.

424

Based on municipal sewage, we suggest further studies on the release of Hg from

425

other anthropogenic sources into the land in China should be performed in the future.

426

For example, 3,300 Tg of industrial solid waste was generated in China in 2015, and

427

only 820 Tg of industrial and municipal solid waste was generated in 2001.63 The

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final fate of Hg in industrial solid waste is still unclear.44 More investigations on the

429

fate of industrial solid waste should be carried out to better understand the potential

430

levels of soil contamination in China.

431

We should also consider the role of anthropogenic MeHg release into aquatic

432

environments and croplands. Although the release of MeHg only accounted for 1.8%

433

of the THg released from municipal sewage, it can accumulate in local fish and crops,

434

such as rice, without long-range transport or methylation of inorganic Hg. Schartup et

435

al. discovered that freshwater discharge results in high levels of MeHg in Arctic

436

marine biota.16 In China, 97% of fish products were harvested from freshwater

437

environments and adjacent seas in 2015.71 Previous studies have indicated that rice

438

(when the fields are flooded) and poultry produced in Hg polluted areas in China can

439

accumulate a large amount of MeHg.32, 33 In some Hg-contaminated regions of China

440

such as Guizhou province, 95% of the daily MeHg intake was rice-dereved.32 There is

441

still a lack of evidence regarding the accumulation of MeHg in other crops and

442

livestock, and further studies need to be carried out. Therefore, we believe that the

443

MeHg released from municipal sewage and other terrestrial anthropogenic sources

444

may be a potential source for the increase in MeHg levels of biota in freshwater,

445

adjacent seas and soil, and mitigation measures should be taken.72 Furthermore, we

446

suggest that the MeHg content in the untreated sewage of MSPTs may be a potential

447

index of regional population exposure to MeHg, especially in underdeveloped regions,

448

such as Tibet, and these data can be used to protect MeHg-susceptible populations,

449

such as developing fetuses.

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ASSOCIATED CONTENT

451

Supporting Information

452

Additional information on the eight regions in China (Figure S1), basic municipal

453

sewage data (Figures S2 and S3), uncertainty analysis (Figure S4), distribution of Hg

454

released from municipal sewage into different environments (Figures S5 to S8), fate

455

of THg in sewage sludge (Figure S9), updates on THg released from direct

456

anthropogenic sources (Figure S10), sampling information (Table S1), and

457

comparison with previous studies (Table S2).

458

ACKONWLEDGMENTS

459

The authors would like to thank the editor, reviewers, Robert P. Mason and Zofia

460

Baumann for their insightful comments and helpful discussion on the paper. This work

461

was funded by the National Natural Science Foundation of China (41630748,

462

41571130010, 41571484, 41130535, and 41471403).

463

REFERENCES

464 465 466 467 468 469 470 471 472 473

1.

Driscoll, C. T.; Mason, R. P.; Chan, H. M.; Jacob, D. J.; Pirrone, N., Mercury as a global pollutant:

sources, pathways, and effects. Environmental science & technology 2013, 47, (10), 4967-4983. 2.

Lamborg, C. H.; Hammerschmidt, C. R.; Bowman, K. L.; Swarr, G. J.; Munson, K. M.; Ohnemus,

D. C.; Lam, P. J.; Heimbürger, L. E.; Rijkenberg, M. J.; Saito, M. A., A global ocean inventory of anthropogenic mercury based on water column measurements. Nature 2014, 512, (7512), 65-68. 3.

Lavoie, R. A.; Jardine, T. D.; Chumchal, M. M.; Kidd, K. A.; Campbell, L. M., Biomagnification

of mercury in aquatic food webs: a worldwide meta-analysis. Environmental science & technology 2013, 47, (23), 13385-13394. 4.

Mason, R. P.; Sheu, G. R., Role of the ocean in the global mercury cycle. Global biogeochemical

cycles 2002, 16, (4), 1-16.

ACS Paragon Plus Environment

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Page 23 of 36

Environmental Science & Technology

474 475 476 477 478 479 480 481 482 483 484 485 486 487 488 489 490 491 492 493 494 495 496 497 498 499 500 501 502 503 504 505 506 507 508 509 510 511 512 513 514 515 516 517

5.

