Strong and Flexible TEMPO-CNF/Boron Nitride Nanocomposite Films / Starka och flexibla nanokompositfilmer av TEMPO-CNF/boronnitrid

Sadatifard, Sara

January 2023

Nanokompositfilmer med fem olika sammansättningar av hexagonala bornitrid nanosheet och TEMPO-CNF tillverkades med hjälp av vakuumassisterad filtreringsteknik. sond-ultraljudsteknik användes som en grön väg för exfoliering av bornitridpulver i vattenhaltigt medium. TEMPO-CNF spelade nyckelroller som både matris och dispergeringsmedel för stabilisering av bornitrid nanosheets i kompositen. Nanokompositfilmerna var flexibla och formbara och de visade höga mekaniska egenskaper inklusive hög draghållfasthet och god brottöjning. / Nanocomposite films with five different compositions of hexagonal boron nitride nanosheets and TEMPO-CNF were fabricated using vacuum-assisted filtration technique. probe-ultrasonication technique was applied as a green route for exfoliation of boron nitride powder in aqueous medium. TEMPO-CNF played key roles as both matrix and dispersant agent for stabilization of the boron nitride nanosheets in the composite. The nanocomposite films were flexible and ductile, and they showed high mechanical properties including high tensile strength and good elongation at break.

Hexagonal boron nitride

cellulose nanofibrils

mechanical properties

nanocomposite

thermal conductivity

Hexagonal bornitrid

cellulose nanofibrillar

mekaniska egenskaper

nanokomposit

värmeledningsförmåga

Composite Science and Engineering

Kompositmaterial och -teknik

Microfibrillated cellulose : Energy-efficient preparation techniques and key properties

Ankerfors, Mikael

January 2012

This work describes three alternative processes for producing microfibrillated cellulose (MFC) in which pulp fibres are first pre-treated and then homogenized using a high-pressure homogenizer. In one process, fibre cell wall delamination was facilitated with a combined enzymatic and mechanical pre-treatment. In the two other processes, cell wall delamination was facilitated by pre-treatments that introduced anionically charged groups into the fibre wall, by means of either a carboxymethylation reaction or irreversibly attaching carboxymethyl cellulose (CMC) onto the fibres. All three processes are industrially feasible and enable production with low energy consumption. Using these methods, MFC can be produced with an energy consumption of 500–2300 kWh/tonne, which corresponds to a 91–98% reduction in energy consumption from that presented in earlier studies. These materials have been characterized in various ways and it has been demonstrated that the produced MFCs are approximately 5–30 nm wide and up to several microns long. / <p>QC 20120928</p>

Microfibrillated cellulose

microfibrillar cellulose

nanocellulose

MFC

NFC

production techniques

energy efficient

gel properties

films

enzymes

carboxymethylation

carboxymethyl cellulose

CMC

mechanical properties

oxygen barrier

homogenization

Paper, Pulp and Fiber Technology

Pappers-, massa- och fiberteknik