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Green Low-Carbon Technology for Metalliferous Minerals

dc.contributor.editorGuo, Lijie
dc.date.accessioned2022-12-06T16:10:17Z
dc.date.available2022-12-06T16:10:17Z
dc.date.issued2022
dc.identifierONIX_20221206_9783036557977_54
dc.identifier.urihttps://directory.doabooks.org/handle/20.500.12854/94531
dc.description.abstractMetalliferous minerals play a central role in the global economy. They will continue to provide the raw materials we need for industrial processes. Significant challenges will likely emerge if the climate-driven green and low-carbon development transition of metalliferous mineral exploitation is not managed responsibly and sustainably. Green low-carbon technology is vital to promote the development of metalliferous mineral resources shifting from extensive and destructive mining to clean and energy-saving mining in future decades. Global mining scientists and engineers have conducted a lot of research in related fields, such as green mining, ecological mining, energy-saving mining, and mining solid waste recycling, and have achieved a great deal of innovative progress and achievements. This Special Issue intends to collect the latest developments in the green low-carbon mining field, written by well-known researchers who have contributed to the innovation of new technologies, process optimization methods, or energy-saving techniques in metalliferous minerals development.
dc.languageEnglish
dc.subject.classificationbic Book Industry Communication::T Technology, engineering, agriculture::TB Technology: general issues
dc.subject.classificationbic Book Industry Communication::T Technology, engineering, agriculture::TB Technology: general issues::TBX History of engineering & technology
dc.subject.classificationbic Book Industry Communication::T Technology, engineering, agriculture::TT Other technologies & applied sciences::TTU Mining technology & engineering
dc.subject.othermetallurgical slag-based binders
dc.subject.othersolidification/stabilisation
dc.subject.otherAs(III)
dc.subject.otherAs(V)
dc.subject.othercalcium hydroxide
dc.subject.othersublevel caving
dc.subject.othernumerical simulation
dc.subject.otherphysical model
dc.subject.otherstructural parameter
dc.subject.othergreen mining
dc.subject.otherlimestone
dc.subject.otherhigh temperature
dc.subject.otherconfining pressure
dc.subject.otherSHPB
dc.subject.otherconstitutive model
dc.subject.otheropen-pit mine
dc.subject.otherPLAXIS 3D
dc.subject.otherdynamic load
dc.subject.othersafety factor
dc.subject.otheracceleration
dc.subject.otherparticle sedimentation
dc.subject.otherfilling mining
dc.subject.otherdegree of influence
dc.subject.otherpipeline transportation
dc.subject.othersolid waste utilization
dc.subject.othertailings
dc.subject.otherreclamation risk
dc.subject.otherhazard identification
dc.subject.othercomplex network
dc.subject.otherhazard management
dc.subject.otherdigital mine
dc.subject.othermine short-term production planning
dc.subject.otherhaulage equipment dispatch plan
dc.subject.otherABCA
dc.subject.otherNSGA
dc.subject.othersettlement velocity measurement
dc.subject.otherK-means
dc.subject.othertailings backfill
dc.subject.otherunsupervised learning
dc.subject.othercemented paste backfill
dc.subject.otherESEM
dc.subject.otherpicture processing
dc.subject.otherfloc networks
dc.subject.otherpumping agent
dc.subject.otherfractal dimension
dc.subject.otherbackfill slurry
dc.subject.otherstrength of cemented backfill
dc.subject.otherinhomogeneity of cemented backfill
dc.subject.othercemented tailings backfill
dc.subject.othercopper
dc.subject.otherzinc
dc.subject.otherrecovery
dc.subject.othersulfide concentrate
dc.subject.otherartificial microbial community
dc.subject.othergranular backfill
dc.subject.otherbearing characteristics
dc.subject.othernumerical model
dc.subject.otherparticle size
dc.subject.othersurface subsidence
dc.subject.otherblasting dust movement
dc.subject.otherdust concentration
dc.subject.otherparticle size distribution
dc.subject.otherblasting dust reduction
dc.subject.otherbackfill
dc.subject.othermetal mine
dc.subject.otherlog-sigmoid
dc.subject.othertailings pond
dc.subject.otherregional distribution
dc.subject.otherdam break
dc.subject.otheraccident statistics
dc.subject.othercausation analysis
dc.subject.otherbackfilling
dc.subject.otherincreasing resistance and reducing pressure
dc.subject.othercomputational fluid dynamics
dc.subject.otherspiral pipe
dc.subject.otherstowing gradient
dc.subject.othercoal-based solid waste
dc.subject.otherorthogonal experiment
dc.subject.otherstrength development
dc.subject.otherregression analysis
dc.subject.otherengineering performance
dc.subject.othern/a
dc.titleGreen Low-Carbon Technology for Metalliferous Minerals
dc.typebook
oapen.identifier.doi10.3390/books978-3-0365-5798-4
oapen.relation.isPublishedBy46cabcaa-dd94-4bfe-87b4-55023c1b36d0
oapen.relation.isbn9783036557977
oapen.relation.isbn9783036557984
oapen.pages292
oapen.place.publicationBasel


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