Kocman, D.; Wilson, S. J.; Amos, H. M.; Telmer, K. H.; Steenhuisen, F.; Sunderland, E. M.;

Mason, R. P.; Outridge, P.; Horvat, M., Toward an Assessment of the Global Inventory of Present-Day Mercury Releases to Freshwater Environments. International Journal of Environmental Research and Public Health 2017, 14, (2), 138-154. 6.

Pirrone, N.; Cinnirella, S.; Feng, X.; Finkelman, R.; Friedli, H.; Leaner, J.; Mason, R.; Mukherjee,

A.; Stracher, G.; Streets, D., Global mercury emissions to the atmosphere from anthropogenic and natural sources. Atmospheric Chemistry and Physics 2010, 10, (13), 5951-5964. 7.

Nriagu, J. O.; Pacyna, J. M., Quantitative assessment of worldwide contamination of air, water

and soils by trace metals. nature 1988, 333, (6169), 134-139. 8.

Sundseth, K.; Pacyna, J. M.; Pacyna, E. G.; Pirrone, N.; Thorne, R. J., Global Sources and

Pathways of Mercury in the Context of Human Health. International journal of environmental research and public health 2017, 14, (1), 105-119. 9.

Streets, D. G.; Horowitz, H. M.; Jacob, D. J.; Lu, Z.; Levin, L.; Ter Schure, A. F.; Sunderland, E.

M., Total Mercury Released to the Environment by Human Activities. Environmental Science & Technology 2017, 51, (11), 5969-5977. 10. Hui, M.; Wu, Q.; Wang, S.; Liang, S.; Zhang, L.; Wang, F.; Lenzen, M.; Wang, Y.; Xu, L.; Lin, Z., Mercury flows in China and global drivers. Environmental science & technology 2016, 51, (1), 222-231. 11. Amos, H. M.; Jacob, D. J.; Kocman, D.; Horowitz, H. M.; Zhang, Y.; Dutkiewicz, S.; Horvat, M.; Corbitt, E. S.; Krabbenhoft, D. P.; Sunderland, E. M., Global biogeochemical implications of mercury discharges from rivers and sediment burial. Environmental science & technology 2014, 48, (16), 9514-9522. 12. Streets, D. G.; Hao, J.; Wu, Y.; Jiang, J.; Chan, M.; Tian, H.; Feng, X., Anthropogenic mercury emissions in China. Atmospheric Environment 2005, 39, (40), 7789-7806. 13. Wu, Y.; Wang, S.; Streets, D. G.; Hao, J.; Chan, M.; Jiang, J., Trends in anthropogenic mercury emissions in China from 1995 to 2003. Environmental science & technology 2006, 40, (17), 5312-5318. 14. Wu, Q.; Wang, S.; Li, G.; Liang, S.; Lin, C.-J.; Wang, Y.; Cai, S.; Liu, K.; Hao, J., Temporal Trend and Spatial Distribution of Speciated Atmospheric Mercury Emissions in China During 1978–2014. Environmental science & technology 2016, 50, (24), 13428-13435. 15. Pacyna, J. M.; Travnikov, O.; De Simone, F.; Hedgecock, I. M.; Sundseth, K.; Pacyna, E. G.; Steenhuisen, F.; Pirrone, N.; Munthe, J.; Kindbom, K., Current and future levels of mercury atmospheric pollution on a global scale. Atmospheric Chemistry and Physics 2016, 16, (19), 12495-12511. 16. Schartup, A. T.; Balcom, P. H.; Soerensen, A. L.; Gosnell, K. J.; Calder, R. S.; Mason, R. P.; Sunderland, E. M., Freshwater discharges drive high levels of methylmercury in Arctic marine biota. Proceedings of the National Academy of Sciences 2015, 112, (38), 11789-11794. 17. Sunderland, E. M.; Dalziel, J.; Heyes, A.; Branfireun, B. A.; Krabbenhoft, D. P.; Gobas, F. A., Response of a macrotidal estuary to changes in anthropogenic mercury loading between 1850 and 2000. Environmental science & technology 2010, 44, (5), 1698-1704. 18. Hammerschmidt, C. R.; Fitzgerald, W. F., Bioaccumulation and trophic transfer of methylmercury in Long Island Sound. Archives of Environmental Contamination and Toxicology 2006, 51, (3), 416-424. 19. Harada, M., Minamata disease: methylmercury poisoning in Japan caused by environmental

