DOCSLIB.ORG

Mine Tailings Restoration Method Uses High Grade Biosolids to Revegetate Land by Susan Mcginley

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Mine Tailings Restoration Method Uses High Grade Biosolids to Revegetate Land by Susan Mcginley Mine Tailings Restoration Method uses high grade biosolids to revegetate land By Susan McGinley ine tailings and biosolids don’t sound like they go together, Mbut combining the two in the proper ratio actually produces a medium that can support living plants. (The prod- uct of wastewater treatment of sewage is known as biosolids.) Ongoing research conducted through the University of Ari- zona, National Science Foundation Wa- ter Quality Center (W-Q-C) offers a so- lution for covering unsightly bare mine tailing piles while at the same time dis- posing of sewage sludge without affect- ing groundwater quality. Tests con- ducted at commercial sites in southern Arizona show that the remediation method does not release heavy metals or excess nitrogen into the soil. I. Pepper I. Mine tailings, the waste material left over from processing ore, are essentially tons of crushed Mine tailings unamended. rock with zero percent Why mix mine tailings with biosolids In cooperation with ASARCO and way beyond that percentage at these in the first place? Because each has Pima County Wastewater Management sites.” The biosolids proved to be ben- what the other lacks. Mine tailings, the Department and with the approval of eficial in adding essential plant nutri- waste material left over from process- the Arizona Department of Environ- ents, amending the soil with organic ing ore, are essentially tons of crushed mental Quality, Pepper and soil scien- matter, and enhancing soil microbial rock with zero percent organic matter. tist Ed Glenn began their research at the populations. The resulting vegetation Deposited in ten-foot “lifts,” they are Mission Mine in Green Valley in De- stabilized the mine tailings and re- extruded like a thick toothpaste that cember 1998. Biosolids were added at duced wind erosion. dries out, according to Ian Pepper, di- the rate of 80 dry tons per acre to a 3.75- “This is important, because the raw rector of the W-Q-C. Thousands of acre site that was seeded initially with tailings are very prone to air pollution these raised, barren piles dot the South- native Southwest grasses. The area was from dust,” Pepper says. Although he west. monitored for plant growth and for the was pleased with these benefits, Pep- “Nothing grows on them; they look presence of nitrates and metals. In De- per admits he was concerned that the like the surface of the moon,” he says. cember 2000 the first biosolid amend- tremendous amount of organic nitro- “We wondered if we could take ment was added to a 20-acre site, also gen going into the ground from the biosolids that are primarily all organic at the Mission Mine, as a real-time dis- biosolids could cause seasonal nitrate materials and add them to mine tail- posal from a wastewater treatment nitrogen (a pollutant) buildup in the ings — the perfect inorganic matrix — plant in Pima County. Approximately groundwater. During the monsoons the to make an instant ‘soil.’ The answer is 150 dry tons per acre were applied to moisture causes mineralization and yes, you can. As soon as you add the that site, then seeded and monitored. rapid nitrification of nitrogen, particu- biosolids to the mine tailings, the mi- Neither site was irrigated, yet today, larly in surface soil. Yet the research- crobial population jumps from 400 per grasses and shrubs cover the once stark ers found the nitrates didn’t leach, es- gram in the tailings to about 10⁷ or 10⁸ landscape. pecially during the cooler winter million per gram in the created soil. “Given the statistics, natural indig- months. This microbial population is a prereq- enous Sonoran Desert is only about 20 “Heterotrophic bacteria feed on some uisite for growth.” percent cover,” Pepper notes. “We go of this. We speculate that massive 18 The University of Arizona College of Agriculture and Life Sciences The Water Quality Center The University of Arizona, Na- tional Science Foundation Water Quality Center (W-Q-C) investi- gates physical, chemical and micro- bial processes that affect the qual- ity of surface and subsurface wa- ters including potable supplies. Housed in the UA College of Agri- culture and Life Sciences Environ- mental Research Laboratory in Tuc- son, the center includes an inter- disciplinary group of biologists, chemists, physicists, hydrologists, and engineers who work together to resolve water quality problems. Undergraduate and graduate stu- I. Pepper I. dents also participate