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dc.contributor.editorTabelin, Carlito
dc.contributor.editorYoo, Kyoungkeun
dc.contributor.editorLi, Jining
dc.date.accessioned2022-02-24T10:37:09Z
dc.date.available2022-02-24T10:37:09Z
dc.date.issued2022
dc.identifierONIX_20220224_9783036527468_104
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/78806
dc.description.abstractRenewable energy and clean storage technologies are at the forefront of the world’s fight against climate change, including the UN-led move towards a carbon-neutral society. Because these complex technologies require more ‘critical’ metals and elements than fossil fuel-based technologies, the demands for raw materials in their manufacturing are skyrocketing and are projected to continue to increase into the foreseeable future.With ore grades on a steep decline, huge amounts of low-grade ores will have to be mined and processed to satisfy the world’s current and future demands for ‘critical’ metals and elements. Expansion of mining and mineral processing operations would mean more mining-related wastes—tailings, waste rocks and acid mine drainage (AMD)—notorious for their devastating and long-term destructive impacts on the environment. This Special Issue explored repurposing/reprocessing of tailings and AMD treatment cost reduction as promising alternatives to manage mine wastes more sustainably. It also includes articles on the critical roles of redox conditions and galvanic interactions on mine waste stability, hydrogeochemical controls on waste rock weathering, and climate change impacts on AMD formation in closed mines.
dc.languageEnglish
dc.subject.classificationthema EDItEUR::T Technology, Engineering, Agriculture, Industrial processes::TB Technology: general issues::TBX History of engineering and technologyen_US
dc.subject.otheracid mine drainage
dc.subject.otherlife cycle simulation
dc.subject.otherglobal warming
dc.subject.otherearth system model
dc.subject.otherRCP2.6
dc.subject.otherRCP8.5
dc.subject.othercopper recovery
dc.subject.othermicrobial fuel cell
dc.subject.otherelectricity generation
dc.subject.othermicrobial community
dc.subject.othersecondary materials
dc.subject.othermanagement
dc.subject.otherabsorption
dc.subject.otherprecipitation
dc.subject.othermine waste
dc.subject.otherdrainage
dc.subject.otherwater quality
dc.subject.othergeochemistry
dc.subject.otherhydrogeology
dc.subject.othermodelling
dc.subject.othercontamination
dc.subject.otherbatch experiments
dc.subject.otherlead
dc.subject.otherzinc
dc.subject.otherimmobilization
dc.subject.otherremediation
dc.subject.otherKabwe
dc.subject.otherZambia
dc.subject.otherabandoned mine
dc.subject.othergroundwater flow analysis
dc.subject.otherbackfilling
dc.subject.othercopper slag reprocessing tailings
dc.subject.othergeopolymer
dc.subject.othermicrostructure
dc.subject.otherNMR
dc.subject.otheriron hydroxide
dc.subject.otheriron oxyhydroxide
dc.subject.othernickel ore
dc.subject.otherfly ash
dc.subject.otherconcrete aggregate
dc.subject.othercalcite
dc.subject.othergoethite
dc.subject.otherhematite
dc.subject.othermagnetite
dc.subject.otherquartz
dc.subject.otherscheelite
dc.subject.otherfluorite
dc.subject.otherdepressant
dc.subject.otherferrous sulfate
dc.subject.otherselective flotation
dc.subject.othermine water treatment
dc.subject.othermilk of lime
dc.subject.othersodium sulfide
dc.subject.othersodium hydroxide
dc.subject.otherarsenic-containing tailings
dc.subject.othercopper mine tailings
dc.subject.othermagnetic susceptibility
dc.subject.othersampling
dc.subject.othermetals
dc.subject.otherphytoremediation
dc.subject.otherheavy metals
dc.subject.othermine tailings
dc.subject.otherendemic species
dc.subject.othernative species
dc.subject.otheralkaline flotation wastewater
dc.subject.otherwaste rock
dc.subject.othermining waste material
dc.subject.othercoal gangue
dc.subject.otherred mud
dc.subject.otherprevention
dc.subject.otherdynamic leaching
dc.subject.otherlaterite
dc.subject.otheralkali-activated
dc.subject.otheralumino-silicates
dc.subject.otherI-optimal
dc.subject.otherresponse surface methodology
dc.subject.otheroptimization
dc.subject.otherAcidithiobacillus
dc.subject.otherbiomining
dc.subject.othercomparative genomics
dc.subject.othergold processing effluents
dc.subject.otherFe-Al bimetallic particles
dc.subject.otherelectrochemical reduction
dc.subject.otherCu-sulfide ore
dc.subject.otherNussir
dc.subject.otherUlveryggen
dc.subject.otherRøros VMS deposit
dc.subject.otherleaching tests
dc.subject.othersubmarine weathering conditions
dc.subject.otheron-land weathering conditions
dc.subject.othern/a
dc.titleNovel and Emerging Strategies for Sustainable Mine Tailings and Acid Mine Drainage Management
dc.typebook
oapen.identifier.doi10.3390/books978-3-0365-2746-8
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0
oapen.relation.isbn9783036527468
oapen.relation.isbn9783036527475
oapen.pages332
oapen.place.publicationBasel


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