ACS Paragon Plus Environment

Environmental Science & Technology

518 519 520 521 522 523 524 525 526 527 528 529 530 531 532 533 534 535 536 537 538 539 540 541 542 543 544 545 546 547 548 549 550 551 552 553 554 555 556 557 558 559 560 561

pollution. Critical reviews in toxicology 1995, 25, (1), 1-24. 20. Liu, M.; Zhang, W.; Wang, X.; Chen, L.; Wang, H.; Luo, Y.; Zhang, H.; Shen, H.; Tong, Y.; Ou, L., Mercury Release to Aquatic Environments from Anthropogenic Sources in China from 2001 to 2012. Environmental Science & Technology 2016, 50, (15), 8169-8177. 21. Cheng, H.; Hu, Y., Mercury in municipal solid waste in China and its control: a review. Environmental science & technology 2011, 46, (2), 593-605. 22. Feng, X.; Li, P.; Qiu, G.; Wang, S.; Li, G.; Shang, L.; Meng, B.; Jiang, H.; Bai, W.; Li, Z., Human exposure to methylmercury through rice intake in mercury mining areas, guizhou province, china. Environmental science & technology 2007, 42, (1), 326-332. 23. Chaudri, A. M.; Allain, C. M.; Badawy, S.; Adams, M. L.; McGrath, S. P.; Chambers, B. J., Cadmium content of wheat grain from a long-term field experiment with sewage sludge. Journal of environmental quality 2001, 30, (5), 1575-1580. 24. Liu, R.; Lin, Y.; Hu, F.; Liu, R.; Ruan, T.; Jiang, G., Observation of emerging photoinitiator additives in household environment and sewage sludge in China. Environmental science & technology 2015, 50, (1), 97-104. 25. Meng, X.; Venkatesan, A. K.; Ni, Y.; Steele, J. C.; Wu, L.; Bignert, A.; Bergman, Å.; Halden, R. U., Organic contaminants in Chinese sewage sludge: a meta-analysis of the literature of the past 30 years. Environmental science & technology 2016, 50, (11), 5454-5466. 26. Zeng, L.; Li, H.; Wang, T.; Gao, Y.; Xiao, K.; Du, Y.; Wang, Y.; Jiang, G., Behavior, fate, and mass loading of short chain chlorinated paraffins in an advanced municipal sewage treatment plant. Environmental science & technology 2013, 47, (2), 732-740. 27. Wang, S.; Zhang, L.; Li, G.; Wu, Y.; Hao, J.; Pirrone, N.; Sprovieri, F.; Ancora, M., Mercury emission and speciation of coal-fired power plants in China. Atmospheric Chemistry and Physics 2010, 10, (3), 1183-1192. 28. Wu, Q.; Wang, S.; Hui, M.; Wang, F.; Zhang, L.; Duan, L.; Luo, Y., New insight into atmospheric mercury emissions from zinc smelters using mass flow analysis. Environmental science & technology 2015, 49, (6), 3532-3539. 29. Ren, W.; Duan, L.; Zhu, Z.; Du, W.; An, Z.; Xu, L.; Zhang, C.; Zhuo, Y.; Chen, C., Mercury transformation and distribution across a polyvinyl chloride (PVC) production line in China. Environmental science & technology 2014, 48, (4), 2321-2327. 30. Lin, Y.; Wang, S.; Wu, Q.; Larssen, T., Material flow for the intentional use of mercury in China. Environmental science & technology 2016, 50, (5), 2337-2344. 31. NBS, China Environment Yearbook. National Bureau of Statistics (NBS): Beijing, China, 2002-2016. 32. Zhang, H.; Feng, X.; Larssen, T.; Qiu, G.; Vogt, R. D., In inland China, rice, rather than fish, is the major pathway for methylmercury exposure. Environmental Health Perspectives 2010, 118, (9), 1183-1188. 33. Yin, R.; Wei, Z.; Sun, G.; Feng, Z.; Hurley, J. P.; Yang, L.; Shang, L.; Feng, X., Mercury risk in poultry in the Wanshan Mercury Mine, China. Environmental Pollution 2017, 230, 810-816. 34. Gibbs, P.; Miskiewicz, A., Heavy metals in fish near a major primary treatment sewage plant outfall. Marine pollution bulletin 1995, 30, (10), 667-674. 35. Hicks, K. A.; Fuzzen, M. L.; McCann, E. K.; Arlos, M. J.; Bragg, L. M.; Kleywegt, S.; Tetreault, G. R.; McMaster, M. E.; Servos, M. R., Reduction of intersex in a wild fish population in response to major municipal wastewater treatment plant upgrades. Environmental science & technology 2017, 51,