in conduct- ing research, publishing and present- Mine tailings three years after biosolids amendment. ing papers, and thus gain broad in- dustry perspective and industrial job opportunities. Funding for the amounts of denitrification were occur- also the benefits and hazards of apply- center is supplied by companies and ring, releasing the nitrogen as gas,” ing liquid digested sludge for agricul- agencies interested in specific wa- Pepper explains. “There was an over- tural crop production. Since 1983 ter quality issues, and by the Na- all loss of nitrogen from the system biosolids have been put on agricultural tional Science Foundation. without detrimental effects on under- land in Marana, north of Tucson, but Research focal areas include wa- ground aquifers.” farmland there is becoming scarce, and ter security; the fate and remediation of commercial and in- Another potential problem was the this method offers an alternative av- dustrial contamination; agrochemi- possibility that the mine tailings still enue of disposal. The W-Q-C is also ex- cal products and practices that in- contained high metal concentrations, amining bioaerosols, chemical odors, fluence water quality; municipal pathogen transport through soil, and particularly copper and molybdenum, waste treatment and reuse; mining; methods for upgrading of class B that could leach into the groundwater; and potable water quality. biosolids to class A. biosolids are characteristically low in “It is the dynamic relationship metals. Again, there were protective The Arizona Mining Association, min- between the private sector and the factors: the lack of irrigation inhibited ing companies, California’s Los Angeles university, and the integration of the leaching, and Pepper found that and Orange County Sanitation Districts, university with industry and govern- biosolids have a tendency to tie up and several agribusinesses have shown mental agencies that makes this complex metals within the mine tail- an interest in this remediation work and NSF Water Quality Center unique,” ings, making them less bioavailable. It the potential for its application on a more says Ian Pepper, director of the should be noted that neither site was widespread basis. Center. “In addition, it is the com- monitored for the presence of patho- bination of university expertise and gens because the treated sludge used corporate funding that leads to sci- in the research was rated class A “ex- CONTACT entific discoveries that can enhance ceptional quality,” or pathogen-free. Ian Pepper water quality for the community at This study was designed to evaluate (520) 626-3328 large.” [email protected] not only the revegetation aspects of adding biosolids to mine tailings, but For more information: wqc.arizona.edu 2002 Agricultural Experiment Station Research Report 19.
Load more

Recommended publications
  • State of Utah DIVISION of WASTE MANAGEMENT GARY R
    Department of Environmental Quality L. Scott Baird Executive Director State of Utah DIVISION OF WASTE MANAGEMENT GARY R. HERBERT AND RADIATION CONTROL Governor Ty L. Howard SPENCER J. COX Director Lieutenant Governor November 5, 2020 Cassady Kristensen Environmental Business Partner Rio Tinto Kennecott 4700 Daybreak Parkway South Jordan, UT 84009 RE: Kennecott Utah Copper Tailings Impoundment Refuse Class IIIb Landfill Permit Dear Ms. Kristensen: The Division of Waste Management and Radiation Control (Division) has completed its review of the application to permit the Rio Tinto Kennecott Utah Copper Tailings Impoundment Refuse Class IIIb Landfill located on the Rio Tinto Kennecott Tailings Impoundment facility in Salt Lake County, Utah. Enclosed with this letter is the approved Permit Number 1905 and applicable attachments from portions of the application. The Permit approval and expiration dates are shown on the permit cover page. Also, the Statement of Basis for this permit (DSHW-2020-014707) is included with the permit. If you have any questions, please call Doug Taylor at (801) 536-0240. Sincerely, Ty L. Howard, Director Division of Waste Management and Radiation Control (Over) DSHW-2020-014711 195 North 1950 West • Salt Lake City, UT Mailing Address: P.O. Box 144880 • Salt Lake City, UT 84114-4880 Telephone (801) 536-0200 • Fax (801) 536-0222 • T.D.D. (801) 536-4284 www.deq.utah.gov Printed on 100% recycled paper TLH/DT/ar Enclosures: Permit (DSHW-2020-004084) Attachment #1 - Landfill Design (DSHW-2020-004510) Attachment #2 – Operation Plan (DSHW- 2020-004512) Attachment #3 – Closure and Post-Closure Plan (DSHW-2020-004514) Statement of Basis (DSHW-2020-014707) c: Gary Edwards, MS, Health Officer, Salt Lake County Health Dept.
