ARSENIC IN GEOSPHERE AND HUMAN DISEASES FFMM..iinndddd ii 44//11//22001100 1100::2233::5599 AAMM Arsenic in the Environment – Proceedings Series Editors Jochen Bundschuh Institute of Applied Research, Karlsruhe University of Applied Sciences, Karlsruhe, Germany Royal Institute of Technology (KTH), Stockholm, Sweden Department of Earth Sciences, National Cheng Kung University, Tainan, Taiwan Prosun Bhattacharya KTH-International Groundwater Arsenic Research Group, Department of Land and Water Resources Engineering, Royal Institute of Technology (KTH), Stockholm, Sweden ISSN: Applied for FFMM..iinndddd iiii 44//11//22001100 1100::2244::0000 AAMM 3RD INTERNATIONAL CONGRESS: ARSENIC IN THE ENVIRONMENT, NATIONAL CHENG KUNG UNIVERSITY (NCKU), TAINAN, TAIWAN, 17–21 MAY 2010 Arsenic in Geosphere and Human Diseases As 2010 Editors Jiin-Shuh Jean Department of Earth Sciences, National Cheng Kung University, Tainan City 701, Taiwan Jochen Bundschuh Institute of Applied Research, Karlsruhe University of Applied Sciences, Karlsruhe, Germany Royal Institute of Technology (KTH), Stockholm, Sweden Department of Earth Sciences, National Cheng Kung University, Tainan, Taiwan Prosun Bhattacharya KTH-International Groundwater Arsenic Research Group, Department of Land and Water Resources Engineering, Royal Institute of Technology (KTH), Stockholm, Sweden FFMM..iinndddd iiiiii 44//11//22001100 1100::2244::0000 AAMM Cover photo The cover photo shows Chukou area in southwestern Taiwan, with the arsenic-enriched Chukou black shale outcrops in the upstream part of Pachang river. These arsenic-enriched black shales are eroded and transported by the river to the coastal plain where they are deposited as sediments forming the Chianan plain aquifer system. Arsenic is mobilized from the aquifer sediments into the groundwater and contrib- utes to the high concentrations of dissolved arsenic, which is a major factor that has caused the endemic blackfoot disease in southwestern Taiwan during the 1950s. The region is supplied with piped arsenic-safe surface water since the 1970s that reduced the the prevalence of the blackfoot disease in the region. CRC Press/Balkema is an imprint of the Taylor & Francis Group, an informa business © 2010 Taylor & Francis Group, London, UK Typeset by Vikatan Publishing Solutions (P) Ltd., Chennai, India Printed and bound in Great Britain by Antony Rowe (a CPI Group Company), Chippenham, Wiltshire All rights reserved. No part of this publication or the information contained herein may be reproduced, stored in a retrieval system, or transmitted in any form or by any means, electronic, mechanical, by pho- tocopying, recording or otherwise, without written prior permission from the publisher. Although all care is taken to ensure integrity and the quality of this publication and the information herein, no responsibility is assumed by the publishers nor the author for any damage to the property or persons as a result of operation or use of this publication and/or the information contained herein. Published by: CRC Press/Balkema P.O. Box 447, 2300 AK Leiden, The Netherlands e-mail: [email protected] www.crcpress.com – www.taylorandfrancis.co.uk – www.balkema.nl ISBN: 978-0-415-57898-1 (Hbk) ISBN: 978-0-203-84531-8 (eBook) FFMM..iinndddd iivv 44//11//22001100 1100::2244::0000 AAMM Arsenic in Geosphere and Human Diseases – Jean, Bundschuh & Bhattacharya (eds) © 2010 Taylor & Francis Group, London, ISBN 978-0-415-57898-1 About the book series Although arsenic has been known as a ‘silent toxin’ since ancient times, and the contamination of drinking water resources by geogenic arsenic was described in different locations around the world long ago— e.g. in Argentina in 1917—it was only two decades ago that it received overwhelming worldwide public attention. As a consequence of the biggest arsenic calamity in the world, which was detected more than twenty years back in West Bengal, India and other parts of Southeast Asia, there has been an exponential rise in scientific interest that has triggered high quality research. Since then, arsenic contamination (predominantly of geogenic origin) of drinking water resources, soils, plants and air, the propagation of arsenic in the food chain, the chronic affects of arsenic ingestion by humans, and their toxicological and related public health consequences, have been described in many parts of the world, and every year, even more new countries or regions are discovered to have arsenic problems. Arsenic is found as a drinking water contaminant, in many regions all around the world, in both devel- oping as well as industrialized countries. However, addressing the problem requires different approaches which take into