ACS Paragon Plus Environment

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Page 25 of 36

Environmental Science & Technology

562 563 564 565 566 567 568 569 570 571 572 573 574 575 576 577 578 579 580 581 582 583 584 585 586 587 588 589 590 591 592 593 594 595 596 597 598 599 600 601 602 603 604 605

(3), 1811-1819. 36. Du, P.; Li, K.; Li, J.; Xu, Z.; Fu, X.; Yang, J.; Zhang, H.; Li, X., Methamphetamine and ketamine use in major Chinese cities, a nationwide reconnaissance through sewage-based epidemiology. Water research 2015, 84, 76-84. 37. Zhang, Q.; Ying, G.; Pan, C.; Liu, Y.; Zhao, J., Comprehensive evaluation of antibiotics emission and fate in the river basins of China: source analysis, multimedia modeling, and linkage to bacterial resistance. Environmental science & technology 2015, 49, (11), 6772-6782. 38. Emmerton, C. A.; Graydon, J. A.; Gareis, J. A.; St. Louis, V. L.; Lesack, L. F.; Banack, J. K.; Hicks, F.; Nafziger, J., Mercury export to the Arctic Ocean from the Mackenzie River, Canada. Environmental science & technology 2013, 47, (14), 7644-7654. 39. Buck, C. S.; Hammerschmidt, C. R.; Bowman, K. L.; Gill, G. A.; Landing, W. M., Flux of Total Mercury and Methylmercury to the Northern Gulf of Mexico from US Estuaries. Environmental science & technology 2015, 49, (24), 13992-13999. 40. Hammerschmidt, C. R.; Fitzgerald, W. F.; Lamborg, C. H.; Balcom, P. H.; Tseng, C.-M., Biogeochemical cycling of methylmercury in lakes and tundra watersheds of Arctic Alaska. Environmental science & technology 2006, 40, (4), 1204-1211. 41. Shen, H.; Tao, S.; Chen, Y.; Ciais, P.; Güneralp, B.; Ru, M.; Zhong, Q.; Yun, X.; Zhu, X.; Huang, T., Urbanization-induced population migration has reduced ambient PM2. 5 concentrations in China. Science Advances 2017, 3, (7), e1700300. 42. Wang, R.; Tao, S.; Wang, W.; Liu, J.; Shen, H.; Shen, G.; Wang, B.; Liu, X.; Li, W.; Huang, Y., Black carbon emissions in China from 1949 to 2050. Environmental science & technology 2012, 46, (14), 7595-7603. 43. AMAP/UNEP, Technical Background Report for the Global Mercury Assessment 2013. Arctic Monitoring and Assessment Programme 2013. 44. NBS, China Environmental Statistical Yearbook. National Bureau of Statistics (NBS): Beijing, China, 2002-2016. 45. Allesch, A.; Brunner, P. H., Material Flow Analysis as a Tool to improve Waste Management Systems: The Case of Austria. Environmental science & technology 2016, 51, (1), 540-551. 46. Brunner, P. H.; Rechberger, H., Handbook of Material Flow Analysis: For Environmental, Resource, and Waste Engineers, Second Edition. In CRC Press, Taylor & Francis Group: 2016. 47. Lindberg, S.; Price, J., Airborne emissions of mercury from municipal landfill operations: a short-term measurement study in Florida. Journal of the Air & Waste Management Association 1999, 49, (5), 520-532. 48. Balogh, S.; Liang, L., Mercury pathways in municipal wastewater treatment plants. Water, Air, and Soil Pollution 1995, 80, (1-4), 1181-1190. 49. Balogh, S. J.; Nollet, Y. H., Mercury mass balance at a wastewater treatment plant employing sludge incineration with offgas mercury control. Science of the total environment 2008, 389, (1), 125-131. 50. Duan, Y.; Zhao, C.; Wang, Y.; Wu, C., Mercury emission from co-combustion of coal and sludge in a circulating fluidized-bed incinerator. Energy & Fuels 2009, 24, (1), 220-224. 51. Hu, D.; Zhang, W.; Chen, L.; Chen, C.; Ou, L.; Tong, Y.; Wei, W.; Long, W.; Wang, X., Mercury emissions from waste combustion in China from 2004 to 2010. Atmospheric environment 2012, 62, 359-366. 52. McInnes, G., Atmospheric Emission Inventory Guidebook: A Joint EMEP/CORINAIR Production.