    [Show full text]
  • Legislation for the Reuse of Biosolids on Agricultural Land in Europe: Overview
    sustainability Review Legislation for the Reuse of Biosolids on Agricultural Land in Europe: Overview Maria Cristina Collivignarelli 1 , Alessandro Abbà 2, Andrea Frattarola 1, Marco Carnevale Miino 1 , Sergio Padovani 3, Ioannis Katsoyiannis 4,* and Vincenzo Torretta 5 1 Department of Civil and Architectural Engineering, University of Pavia, via Ferrata 1, 27100 Pavia, Italy; [email protected] (M.C.C.); [email protected] (A.F.); [email protected] (M.C.M.) 2 Department of Civil, Environmental, Architectural Engineering and Mathematics, University of Brescia, via Branze 43, 25123 Brescia, Italy; [email protected] 3 ARPA Lombardia, Pavia Department, via Nino Bixio 13, 27100 Pavia, Italy; [email protected] 4 Department of Chemistry, Laboratory of Chemical and Environmental Technology, Aristotle University of Thessaloniki, 54124 Thessaloniki, Greece 5 Department of Theoretical and Applied Sciences, University of Insubria, via G.B. Vico 46, 21100 Varese, Italy; [email protected] * Correspondence: [email protected] Received: 17 September 2019; Accepted: 25 October 2019; Published: 29 October 2019 Abstract: The issues concerning the management of sewage sludge produced in wastewater treatment plants are becoming more important in Europe due to: (i) the modification of sludge quality (biological and chemical sludge are often mixed with negative impacts on sludge management, especially for land application); (ii) the evolution of legislation (landfill disposal is banned in many European countries); and (iii) the technologies for energy and material recovery from sludge not being fully applied in all European Member States. Furthermore, Directive 2018/851/EC introduced the waste hierarchy that involved a new strategy with the prevention in waste production and the minimization of landfill disposal.
    [Show full text]
  • Assessment of the Possible Reuse of Extractive Waste Coming from Abandoned Mine Sites: Case Study in Gorno, Italy
    sustainability Article Assessment of the Possible Reuse of Extractive Waste Coming from Abandoned Mine Sites: Case Study in Gorno, Italy Neha Mehta 1,2, Giovanna Antonella Dino 1,*, Iride Passarella 3, Franco Ajmone-Marsan 4, Piergiorgio Rossetti 1 and Domenico Antonio De Luca 1 1 Department of Earth Sciences, University of Turin, 10125 Torino, Italy; [email protected] (N.M.); [email protected] (P.R.); [email protected] (D.A.D.L.) 2 School of Mechanical and Aerospace Engineering, Queen’s University Belfast, Belfast, BT9 5AH, UK 3 Horizon s.r.l., 10095 Grugliasco (TO), Italy; [email protected] 4 Department of Agricultural, Forestry and Food Sciences, University of Turin, 10095 Grugliasco (TO), Italy; [email protected] * Correspondence: [email protected]; Tel.: +39-011-6705150 Received: 21 January 2020; Accepted: 17 March 2020; Published: 21 March 2020 Abstract: Supply of resources, a growing population, and environmental pollution are some of the main challenges facing the contemporary world. The rapid development of mining activities has produced huge amounts of waste. This waste, found in abandoned mine sites, provides the potential opportunity of extracting raw material. The current study, therefore, focuses on testing the validation of a shared methodology to recover extractive waste from abandoned mines, and applies this methodology to a case study in Gorno, northwest Italy. The methods focused on: (1) analyzing the impact of tailings and fine fraction of waste rock (<2 mm) on plants (Cress - Lepidium Sativum) to assess usability of both as soil additive, and (2) recovering raw materials from tailings and coarse fraction (>2 mm) of waste rock, by means of dressing methods like wet shaking table and froth flotation.
