Platinum and rhenium extraction from a spent refinery catalyst using Bacillus megaterium as a cyanogenic bacterium: Statistical modeling and process optimization

Bioresource Technology

Volumn 171, Issue , 2014, Pages 401-409

  Motaghed, M ^a   Mousavi, S M ^a   Rastegar, S O ^a   Shojaosadati, S A ^a  

^a TARBIAT MODARES UNIVERSITY   (Iran)

Author keywords

Bacillus megaterium; Kinetics; Process optimization; Pt and Re recovery; Spent refinery catalyst

Indexed keywords

AMINO ACIDS; BACTERIA; BACTERIOLOGY; CATALYSTS; CYANIDES; DISSOLVED OXYGEN; ENZYME KINETICS; OPTIMIZATION; PROCESS CONTROL; REFINING; RHENIUM;

BACILLUS MEGATERIUM; EFFECTIVE PARAMETERS; GROWTH CHARACTERISTIC; MODIFIED SHRINKING-CORE MODEL; RATE-CONTROLLING STEPS; REFINERY CATALYSTS; RESPONSE SURFACE METHODOLOGY; STATISTICAL MODELING;

PLATINUM;

CYANIDE; HEAVY METAL; PETROLEUM; PLATINUM; RHENIUM; HYDROGEN CYANIDE; WASTE;

BACTERIUM; BIOTECHNOLOGY; CATALYST; CYANIDE; OPTIMIZATION; PLATINUM; REACTION KINETICS; REFINING INDUSTRY; RHENIUM;

ARTICLE; BACILLUS MEGATERIUM; BACTERIUM CULTURE; BIOLEACHING; CATALYST; CYANOBACTERIUM; EXTRACTION; INDUSTRIAL WASTE; KINETICS; NONHUMAN; PETROCHEMICAL INDUSTRY; PROCESS OPTIMIZATION; SPENT REFINERY CATALYST; ANALYSIS; BIOREACTOR; CULTURE TECHNIQUE; ISOLATION AND PURIFICATION; METABOLISM; STATISTICAL MODEL; WASTE;

CATALYSTS; CONCENTRATION; GLYCINE; OPTIMIZATION; PLATINUM; RHENIUM;

BACILLUS MEGATERIUM; BACTERIA (MICROORGANISMS);

BACILLUS MEGATERIUM; BIOREACTORS; CELL CULTURE TECHNIQUES; HYDROGEN CYANIDE; MODELS, STATISTICAL; PETROLEUM; PLATINUM; RHENIUM; WASTE PRODUCTS;

EID: 84908670873     PISSN: 09608524     EISSN: 18732976     Source Type: Journal    
DOI: 10.1016/j.biortech.2014.08.032     Document Type: Article

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