TY - JOUR
T1 - Controlled surface acetylation of cellulosics to tune biodegradability while expanding their use towards common petrochemical-based plastics
AU - King, Alistair
AU - Paajanen, Antti
AU - Mahlamäki, Ella
AU - Mäkelä, Mikko
AU - Penttilä, Paavo
AU - Leino, Mari
AU - Spönla, Elisa
AU - Svanberg, Mariitta
AU - Koso, Tetyana
AU - Tanaka, Atsushi
AU - Liukkonen, Vuokko
AU - Solberg, Amalie
AU - Savolainen, Anniina
AU - Orelma, Hannes
AU - Korpela, Antti
AU - Syverud, Kristin
AU - Harlin, Ali
PY - 2024/2/20
Y1 - 2024/2/20
N2 - The European Commissions single-use plastics directive has put major restrictions on the use of chemically modified cellulosics for different material applications, e.g., as films, fibres, foams and other shaped objects. In addition, the wet strength and barrier properties of some of these materials are lacking, in comparison to petrochemical-based plastics. In the current study we demonstrate that it is possible to carry out surface selective acetylation of kraft fibre paper and nano-paper to create materials that maintain biodegradability. This is shown to be highly dependent on the degree of bulk acetylation, with those materials with modification restricted to fibril surface monoacetylation offering fine control over enzymatic digestibility. Materials which show the formation of cellulose triacetate were much less degradable in the timeframe of our assessment methods. However, the wet strength and extensibility of these materials was significantly improved, pushing the envelope for application towards moisture-rich environments. The mechanistic component of our study shows acetylation occurs down to the fibril surface level, and not just on the macrofibre level. We believe that this study offers a strong basis for widening the application scope of cellulosics towards traditionally petrochemical-based plastics
AB - The European Commissions single-use plastics directive has put major restrictions on the use of chemically modified cellulosics for different material applications, e.g., as films, fibres, foams and other shaped objects. In addition, the wet strength and barrier properties of some of these materials are lacking, in comparison to petrochemical-based plastics. In the current study we demonstrate that it is possible to carry out surface selective acetylation of kraft fibre paper and nano-paper to create materials that maintain biodegradability. This is shown to be highly dependent on the degree of bulk acetylation, with those materials with modification restricted to fibril surface monoacetylation offering fine control over enzymatic digestibility. Materials which show the formation of cellulose triacetate were much less degradable in the timeframe of our assessment methods. However, the wet strength and extensibility of these materials was significantly improved, pushing the envelope for application towards moisture-rich environments. The mechanistic component of our study shows acetylation occurs down to the fibril surface level, and not just on the macrofibre level. We believe that this study offers a strong basis for widening the application scope of cellulosics towards traditionally petrochemical-based plastics
U2 - 10.26434/chemrxiv-2024-9pt8w
DO - 10.26434/chemrxiv-2024-9pt8w
M3 - Article in a proceedings journal
SN - 2573-2293
JO - ChemRxiv preprint
JF - ChemRxiv preprint
ER -