    [Show full text]
  • Revegetation of Mine Tailings Throughthe Use of Biosolid Amendment1
    REVEGETATION OF MINE TAILINGS THROUGHTHE USE OF BIOSOLID AMENDMENT1 I.L. Pepper2, S.A. Bengson, P.R. Rao, and K.L. Josephson Abstract. Mine tailings represent the end product of mineral ores that are processed to extract specific metals such as copper. Tailings are in essence crushed rock with 0% organic matter, and can be layered to depths of 30B36m. We evaluated revegetation of mine tailings through the one time application of municipal biosolids. Specifically a 2 hectare copper mine-tailing plot near the Mission Mine in Southern Arizona was designated for this study. Approximately 220 dry tons per hectare of biosolids was added and incorporated in December 1998. The potential for successful revegetation was evaluated by monitoring soil microbial populations, which quickly become established at •107 heterotrophic bacteria per gram of biosolid amended mine tailings. By September 2001 vegetative cover had increased from zero to 77%. Initially bermudagrass and Russian Thistle were the predominant species involved. More recently Buffalo grass and Lehmans Lovegrass have become more prominent. Monitoring of soil metal concentrations as a function of depth showed that the tailings were the major source of metals, not the biosolids. There was no evidence that metals were leaching under the low rainfall, non-irrigated conditions. Plant tissue metal concentrations showed that phytoremediation could remove metals from the surface depths of tailings. Soil nitrate concentrations varied seasonally and with tailing depth. Nitrogen transformations included ammonification, nitrification and denitrification, which allowed nitrogen to be removed from tailings. Leaching of nitrate appeared to be minimal. Overall biosolid amendment of mine tailings appeared to be a successful technological approach to enhance revegetation of the mine tailings.
    [Show full text]
  • Environmental Lmpact Mine Development and Tailings Disposal
    .--L South Pocific Regionol Environm€nf Progromme ft -- Ittltt-'r'tl SPREP Reports ond Studies Series no, 95 WJ: Environmental lmPact Hffi Assessment Guidelines for Mine DeveloPment and ffi Tailings Disposal at Tropical Coastal Mines ar'' -il South Pocific Reglonol Environment Progromrre Environmental lmpact Assessment Guidelines for Mine Development and Tailings Disposal at Tropical Coastal Mines Prepared by Derek Ellls Assisted by Jacquellne Connolly SPREP Librry Cataloguing-in-Publication Dara Ellis,Dcsck Erwironmental impact ascsmcot guiddinca fq minc dcrrclopment 2ad t.ilingr dispod et topicel costal rnincs / grcprrcd \ p6d Ellir ard **itt"d bJ.cqudinc Connolly. - Apie,Vftstcrn Samoa : SPREB 1996. viii,26p. : 69., placcs, ublcs : 29 can- ISBN:982-04-0150-X 1. Environncntal impact rtetcmens.2. Mincs and rnincrrl rrsouroae - Erndrronmcnal aspccs, 3. Erwironmcnal monitori.g- I. C.onnolly, Jacquclinc. II. South Pacific Rcgiond Environmcnt Prognmmc. IV Tida 333.765 kcprrcd for putilication by thc South Pacifc Rcgionel Ernironmcot kogrlmmc, PO Bc 24o,Apb,Wcrtcrn Samoa @ South PacificRcgiorrl Environmcnt Plogrannc, 1996 Thc South Pecifc Rcgional En'ironncnt Plogrililnc authcbcs thc rcproduction of tcmud netcrid, wholc or parq in any form, providcd approprbtc acknorlcdgcmcot b gi\r€o. Original 3srt; F'ngfirh Editor Barbare Hcason Production Pctcr Erans Photographs Plare I (covcr and p.4) reproduced with permission of Island Copper Mine, BHP Minerals Canada Ltd; platc 6 (cover and p.6) and plate 5 reproduced with permission of Placcr Pacific Limited, Typeset in I l/13 Bembo and UR\7 Casde Printed on I l0gsm Tudor RP. (100% recyded) by ABC Printing, Brisbane, Australia Printed with finaocial assistance from AusAID Covcr photographs Top:The seale of uwu produaionfmm ninitg and milling prouses an be enotmorn, Hererun see the *uste mck dunry anil their redamation at klanil Coppa Mine, Canada.
