Preparation of cellulose-rich membranes from wood: effect of wood pretreatment process on membrane performance

Lopatina, Anastasiia; Anugwom, Ikenna; Esmaeili, Mohammadamin; Puro, Liisa; Virtanen, Tiina; Mänttäri, Mika; Kallioinen, Mari

doi:10.1007/s10570-020-03430-0

Cited by 15 publications

(16 citation statements)

References 55 publications

(65 reference statements)

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“…Cellulose Acetate has also been recovered from waste cigarette filters which is one of the most abundant forms of plastic waste present globally. Typically, biomass has 40 to 60 % cellulose, 15 to 30 % hemicellulose, and 10 to 25 % lignin [8] . From Figure 3 it can be confirmed that cellulose has hydroxyl groups, which are responsible for its high hydrophilicity.…”

Section: Types Of Biopolymers For Membrane Productionmentioning

confidence: 90%

“…The properties of lignin and the complexity of the chemical composition of the wood prevented the formation of a dense top layer. [8] After the removal of lignin and hemicellulose, the wood membrane becomes flexible, with greater hydrophilicity and oleophobicity. [10] With further treatments, the purity of cellulose increased producing a chemically more homogeneous, tighter membrane having increased retention and decreased permeance.…”

Section: Cellulosementioning

confidence: 99%

“…Membranes manufactured from untreated birch wood exhibited higher permeance and lower retention. The properties of lignin and the complexity of the chemical composition of the wood prevented the formation of a dense top layer [8] …”

Section: Types Of Biopolymers For Membrane Productionmentioning

confidence: 99%

“…After the removal of lignin and hemicellulose, the wood membrane becomes flexible, with greater hydrophilicity and oleophobicity [10] . With further treatments, the purity of cellulose increased producing a chemically more homogeneous, tighter membrane having increased retention and decreased permeance [8] . More research is required for solvents used to treat substrates.…”

Section: Types Of Biopolymers For Membrane Productionmentioning

confidence: 99%

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Green and Non‐Conventional Materials for Membrane Synthesis: A Review

et al. 2022

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Membrane separation has been an upgrade in our quest for eco-friendly processes because of its minimal energy usage and lesser waste generation. However, the most widely used membranes are polymeric membranes. Most of these membranes are non-biodegradable and are replaced after deterioration/fouling and then discarded. Dumping without treatment on a large scale is a significant environmental problem. Green polymers only make up a limited percentage of all the new materials that are reported every year. We require more research in developing renewable, inexpensive membranes from waste materials to ensure progress with the least toll on the environment. Several reported green methods can partially achieve green synthesis. This ensures the least use of nonbiodegradable polymers in membranes. This review will emphasize the exploration of more natural materials given the target is to fabricate membranes in a way, where both raw material and membrane preparation are green.

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Section: Types Of Biopolymers For Membrane Productionmentioning

confidence: 90%

Section: Cellulosementioning

confidence: 99%

Section: Types Of Biopolymers For Membrane Productionmentioning

confidence: 99%

Section: Types Of Biopolymers For Membrane Productionmentioning

confidence: 99%

See 2 more Smart Citations

Green and Non‐Conventional Materials for Membrane Synthesis: A Review

et al. 2022

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“…Despite the chosen method of describing cellulose as a polymer-regardless of whether it is recognised as hydrophilic or an amphiphilic one [5][6][7][8][9]-the regenerated cellulose membranes are universally acknowledged as very hydrophilic, having higher biocompatibility and lower fouling tendency when compared with petroleum-based polymers due to cellulose being a biopolymer [10][11][12][13]. The existing research focusing on the manufacturing of cellulose membranes is highly variable regarding whether research groups prefer to use commercially produced cellulose [14][15][16] or biobased cellulose sources [2,17,18], using various solvents with high capacity for cellulose dissolution [3,4,19]. The steady interest towards ionic liquids (ILs) as cellulose and biomass solvent media is supported with such characteristics as their potential recyclability, low vapour pressure, and good chemical and thermal stability [20][21][22][23].…”

Section: Introductionmentioning

confidence: 99%

Wood-Based Cellulose-Rich Ultrafiltration Membranes: Alkaline Coagulation Bath Introduction and Investigation of Its Effect over Membranes’ Performance

et al. 2022

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In this study, wood-based cellulose-rich membranes were produced with a novel approach to casting procedure. Flat-sheet membranes were prepared from birch biomass pretreated with deep eutectic solvent and dissolved in ionic liquid–dimethylsulfoxide system via phase inversion method. Alkaline coagulation bath filled with sodium hydroxide solution was added to the process before a water coagulation bath and aimed to improve membranes’ performance. The effect of NaOH coagulation bath on the membrane was studied based on two NaOH concentrations and two different treatment times. The characterisation methods included measuring pure water permeabilities, polyethylene glycol 35 kDa model solution retentions, hydrophilicity, zeta potential, and chemical structure. Additionally, suitability of the membranes for removing residual phosphorous from a municipal wastewater treatment plant’s effluent was studied. The study revealed that introduction of the alkaline coagulation bath led to additional removal of lignin from membrane matrix and increase in the filtration capacity up to eight times. The resulting membranes can be characterised as very hydrophilic, with contact angle values 11.9–18.2°, negatively charged over a wide pH range. The membranes with the highest permeability, 380–450 L/m2·h·bar, showed approximately 70% phosphorus removal from purified wastewater, good removal of suspended solids, and low irreversible fouling tendency.

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Esterified Lignin from Construction and Demolition Waste (CDW) as a Versatile Additive for Polylactic‐Acid (PLA) Composites—The Effect of Artificial Weathering on its Performance

et al. 2022

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Demand for sustainable packaging and building materials has increased the need for biobased additives. Biocomposites can often be exposed to different weather conditions and UV irradiation. Thus, additives to prevent the negative impact of weathering are generally added to composites. This study aims to evaluate using esterified lignin as an additive against weathering effects in polylactic‐acid (PLA) composites. Lignin is extracted from construction and demolition waste (CDW) wood using a deep eutectic solvent then esterified and tested as an additive in the fabrication of bio‐based composites. For comparison, lignin from birch is used as a raw material for an additive. Esterification is confirmed by solid‐state NMR analysis. Samples are exposed to artificial weathering for 700 hours and their impact strength and color change properties are measured. The results indicate that esterified lignin from CDW (CDW e‐lignin) as an additive protects the biocomposite from the weathering impact. The sample containing the CDW e‐lignin as an additive suffers only a 4.3% of reduction of impact strength, while the samples that contain commercial additives lose clearly more of their impact strength (from 23.1% to 61.1%). Based on the results CDW e‐lignin is a good additive to prevent weathering. As a conclusion, the esterified lignin from CDW, is a versatile additive for composite production.

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Preparation of cellulose-rich membranes from wood: effect of wood pretreatment process on membrane performance

Cited by 15 publications

References 55 publications

Green and Non‐Conventional Materials for Membrane Synthesis: A Review

Green and Non‐Conventional Materials for Membrane Synthesis: A Review

Wood-Based Cellulose-Rich Ultrafiltration Membranes: Alkaline Coagulation Bath Introduction and Investigation of Its Effect over Membranes’ Performance

Esterified Lignin from Construction and Demolition Waste (CDW) as a Versatile Additive for Polylactic‐Acid (PLA) Composites—The Effect of Artificial Weathering on its Performance

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