account, the differential economic and social conditions in both country groups. It has been estimated that 200 million people worldwide are at risk from drinking water containing high concen- trations of As, a number which is expected to further increase due to the recent lowering of the limits of arsenic concentration in drinking water to 10 μg/L, which has already been adopted by many countries, and some authorities are even considering decreasing this value further. The book series Arsenic in the Environment – Proceedings provides together with the book series Arsenic in the Environment an inter- and multidisciplinary source of information, making an effort to link the occurrence of geogenic arsenic in different environments and the potential contamination of ground- and surface water, soil and air and their effect on the human society. The series fulfills the growing interest in the worldwide arsenic issue, which is being accompanied by stronger regulations on the permissible Maximum Contaminant Levels (MCL) of arsenic in drinking water and food, which are being adopted not only by the industrialized countries, but increasingly by developing countries. Consequently, we see the book series Arsenic in the Environment – Proceedings with the outcomes of the international congress series Arsenic in the Environment, which we organize biannually in different parts of the world, as a regular update on the latest developments of arsenic research. It is further a platform to present the results from other international or regional congresses or other scientific events. This Pro- ceedings series acts as an ideal complement to the books of the series Arsenic in the Environment, which includes authored or edited books from world-leading scientists on their specific field of arsenic research, giving a comprehensive information base. Supported by a strong multi-disciplinary editorial board, book proposals and manuscripts are peer reviewed and evaluated. Both of the two series will be open for any person, scientific association, society or scientific network, for the submission of new book projects. We have an ambition to establish an international, multi- and interdisciplinary source of knowledge and a platform for arsenic research oriented to the direct solution of problems with considerable social impact and relevance rather than simply focusing on cutting edge and breakthrough research in physical, chemical, toxicological and medical sciences. It shall form a consolidated source of information on the worldwide occurrences of arsenic, which otherwise is dispersed and often hard to access. It will also have a role in increasing the awareness and knowledge of the arsenic problem among administrators, policy makers and company executives and improving international and bilateral cooperation on arsenic con- tamination and its effects. Both of the book series cover all fields of research concerning arsenic in the environment and aims to present an integrated approach from its occurrence in rocks and mobilization into the ground- and sur- face water, soil and air, its transport therein, and the pathways of arsenic introduction into the food chain including uptake by humans. Human arsenic exposure, arsenic bioavailability, metabolism and toxicology are treated together with related public health effects and risk assessments in order to better manage the contaminated land and aquatic environments and to reduce human arsenic exposure. Arsenic removal v FFMM..iinndddd vv 44//11//22001100 1100::2244::0011 AAMM technologies and other methodologies to mitigate the arsenic problem are addressed not only from the technological perspective, but also from an economic and social point of view. Only such inter- and multi- disciplinary approaches will allow a case-specific selection of optimal mitigation measures for each spe- cific arsenic problem and provide the local population with arsenic-safe drinking water, food, and air. Jochen Bundschuh Prosun Bhattacharya (Series Editors) vi FFMM..iinndddd vvii 44//11//22001100 1100::2244::0011 AAMM Arsenic in Geosphere and Human Diseases – Jean, Bundschuh & Bhattacharya (eds) © 2010 Taylor & Francis Group, London, ISBN 978-0-415-57898-1 Dedication We dedicate this proceedings book to the people from southwestern Taiwan, who have suffered from the endemic Blackfoot Disease for several decades before the problem of arsenic in drinking water was solved. We also dedicate it to the residents in the arsenic-affected region in Taiwan, who supported our scientific inves- tigations related to arsenic by permitting us to collect samples of groundwater, sediments, soils, fish, etc. We hope that their suffering has risen the awareness of the