ACS Paragon Plus Environment

Environmental Science & Technology

606 607 608 609 610 611 612 613 614 615 616 617 618 619 620 621 622 623 624 625 626 627 628 629 630 631 632 633 634 635 636 637 638 639 640 641 642 643 644 645 646 647 648 649

European Environment Agency: 1996. 53. Liu, M.; Chen, L.; Wang, X.; Zhang, W.; Tong, Y.; Ou, L.; Xie, H.; Shen, H.; Ye, X.; Deng, C., Mercury Export from Mainland China to Adjacent Seas and Its Influence on the Marine Mercury Balance. Environmental science & technology 2016, 50, (12), 6224-6232. 54. Wang, S.; Xing, D.; Wei, Z.; Jia, Y., Spatial and seasonal variations in soil and river water mercury in a boreal forest, Changbai Mountain, Northeastern China. Geoderma 2013, 206, 123-132. 55. Liu, J.; Feng, X.; Zhu, W.; Zhang, X.; Yin, R., Spatial distribution and speciation of mercury and methyl mercury in the surface water of East River (Dongjiang) tributary of Pearl River Delta, South China. Environmental Science and Pollution Research 2012, 19, (1), 105-112. 56. Zheng, W.; Kang, S.; Feng, X.; Zhang, Q.; Li, C., Mercury speciation and spatial distribution in surface waters of the Yarlung Zangbo River, Tibet. Chinese Science Bulletin 2010, 55, (24), 2697-2703. 57. Gbondo-Tugbawa, S. S.; McAlear, J. A.; Driscoll, C. T.; Sharpe, C. W., Total and methyl mercury transformations and mass loadings within a wastewater treatment plant and the impact of the effluent discharge to an alkaline hypereutrophic lake. Water research 2010, 44, (9), 2863-2875. 58. Bodaly, R. D.; Rudd, W.; Flett, R. J., Effect of urban sewage treatment on total and methyl mercury concentrations in effluents. Biogeochemistry 1998, 40, (2-3), 279-291. 59. da Silva Oliveira, A.; Bocio, A.; Trevilato, T. M. B.; Takayanagui, A. M. M.; Domingo, J. L.; Segura-Muñoz, S. I., Heavy metals in untreated/treated urban effluent and sludge from a biological wastewater treatment plant. Environmental Science and Pollution Research-International 2007, 14, (7), 483-489. 60. Mao, Y.; Cheng, L.; Ma, B.; Cai, Y., The fate of mercury in municipal wastewater treatment plants in China: significance and implications for environmental cycling. Journal of hazardous materials 2016, 306, 1-7. 61. Zhao, J.; Jiang, Y.; Yan, B.; Wei, C.; Zhang, L.; Ying, G., Multispecies acute toxicity evaluation of wastewaters from different treatment stages in a coking wastewater‐treatment plant. Environmental toxicology and chemistry 2014, 33, (9), 1967-1975. 62. Zhao, H.; Li, X.; Wang, X.; Tian, D., Grain size distribution of road-deposited sediment and its contribution to heavy metal pollution in urban runoff in Beijing, China. Journal of Hazardous Materials 2010, 183, (1), 203-210. 63. NBS, China Statistical Yearbook. National Bureau of Statistics (NBS): Beijing, China, 2002-2016. 64. Liu, X.; Sheng, H.; Jiang, S.; Yuan, Z.; Zhang, C.; Elser, J. J., Intensification of phosphorus cycling in China since the 1600s. Proceedings of the National Academy of Sciences 2016, 113, (10), 2609-2614. 65. Sallon, S.; Dory, Y.; Barghouthy, Y.; Tamdin, T.; Sangmo, R.; Tashi, J.; Yangdon, S.; Yeshi, T.; Sadutshang, T.; Rotenberg, M., Is mercury in Tibetan Medicine toxic? Clinical, neurocognitive and biochemical results of an initial cross-sectional study. Experimental Biology and Medicine 2017, 242, (3), 316-332. 66. Ernst, E.; Coon, J. T., Heavy metals in traditional Chinese medicines: a systematic review. Clinical Pharmacology & Therapeutics 2001, 70, (6), 497-504. 67. Zhang, L.; Wang, S.; Wang, L.; Wu, Y.; Duan, L.; Wu, Q.; Wang, F.; Yang, M.; Yang, H.; Hao, J., Updated emission inventories for speciated atmospheric mercury from anthropogenic sources in China. Environmental science & technology 2015, 49, (5), 3185-3194. 68. Tian, H.; Gao, J.; Lu, L.; Zhao, D.; Cheng, K.; Qiu, P., Temporal trends and spatial variation

