Direct electrospinning of cellulose in the DBU-CO2 switchable solvent system

Heidari, Mina; Onwukamike, Kelechukwu N.; Grau, Étienne; Grelier, Stéphane; Cramail, Henri; Meier, Michael A. R.; Greiner, Andreas

doi:10.1007/s10570-021-03967-8

Cited by 6 publications

(4 citation statements)

References 51 publications

(61 reference statements)

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“…This is similar to the reaction between cellulose and carbon disulfide to form water-soluble cellulose xanthate used in the still-common viscose process . Direct electrospinning of fibers from the CO 2 /base/DMSO solvent system has recently been reported . Cellulose films produced from this solvent have been reported to consist of cellulose IV I , a crystal structure not normally seen in technical applications.…”

Section: Introductionmentioning

confidence: 64%

Direct Evidence for Reaction between Cellulose and CO₂ from Nuclear Magnetic Resonance

Gunnarsson

Bernin

Hasani

et al. 2021

ACS Sustainable Chem. Eng.

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The direct reaction between carbohydrates and CO2 has recently attracted attention in the context of cellulose dissolution and derivatization as well as carbon capture applications. We have directly demonstrated the formation of cellulose carbonate upon the introduction of CO2 into a non-aqueous cellulose solution by nuclear magnetic resonance spectroscopy. Comparison of the observed spectra with accurate electronic structure calculations of the changes in chemical shifts upon reaction allowed us to confirm the expectation that CO2 reacts with the hydroxyl group on carbon 6 of the cellulose but not exclusively this hydroxyl group. We found good agreement between predicted and measured chemical shifts using a simple computational method.

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Section: Introductionmentioning

confidence: 64%

Direct Evidence for Reaction between Cellulose and CO₂ from Nuclear Magnetic Resonance

Gunnarsson

Bernin

Hasani

et al. 2021

ACS Sustainable Chem. Eng.

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“…In recent years, progress has been made by Meier, who introduced a more sustainable process for esterification of cellulose in a switchable 1,8diazabicyclo[5.4.0]undec-7-en (DBU)/CO 2 solvent system that holds promise for the development and processing of advanced cellulose-based plastics. [165][166][167][168][169][170][171][172][173] Tough and transparent cellulose nanopaper with high porosity was derived from aqueous dispersions of cellulose nanofibrils. [174][175][176][177][178][179] Advances in nanofibrillated cellulose production and its potential applications, ranging from nanopaper to nanocomposites, coatings, and food packaging, have been addressed by several reviews.…”

Section: Bio-based Plastics Extracted From Naturementioning

confidence: 99%

Closing the Carbon Loop in the Circular Plastics Economy

Schirmeister

Mülhaupt

2022

Macromol. Rapid Commun.

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Today, plastics are ubiquitous in everyday life, problem solvers of modern technologies, and crucial for sustainable development. Yet the surge in global demand for plastics of the growing world population has triggered a tidal wave of plastic debris in the environment. Moving from a linear to a zero‐waste and carbon‐neutral circular plastic economy is vital for the future of the planet. Taming the plastic waste flood requires closing the carbon loop through plastic reuse, mechanical and molecular recycling, carbon capture, and use of the greenhouse gas carbon dioxide. In the quest for eco‐friendly products, plastics do not need to be reinvented but tuned for reuse and recycling. Their full potential must be exploited regarding energy, resource, and eco‐efficiency, waste prevention, circular economy, climate change mitigation, and lowering environmental pollution. Biodegradation holds promise for composting and bio‐feedstock recovery, but it is neither the Holy Grail of circular plastics economy nor a panacea for plastic littering. As an alternative to mechanical downcycling, molecular recycling enables both closed‐loop recovery of virgin plastics and open‐loop valorization, producing hydrogen, fuels, refinery feeds, lubricants, chemicals, and carbonaceous materials. Closing the carbon loop does not create a Perpetuum Mobile and requires renewable energy to achieve sustainability.