responsible authorities and the scientific community elsewhere in the world where over 200 million people still suffer from the arsenic problem. We also dedicate it to Dr. Kim-Ho Wang for setting up the Taiwan Blackfoot Disease Museum in Tainan in 2008. This museum has contributed to an improved understanding of the history and treatment of Blackfoot Disease in Taiwan. vii FFMM..iinndddd vviiii 44//11//22001100 1100::2244::0011 AAMM Arsenic in Geosphere and Human Diseases – Jean, Bundschuh & Bhattacharya (eds) © 2010 Taylor & Francis Group, London, ISBN 978-0-415-57898-1 Table of contents About the book series v Dedication vii Foreword (President, KTH) xxv Foreword (President, HsKA) xxvii Foreword (President, NCKU) xxix Organizers xxxi Scientific committee xxxiii Editors’ foreword xxxv List of contributors xxxvii Section I: Geology, hydrology, and hydrogeology of arsenic I.1 Geogenic and anthropogenic sources of arsenic Occurrences of arsenic and fluoride in groundwater – A global overview 3 A.B. Mukherjee, P. Bhattacharya, G. Jacks & J. Bundschuh Sedimentological, climatic, and tectonic, controls on arsenic pollution of groundwater 6 J.M. McArthur Geogenic and anthropogenic sources of arsenic in North Portugal 8 M. Inácio, L. Pinto, V. Pereira & E. Ferreira da Silva Arsenic in bedrock aquifers in the greater Augusta area, Maine, USA 11 Q. Yang, H.-B. Jung, C. Culbertson, M. Nielson, C. Schalk, C. Johnson, R. Marvinney, M. Loiselle, D. Locke, H. Cheek, H. Thibodeau, B. O’Shea, M. Stute & Y. Zheng Arsenic contaminated groundwater from parts of Middle Ganga Plain, Uttar Pradesh, India 14 B.A. Shah Groundwater arsenic contamination in Ganga basin of Bihar, India 16 D.S. Mishra High arsenic levels in water resources resulting from alteration zones: A case study from Biga Peninsula, Turkey 18 A. Baba Groundwater arsenic in the Holocene Brahmaputra floodplains of Assam, Northeastern India: Distribution and trends of hydrogeochemical variations 21 C. Mahanta, P. Bhattacharya, R. Thunvik, G. Jacks, O. Sracek, R.T. Nickson, G. Enmark, D. Norborg & R. Herbert ix FFMM..iinndddd iixx 44//11//22001100 1100::2244::0011 AAMM Hydrogeochemistry of the alluvial aquifers of the central Gangetic Plain in India: Constraints on source and mobility of arsenic 23 AL. Ramanathan, P. Tripathi, R. Ranjan, Manish Kumar, P. Bhattacharya, K. Elfverson, R. Thunvik, G. Jacks, O. Sracek, J. Bundschuh & M. Tsujimura Distribution characteristics of high-fluoride and high-arsenic groundwater and countermeasures in Huzhou area of Zhejiang Province 26 Y. Jiang, X. Zhou, J. Jia, Q. Zhou, Yunfeng Li & Yun Li Arsenic contamination in the sediments of the Daliao river system in China 28 C. Lin, M.C. He & S.L. Wang Arsenic enrichment and sources in surface water and soil in Yarlung Tsangpo and Singe Tsangpo drainages in Tibet 31 S.H. Li, M.G. Wang, B.S. Zheng, Q. Yang & Y. Zheng Analysis of spatial variability of arsenic concentration in spring waters in Central Iberian Zone (Province of Ávila, Spain) using principal component analysis and geostatistical tools 33 E. Giménez-Forcada, C. Guardiola-Albert & I. Iribarren-Campaña Arsenic contamination in groundwater of An Giang and Dong Thap provinces in Vietnam 36 S. Bang, T.H. Hoang, K.-W. Kim & M.H. Nguyen Temporal variation of groundwater arsenic in shallow groundwater from the Hetao Basin, Inner Mongolia 38 H. Guo, B. Zhang, X. Tang, Yuan Li, Suzhen Yang & D. Chen Geothermal arsenic 41 D.K. Nordstrom Arsenic contamination in groundwater of Bangladesh 44 H.M. Anawar, J. Akai & M. Mihaljevič Arsenic in groundwater in northern Sweden 46 M. Svensson, M. von Brömssen, P. Bhattacharya & G. Jacks Groundwater contamination by arsenic in Datong Basin, China 48 A. Ding, L. Cheng, S. Yang, H. Zhang, D. Li, J. Zhou & J. Wang Arsenic distributions in rivers around the world largest antimony mine of Xikuangshan in Hunan province of China 50 Xiangqin Wang, M.C. He, X. Lu & J. Xi Distribution of arsenic in sediment from San Juan River basin in Nuevo Leon, Mexico 52 L. Sandoval & J.M. Alfaro I.2 Total arsenic and arsenic speciation The role of common metal contaminants on arsenic speciation in soils and on common soil minerals 55 M. Gräfe, E. Smith, D.A. Beattie & D.L. Sparks Redox zoning in arsenic-rich groundwater, West Bengal, India 59 A. Biswas, D. Chatterjee, S. Majumder, Z. Berner & H. Neidhardt Arsenic mobilization in shallow alluvial aquifers of Chapai-Nawabganj District, Northwestern Bangladesh 61 A.H.M.S. Reza, J.-S. Jean, H.-J. Yang, C.-C. Liu, S.-D. Luo, M.-K. Lee & J.-F. Lee Arsenic species in the high arsenic groundwater of Shanxi, China 64 Z. Chen, J.-H. Liang & Y.-G. Zhu x FFMM..iinndddd xx 44//11//22001100 1100::2244::0011 AAMM
Description: