Foaming of oxidized nanocellulose for the preparation of high-flux water filters

TY - JOUR

T1 - Foaming of oxidized nanocellulose for the preparation of high-flux water filters

AU - Fortea-Verdejo, Marta

AU - Jiang, Qixiang

AU - Bismarck, Alexander

AU - Mautner, Andreas

N1 - Publisher Copyright: © 2022, The Author(s).

PY - 2023/5

Y1 - 2023/5

N2 - Treatment of polluted water is an important task to secure access to clean water also for future generations. Filters are an efficient means to reject various pollutants on a wide range of size scales either by size-exclusion or electrostatic interaction, respectively. Commonly, filters and membranes from various synthetic materials are employed for these applications. Recently, filters based on renewable (nano) cellulose papers and coatings emerged as sustainable alternative to synthetic materials usually utilized. However, fabrication of such paper network structures from aqueous suspension by filtration processes is a time-consuming process caused by the high water holding capacity of highly hydrophilic and negatively charged nanocellulose fibrils. To optimize the preparation of nanocellulose coated filters, substitution of water by air and thus generating nanocellulose foams that are collapsed onto a substrate would be an appealing approach. Here we present the development of foams from negatively charged TEMPO-oxidized nanocellulose by screening various surfactants and concentrations to generate a foam stable enough to be transferred onto a viscose substrate. Foams were collapsed by oven consolidation, positive pressure filtration, or hot-pressing, respectively. Consolidated filters were tested for their water permeance and rejection of heavy metal ions using copper ions as model system. Very high permeances competitive to commercial filters based on synthetic polymers were achieved. Furthermore, adsorption capacities for copper of up to 70 mg/g were found. This is close to adsorption capacities reported for negatively charged TEMPO-oxidized nanocellulose in conventional batch-wise static adsorption. However, in the current process adsorption takes place during filtration of water through filters in a continuous process which constitutes a tremendous advantage. Graphical Abstract: [Figure not available: see fulltext.].

AB - Treatment of polluted water is an important task to secure access to clean water also for future generations. Filters are an efficient means to reject various pollutants on a wide range of size scales either by size-exclusion or electrostatic interaction, respectively. Commonly, filters and membranes from various synthetic materials are employed for these applications. Recently, filters based on renewable (nano) cellulose papers and coatings emerged as sustainable alternative to synthetic materials usually utilized. However, fabrication of such paper network structures from aqueous suspension by filtration processes is a time-consuming process caused by the high water holding capacity of highly hydrophilic and negatively charged nanocellulose fibrils. To optimize the preparation of nanocellulose coated filters, substitution of water by air and thus generating nanocellulose foams that are collapsed onto a substrate would be an appealing approach. Here we present the development of foams from negatively charged TEMPO-oxidized nanocellulose by screening various surfactants and concentrations to generate a foam stable enough to be transferred onto a viscose substrate. Foams were collapsed by oven consolidation, positive pressure filtration, or hot-pressing, respectively. Consolidated filters were tested for their water permeance and rejection of heavy metal ions using copper ions as model system. Very high permeances competitive to commercial filters based on synthetic polymers were achieved. Furthermore, adsorption capacities for copper of up to 70 mg/g were found. This is close to adsorption capacities reported for negatively charged TEMPO-oxidized nanocellulose in conventional batch-wise static adsorption. However, in the current process adsorption takes place during filtration of water through filters in a continuous process which constitutes a tremendous advantage. Graphical Abstract: [Figure not available: see fulltext.].

KW - Nanocellulose

KW - Carbohydrates

KW - Membranes

KW - Surfactants

KW - Foam

KW - Coating

KW - HEAVY-METAL IONS

KW - NANOFILTRATION MEMBRANES

KW - CELLULOSE NANOFIBERS

KW - ADSORPTION

KW - NANOMATERIALS

KW - ADSORBENTS

KW - REMOVAL

KW - NANOPAPERS

KW - NITRATE

KW - AG+

UR - http://www.scopus.com/inward/record.url?scp=85143762520&partnerID=8YFLogxK

U2 - 10.1007/s00706-022-03014-7

DO - 10.1007/s00706-022-03014-7

M3 - Article

VL - 154

SP - 523

EP - 532

JO - Monatshefte für Chemie

JF - Monatshefte für Chemie

SN - 0026-9247

IS - 5

ER -