    [Show full text]
  • Litter Decomposition on Directly Revegetated Tailings at the Kidston Gold Mine, North Queensland, Australia1
    LITTER DECOMPOSITION ON DIRECTLY REVEGETATED TAILINGS AT THE KIDSTON GOLD MINE, NORTH QUEENSLAND, AUSTRALIA1 Andrew H. Grigg2 Abstract. An investigation of litter decomposition was undertaken at the Kidston Gold Mine in north Queensland, Australia with the aim of assessing the status of nutrient cycling capacity on a directly-revegetated tailings dam. Weight losses from leaf litter contained in litterbags placed in a 5-year old revegetated section of the dam were not significantly different from losses observed at two unmined reference sites over the 18 month study period, representing a rapid improvement in nutrient cycling capacity in the reconstructed ecosystem. However, fitted decay curves for each site predicted a slower decay constant and a longer litter half-life on the dam, which indicated that full pre-mining capability had not yet been achieved. Weight loss in the reconstructed system was most constrained by the low build-up of microbial biomass within the surface soil, which is expected to take at least 10 years to achieve pre-mining levels. In contrast, weight losses in the unmined sites appeared more related to the abundance of invertebrate fauna rather than microbial content. The results presented here of a developing system suggest that the importance of different factors affecting decomposition will reflect those that are most limiting over the course of ecosystem recovery. Additional Key Words: nutrient cycling, ecosystem recovery, microbial biomass, invertebrates. _____________________ 1Paper presented at the 2002 National Meeting of the American Society of Mining and Reclamation, Lexington KY, June 9-13, 2002. Published by ASMR, 3134 Montavesta Rd., Lexington, KY 40502.
    [Show full text]
  • Biosolids Management in New York State
    Biosolids Management in New York State MARCH 2018 DIVISION OF MATERIALS MANAGEMENT | 625 BROADWAY, ALBANY, NY 12233-7253 Preface This report is an update to the Division of Materials Management 2011 edition of “Biosolids Management in New York State.” It provides the most current information available concerning biosolids management practices in New York State. Biosolids was previously called sewage sludge. 6 NYCRR Part 360 regulations define biosolids as: the accumulated semi-solids or solids resulting from treatment of wastewaters from publicly or privately owned or operated sewage treatment plants. Biosolids does not include grit or screenings, or ash generated from the incineration of biosolids. We would like to thank all chief operators and managers of the wastewater treatment facilities in New York State that responded to our survey questionnaires. The report could not be completed as comprehensively without their assistance. Any comments, questions, or requests for specific data regarding this report may be sent to Molly Baker at [email protected]. Table of Contents Findings Summary ......................................................................................................................................... 1 Biosolids Management Survey ...................................................................................................................... 3 Sources of Information ............................................................................................................................. 3 Biosolids
    [Show full text]
  • A Review of Pretreatment Methods to Enhance Solids Reduction During
    applied sciences Review A Review of Pretreatment Methods to Enhance Solids Reduction during Anaerobic Digestion of Municipal Wastewater Sludges and the Resulting Digester Performance: Implications to Future Urban Biorefineries Bimi Shrestha 1, Rafael Hernandez 1, Dhan Lord B. Fortela 1, Wayne Sharp 2, Andrei Chistoserdov 3, Daniel Gang 2 , Emmanuel Revellame 4, William Holmes 5 and Mark E. Zappi 1,* 1 Department of Chemical Engineering, University of Louisiana at Lafayette, Lafayette, LA 70504, USA; [email protected] (B.S.); [email protected] (R.H.); [email protected] (D.L.B.F.) 2 Department of Civil Engineering, University of Louisiana at Lafayette, Lafayette, LA 70504, USA; [email protected] (W.S.); [email protected] (D.G.) 3 Department of Biology, University of Louisiana at Lafayette, Lafayette, LA 70504, USA; [email protected] 4 Department of Industrial Technology, University of Louisiana at Lafayette, Lafayette, LA 70504, USA; [email protected] 5 Energy Institute of Louisiana, University of Louisiana at Lafayette, Lafayette, LA 70503, USA; [email protected] * Correspondence: [email protected] Received: 18 November 2020; Accepted: 18 December 2020; Published: 21 December 2020 Abstract: The rapid increase in the population is expected to result in the approaching of design capacity for many US wastewater treatment plants (WWTPs) over the next decade. WWTPs treat both municipal and industrial wastewater influents, resulting in the production of biosolids after digestion. Biogas, a potential recovered alternative energy source, is also produced as an output from successful anaerobic digestion. More than 7M of dry tons/year of biosolids produced in the US are most often disposed in either landfills or land-applied (~80%).
