Nano-fibrillated cellulose-zeolites based new hybrid composites aerogels with super thermal insulating properties

Industrial Crops and Products

Volumn 65, Issue , 2015, Pages 374-382

  Bendahou, Dounia ^a,b   Bendahou, Abdelkader ^a   Seantier, Bastien ^a   Grohens, Yves ^a   Kaddami, Hamid ^b  

^a UNIVERSITÉ DE BRETAGNE SUD   (France)

^b CADI AYYAD UNIVERSITY   (Morocco)

Author keywords

Mechanical properties; Nanozeolites; Porosity; Super insulating aerogels; TEMPO oxidized NFC

Indexed keywords

AEROGELS; CELLULOSE; HYBRID MATERIALS; INSULATION; MECHANICAL PROPERTIES; NANOFIBERS; PERIODIC STRUCTURES; PORE SIZE; POROSITY; STIFFNESS; THERMAL INSULATION;

CELLULOSE MICROFIBRILS; CELLULOSE NANOFIBERS; CONDUCTIVITY PROPERTIES; MICROMETRIC FIBERS; NANOZEOLITES; RELATIVE FRACTION; TEMPO-OXIDIZED NFC; THERMAL INSULATING PROPERTIES;

THERMAL CONDUCTIVITY;

CELLULOSE; MECHANICAL PROPERTY; OPTIMIZATION; POROSITY; THERMAL CONDUCTIVITY; ZEOLITE;

CELLULOSE; COMPOSITES; THERMAL CONDUCTIVITY; ZEOLITES;

EID: 84946051601     PISSN: 09266690     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.indcrop.2014.11.012     Document Type: Article

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