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“…Several studies utilizing cellulose as synthesized bers previously dissolved in some non-derivatizing solvents were conducted by [18] using TFA and DCE as the solvents via electrospinning. Recently, Hedidari et al [19] also used the direct method of cellulose dissolution in electrospinning using microcrystalline cellulose (MCC) and cellulose pulp (CP) as a feedstock for membrane polymer with DBU-CO 2 system as the solvent. On the other hand, Teow et al [20] formulated membranes from the mixture of OPEFB cellulose and PVDF; yet the solvent they used were mixture of 95% 1-methyl-2-pyrrolidone (NMP) and LiCl to remove dye from water.…”

Section: Introductionmentioning

confidence: 99%

Valorization of Oil Palm Empty Fruit Bunch (OPEFB) as Membrane Polymer via Non-solvent Induced Phase Separation Method (NIPS) for Removal of Aqueous Contaminants

Sjahro,

Yunus,

Abdullah

et al. 2024

Preprint

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Oil palm empty fruit bunches (OPEFB) is byproducts from the palm oil processing mills currently discarded on field with less economic value, while it has a potential as precursor for cellulose feedstock as main polymer of membranes as biodegradable, environmentally benign, and renewable material. Due to its poor insolubility in most of available solvents, its utilization as matrix main polymer is limited. In this study, we transformed native and functionalized cellulose derived from OPEFB into membrane via non-solvent induced phase separation (NIPS) using trifluoroacetic acid (TFA) and dichloroethane (DCE) as the solvent. The fabrication parameters included duration of air exposure ranging for 2,3, and 4 minutes prior to water immersion for 24 hours; and membrane composition, consisting of cellulose as main polymer, TiO2, and PEG. Based on TGA analysis, it suggests that membrane of pure cellulose has the highest decomposition temperature, while FTIR spectra of the synthesized membranes indicate complete evaporation of TFA & DCE during water immersion. The membranes were characterized to have water affinity indicating hydrophilic properties with water contact angle ranging from 16.12o to 26.4o. The membrane maximum water flux rate accounted for 172.6 L.m-2.h-1. Bar-1, while ion removal for Pb2+ Cu2+ and Cr3+ , dye ranged from 87.3% to 98.9%, 83.98 to 99.28%, 93.6% to 99.9%, 94.3% to 99%, respectively. Meanwhile, oil rejection ranged from 98.03% to 99.36%. Thus, it can be concluded that OPEFB derived cellulose as main polymer matrices for membrane have a great potential for wastewater treatment and water purification area.

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Direct electrospinning of cellulose in the DBU-CO2 switchable solvent system

Cited by 6 publications

References 51 publications

Direct Evidence for Reaction between Cellulose and CO₂ from Nuclear Magnetic Resonance

Direct Evidence for Reaction between Cellulose and CO₂ from Nuclear Magnetic Resonance

Closing the Carbon Loop in the Circular Plastics Economy

Valorization of Oil Palm Empty Fruit Bunch (OPEFB) as Membrane Polymer via Non-solvent Induced Phase Separation Method (NIPS) for Removal of Aqueous Contaminants

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Direct electrospinning of cellulose in the DBU-CO2 switchable solvent system

Cited by 6 publications

References 51 publications

Direct Evidence for Reaction between Cellulose and CO2 from Nuclear Magnetic Resonance

Direct Evidence for Reaction between Cellulose and CO2 from Nuclear Magnetic Resonance

Closing the Carbon Loop in the Circular Plastics Economy

Valorization of Oil Palm Empty Fruit Bunch (OPEFB) as Membrane Polymer via Non-solvent Induced Phase Separation Method (NIPS) for Removal of Aqueous Contaminants

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Product

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Direct Evidence for Reaction between Cellulose and CO₂ from Nuclear Magnetic Resonance

Direct Evidence for Reaction between Cellulose and CO₂ from Nuclear Magnetic Resonance