    [Show full text]
  • Tailings Pond Rehabilitation Project and Effluent Management System Upgrade, Baldivis
    Tailings pond rehabilitation project and effluent management system upgrade, Baldivis Western Mining Corporation Ltd Report and recommendation of the Environmental Protection Authority Environmental Protection Authority Bulletin 489 January 1991 Taiiings pond rehabiiitation project and effluent management system upgrade, Baldivis Western Mining Corporation Ltd Report and recommendation of the Environmentai Protection Authority ISBN 0 7309 3593 0 ISSN 1030 0120 Assessment Number 323 Contents Page Summary and recommendation 1. Background 1 2. The proposal 1 2.1 The tailings pond 2.2 Timing 3 3. Potential environmental impacts assessed by the Environmental Protection Authority 3 3.1 Lake Cooloongup 3 3.2 Terrestrial vegetation 3 4~ Conclusion 5 Figures 1 ~Tailings pond locality plan 2 2. Proposed timing of activities described in CER 4 Appendices 1 List of Commitments made by the Proponent 2. Proponent's response to issues raised during the assessment process 3. Llst of organisations and members of the public that made submissions Summary and recommendation In 1969, Western Mining Corporation Limited (WMC's) constructed a tailings pond in Baldivis, 7 km from the Company's Kwinana Nickel Refinery, to store solid and liquid wastes from the refinery. In March 1979, it was discovered that the tailings pond was leaking ammonium sulphate solution to the ground1..vater resulting in contamination of tr1e bottom ·third of the groundv;ater body (aquifer). it is not c!ear whether any subsequent environmental impacts have occurred and none has been properly identified at this time. However, this absence of obvious environmental impact could be attributed to the depth of the contamination within the aquifer and that it is overlain by a significant thickness of good quality groundwater.
    [Show full text]
  • Management of Sulfide-Bearing Waste, a Challenge for the Mining Industry
    Minerals 2012, 2, 1-10; doi:10.3390/min2010001 OPEN ACCESS minerals ISSN 2075-163X www.mdpi.com/journal/minerals/ Review Management of Sulfide-Bearing Waste, a Challenge for the Mining Industry Björn Öhlander 1,*, Terrence Chatwin 2 and Lena Alakangas 1 1 Department of Geosciences, Luleå University of Technology, SE-971 87 Luleå, Sweden; E-Mail: [email protected] 2 International Network for Acid Prevention, 2105 Oneida Street, Salt Lake City, UT 84109, USA; E-Mail: [email protected] * Author to whom correspondence should be addressed; E-Mail: [email protected]; Tel.: +46-920-491396; Fax: +46-920-491199. Received: 13 December 2011; in revised form: 3 January 2012 / Accepted: 2 February 2012 / Published: 8 February 2012 Abstract: Oxidation of iron sulfides in waste rock dumps and tailings deposits may result in formation of acid rock drainage (ARD), which often is a challenging problem at mine sites. Therefore, integrating an ARD management plan into the actual mine operations in the early phases of exploration, continuing through the mine life until final closure might be successful and decrease the environmental impact. A thorough characterization of ore and waste should be performed at an early stage. A detailed knowledge of mineralogical composition, chemical composition and physical properties such as grain size, porosity and hydraulic conductivity of the different waste types is necessary for reliable predictions of ARD formation and efficiency of mitigation measures. Different approaches to prevent and mitigate ARD are discussed. Another key element of successfully planning to prevent ARD and to close a mining operation sustainably is to engage the mine stakeholders (regulators, community and government leaders, non-governmental organization (NGOs) and lenders) in helping develop and implement the ARD management plan.