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Environmental Science & Technology

650 651 652 653 654 655 656 657 658 659 660 661 662 663

characteristics of hazardous air pollutant emission inventory from municipal solid waste incineration in China. Environmental science & technology 2012, 46, (18), 10364-10371. 69. Zhang, Y.; Jacob, D. J.; Horowitz, H. M.; Chen, L.; Amos, H. M.; Krabbenhoft, D. P.; Slemr, F.; Louis, V. L. S.; Sunderland, E. M., Observed decrease in atmospheric mercury explained by global decline in anthropogenic emissions. Proceedings of the National Academy of Sciences 2016, 113, (3), 526-531. 70. Streets, D. G.; Lu, Z.; Levin, L.; ter Schure, A. F.; Sunderland, E. M., Historical releases of mercury to air, land, and water from coal combustion. Science of The Total Environment 2018, 615, 131-140. 71. CMA, China Fisheries Statistical Yearbook. China Ministry of Agriculture (CMA): Beijing, China, 2016. 72. Jonsson, S.; Skyllberg, U.; Nilsson, M. B.; Lundberg, E.; Andersson, A.; Björn, E., Differentiated availability of geochemical mercury pools controls methylmercury levels in estuarine sediment and biota. Nature Communications 2014, 5, (5), 4624-4633.

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Figure 1. Locations of the municipal sewage treatment plants selected for this study. The

666

black line is the Chinese geographic “Hu Huanyong Line” (reflects the different levels of

667

human activities in different regions in China). The information on the distribution of the

668

Chinese population is from the census information for each region (http://data.cnki.net/).

669

The South China Sea is not included in the map.

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Figure 2. THg (a) and MeHg (b) concentrations in the influent (untreated) and effluent

671

(treated) sewage of municipal sewage treatment plants in different provinces in China. It

672

should be noted that the scales for the influent and effluent for both THg and MeHg

673

concentrations are different, since the effluent is significantly smaller than the influent.

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Figure 3. The relationship between amount of THg and MeHg and the population

675

distribution in China. a is the relationship of the THg concentrations between the sewage

676

influent (untreated) and effluent (treated); b is the relationship of the MeHg concentrations

677

between the sewage influent (untreated) and effluent (treated); c and d are the

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relationships of the THg and MeHg released with respect to the population distribution,

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respectively. Shaded areas in the figures are the 95% confidence intervals.

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Figure 4. Distributions of THg and MeHg released from municipal sewage in China in

681

2015. a and b are the release of THg and MeHg, respectively; c and d are the contribution

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per capita of THg and MeHg in the different provinces, respectively.

