Mechanical dissociation and fragmentation of lignocellulosic biomass: Effect of initial moisture, biochemical and structural proprieties on energy requirement

Applied Energy

Volumn 142, Issue , 2015, Pages 240-246

  Barakat, Abdellatif ^a   Monlau, Florian ^a,b   Solhy, Abderrahim ^c   Carrere, Hélène ^b  

^a UMR IATE   (France)

^b LABORATOIRE DE BIOTECHNOLOGIE DE L ENVIRONNEMENT   (France)

^c MOHAMMED VI POLYTECHNIC UNIVERSITY   (Morocco)

Author keywords

Biomass; Energy; Mechanical pretreatment; Milling; Multivariate regression; Physicochemical features

Indexed keywords

MILLING (MACHINING); MOISTURE; MOISTURE DETERMINATION; PARTICLE SIZE; PARTICLE SIZE ANALYSIS; REGRESSION ANALYSIS; SIZE DETERMINATION;

ACCESSIBLE SURFACE AREAS; ENERGY; INITIAL MOISTURE CONTENT; LIGNOCELLULOSIC BIOMASS; MECHANICAL PRE-TREATMENT; MULTIVARIATE REGRESSION; PHYSICOCHEMICAL FEATURES; SPECIFIC ENERGY REQUIREMENT;

BIOMASS;

BIOCHEMICAL COMPOSITION; BIOMASS; CELLULOSE; CRYSTALLINITY; ENERGY EFFICIENCY; FRAGMENTATION; LIGNIN; MOISTURE CONTENT; ORGANIC ACID; PARTICLE SIZE; PHYSICOCHEMICAL PROPERTY;

EID: 84921369429     PISSN: 03062619     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.apenergy.2014.12.076     Document Type: Article

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