    [Show full text]
  • Sewage Sludge (Biosolids) Were Incomplete Or in Biosolids but Cannot Yet and the Environment
    U.S. ENVIRONMENTAL PROTECTION AGENCY OFFICE OF INSPECTOR GENERAL Cleaning up and revitalizing land EPA Unable to Assess the Impact of Hundreds of Unregulated Pollutants in Land-Applied Biosolids on Human Health and the Environment Report No. 19-P-0002 November 15, 2018 Report Contributors: Tina Lovingood Jill Trynosky Jenny Drzewiecki Ben Beeson Patrick Milligan Abbreviations CDC U.S. Centers for Disease Control and Prevention CFR Code of Federal Regulations EPA U.S. Environmental Protection Agency NIOSH National Institute for Occupational Safety and Health NPDES National Pollutant Discharge Elimination System OECA Office of Enforcement and Compliance Assurance OIG Office of Inspector General POTW Publicly Operated Treatment Works RCRA Resource Conservation and Recovery Act USGS U.S. Geological Survey Cover Photo: Tilling soil and injecting biosolids into a farm field near Madison, Wisconsin. (OIG photo) Are you aware of fraud, waste or abuse in an EPA Office of Inspector General EPA program? 1200 Pennsylvania Avenue, NW (2410T) Washington, DC 20460 EPA Inspector General Hotline (202) 566-2391 1200 Pennsylvania Avenue, NW (2431T) www.epa.gov/oig Washington, DC 20460 (888) 546-8740 (202) 566-2599 (fax) [email protected] Subscribe to our Email Updates Follow us on Twitter @EPAoig Learn more about our OIG Hotline. Send us your Project Suggestions U.S. Environmental Protection Agency 19-P-0002 Office of Inspector General November 15, 2018 At a Glance Why We Did This Review EPA Unable to Assess the Impact of Hundreds of We conducted this audit to Unregulated Pollutants in Land-Applied determine whether the U.S. Environmental Biosolids on Human Health and the Environment Protection Agency (EPA) has and implements controls What We Found over the land application of sewage sludge that are The EPA’s controls over the land application of The EPA identified 352 pollutants protective of human health sewage sludge (biosolids) were incomplete or in biosolids but cannot yet and the environment.
    [Show full text]
  • Mining Waste Challenges: Environmental Risks of Gigatons of Mud, Dust and Sediment in Megadiverse Regions in Brazil
    sustainability Communication Mining Waste Challenges: Environmental Risks of Gigatons of Mud, Dust and Sediment in Megadiverse Regions in Brazil Flávio F. Carmo 1,* , Andressa O. Lanchotti 2 and Luciana H.Y. Kamino 1 1 Prístino Institute, Belo Horizonte 30462-180, Brazil; [email protected] 2 Public Prosecutor’s Office of the State of Minas Gerais, Operational Support Center for the Environmental Defense Prosecutor’s Office, Belo Horizonte 30190-100, Brazil; [email protected] * Correspondence: fl[email protected] Received: 14 August 2020; Accepted: 2 October 2020; Published: 14 October 2020 Abstract: The management of long-lived mining wastes is a complex environmental challenge, but the subject is little discussed among the public, scientific community, and policymakers. The negative environmental impacts caused by mining wastes are severe and cause damage to human health and the loss and degradation of natural ecosystems. With the objective of stimulating discussion to advance the development of measures to contain threats to biodiversity and to mitigate negative impacts, we present an overview of total volumes of mining waste disposal in tailings dams and dump piles, discriminating them by ore type and biome. We highlight the major environmental risks and challenges associated with tropical forests, savannas, and freshwater ecosystems and possible limitations and advances in public policies and governance. The scale of this challenge is global, as some data show, for example, Brazil generated 3.6 billion tons of solid mining waste in dump piles in the period between 2008 and 2019. The volume is equivalent to 62% of the global mass of nonfuel minerals removed from the planet’s crust in 2006.
    [Show full text]