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Figure 5. THg and MeHg material flow analyses of municipal sewage from the source to

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various sinks in China. a is the material flow analyses in 2015; b and c are the

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Environmental Science & Technology

685

uncertainties of the THg and MeHg released from municipal sewage from 2001 to 2015,

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respectively; d and e are the trends of THg and MeHg received by different sinks from

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2001 to 2015, respectively. In figure a, brown is the source, green is the temporary

688

storage and blue is the sink. Urban areas can also be sinks in this study.

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Figure 6. Trends in the release of THg from municipal sewage into aquatic environments,

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land and the atmosphere in different regions of China from 2001 to 2015. Details for

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different regions and land sub-sinks in different regions are provided in Figure S1 and S9

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(Supporting Information), respectively.

ACS Paragon Plus Environment

Environmental Science & Technology

THg

THg (Mg/yr)

80% 50% 20%

Urban

?

17

?

15

Decreasing

0 2001

2015

63

80% 50% 20%

Water

?

Municipal sewage

MeHg 23

MeHg (kg/yr)

280

Increasing 0 360

160

MeHg (kg/yr)

110

THg (Mg/yr)

210

Land

Air

Year

Abstract Art

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Environmental Science & Technology

± Heilongjiang

40°0'0"N

Jilin

Beijing Xinjiang

Liaoning

Hebei Gansu

Inner Mongolia

Tianjin

Shanxi Ningxia Shandong

Qinghai 30°0'0"N

Jiangsu

Henan

Shannxi

Tibet

Shanghai Anhui Hubei

Chongqing

Zhejiang

Sichuan Jiangxi Hunan

Fujian

Guizhou Sample size

Taiwan 20°0'0"N

1

3

Yunnan

>5

Guangxi

Guangdong

Unit: population/km2

0

600 90°0'0"E

>1200 100°0'0"E

Figure 1

ACS Paragon Plus Environment

Hainan 110°0'0"E

0

500

1,000 Kilometers 120°0'0"E

Environmental Science & Technology

a

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b Heilongjiang Beijing Tianjin

Beijing Tianjin

Liaoning Heilongjiang

Liaoning

Gansu

Shanxi

Henan

Influent (μg/L)

1

0

0

THg

Effluent (μg/L)

Sichuan Hubei Chongqing

10

Hunan Yunnan

Jiangsu Shannxi

Shanghai

Tibet

20 Fujian

Guangxi Guangdong

Henan

Shanghai

Sichuan Hubei Chongqing

Zhejiang

10

0

0

MeHg

Figure 2

ACS Paragon Plus Environment

Effluent (ng/L)

Shannxi

Shandong

Qinghai

Jiangsu

Tibet

Hebei

Ningxia

Shanxi

Shandong

Influent (ng/L)

Qinghai

Gansu

Hebei

Ningxia

Zhejiang

Hunan Fujian Yunnan

Guangxi Guangdong

2 a. P6.4

Environmental Science & Technology

a

Urban

210

17(?)

River

160 (280)

12(18)

Municipal sewage

Industry

THg release (Mg/yr)

THg (MeHg) flow Unit: Mg/yr (kg/yr)

150 (260)

140

50% 20%

70

70

0 2001

20% 120

120

0 2001

Landscape

Building material

River Lake Ocean Landfill

48

Cropland Incineration Dumping

24

Building material Reuse

26(?)

16(?)

0

2015 Year

d

140 (220)

Sewage sludge

240

50%

72

Sewage treatment plant

Ocean

0

2015

80% 240

Year

THg release (Mg/yr)

Lake

360

c 80%

140

Municipal services 0.74 (4.3)

360

210

b MeHg release (kg/yr)

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Emission

0 120

Incineration

15(?)

23(63) Aquatic environment

Land

Atmosphere

MeHg release (kg/yr)

Cropland

26(?)

Landfill

0.82(?)

e

80

River Lake Ocean

40

Reuse

0 2001

Figure 5

ACS Paragon Plus Environment

2008 Year

2015

Environmental Science & Technology

THg release (Mg/yr)

60

40

16

20

8

0

0

48

THg release (Mg/yr)

24

Total release

12

Land

32

8

16

4

0 2001

2008 Year

2015

Aquatic environment

Atmosphere

0 2001

2008 Year

2015

North

Northeast

East

Central

South

Southwest

Northwest

Tibetan Region

Figure 6

ACS Paragon Plus Environment

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