Search

Showing total 896,971 results
Start Over Topic materials science Database OpenAIRE
896,971 results

1. Plasmonic Paper-Based Flexible SERS Biosensor for Highly Sensitive Detection of Lactic and Uric Acid

Author

M. Verma, Santosh K. Tripathi, N. Eswara Prasad, Prabhat K. Dwivedi, Tania K. Naqvi, and Manish M. Kulkarni

Subjects
Silver, Materials science, Biomedical Engineering, Metal Nanoparticles, Pharmaceutical Science, Medicine (miscellaneous), Preventive health, Substrate (chemistry), Bioengineering, Nanotechnology, Biosensing Techniques, Paper based, Spectrum Analysis, Raman, Uric Acid, Computer Science Applications, Highly sensitive, Silver mirror, chemistry.chemical_compound, chemistry, Humans, Uric acid, Electrical and Electronic Engineering, Biosensor, Plasmon, Biotechnology
Abstract

Selective detection and quantification of biomarkers related to human diseases are essential for preventive healthcare. Surface-enhanced Raman scattering (SERS) spectroscopy is a powerful analytical tool offering high sensitivity. However, the success of this promising analytical tool relies on the ability to effectively fabricate SERS substrate. Herein we have demonstrated a plasmonic paper-based flexible substrate (PPFS) for SERS sensing. In situ growth of silver nanostructures (AgNS) on the paper-based substrate was achieved by using a simple one-step silver mirror reaction (SMR). FESEM and TEM results depicts that the increasing silver ion content influences the morphology (growth of multifacets), as well as size of AgNS. Further, the PPFS substrate was tested with Rhodamine-6G (Rh-6G) dye and an attomole sensitivity with a LOD of 4.54 x 10-18 M was achieved. Further, two biomarkers, lactic acid (LA) and uric acid (UA) were detected on the PPFS substrate, with μM and pM sensitivity, having LOD values of 0.6 x 10-6 and 0.3 x 10-12 M respectively. Above detection levels for UA on PPFS is two orders better than reported values, whereas for LA it is comparable with reported substrates. Finally, UA, LA and their mixtures were tested on PPFS and results compared with commercial substrate. The performance of PPFS were found better in all cases, thus, multifaceted AgNS paper based PPFS offers the potential to be used as a biosensor for detection of various biomarkers from body fluids, responsible for the detection of the critical disease for preventive health care.

Published
2022

2. Behavior of 4 types of paper with printed QR codes for evaluating denture marking in conditions of extreme heat

Author

Ying-Jie Zhu, Gabriel M Fonseca, Javier Rojas-Torres, and Mara Cea

Subjects
Thermogravimetric analysis, Materials science, Filter paper, Extreme Heat, Heat resistance, 030206 dentistry, Esthetics, Dental, Silicon Dioxide, United States, Polyolefin, Extreme heat, 03 medical and health sciences, chemistry.chemical_compound, 0302 clinical medicine, chemistry, Hydroxyapatites, Oral Surgery, Composite material, Dentures
Abstract

Statement of problem Quick response (QR) codes are a fast and efficient technology for linking and accessing identifying information, and their use has been proposed in forensics. The heat resistance and esthetics of denture marking methods (DMMs) have been recommended by the American Dental Association (ADA), but studies on these aspects of printed QR codes are lacking. Purpose The purpose of this study was to determine the optimal printed material with QR codes for implementation as a DMM adjusted to the recommendations of the ADA. Material and methods The behavior of 4 types of paper, bond paper, fiberglass filter paper, ultralong hydroxyapatite nanowire paper, and polyolefin and silica paper with printed QR codes was analyzed. They were exposed to temperatures between 100 °C and 1000 °C in a heat muffle for 1 hour. Each specimen was subjected to both a morphological and a thermogravimetric analysis (TGA) and scanned by using 3 different smartphones. Results The scans were positive for bond paper (33.3%), fiberglass fiber paper (50%), ultralong hydroxyapatite nanowire paper (100%), and polyolefin and silica paper (70.4%). The TGA revealed continuous decomposition curves (average 16.5 minutes at 624 °C). Conclusions Printed QR codes on ultralong hydroxyapatite nanowire paper appear to be suitable as information reservoirs, even surviving incineration, and may be implemented as a DMM conforming to the ADA recommendations.

Published
2022

3. A Distance-Based Microfluidic Paper-Based Biosensor for Glucose Measurements in Tear Range

Author

Mohsen Rabbani and Samira Allameh

Subjects
Paper, Materials science, business.industry, Microfluidics, Glucose Measurement, Bioengineering, Biosensing Techniques, General Medicine, Microfluidic Analytical Techniques, Applied Microbiology and Biotechnology, Biochemistry, Glucose Oxidase, Paper based biosensor, Glucose, Range (statistics), Optoelectronics, business, Molecular Biology, Horseradish Peroxidase, Distance based, Biotechnology
Abstract

The prevalence of diabetes has increased over the past years. Therefore, developing minimally invasive, user-friendly and cost-effective glucose biosensors is necessary especially in low-income and developing countries. Cellulose paper-based analytical devices have attracted the attention of many researchers due to affordability, not requiring trained personnel, and complex equipment. This paper describes a microfluidic paper-based analytical device for the detection of glucose in tear with the naked eye. The paper-based biosensor fabricated by laser CO2, and GOx/HRP enzymatic solution coupled with TMB was utilized as reagents. A sample volume of 10 µl was needed for the biosensor operation and the results were observable within 5 minutes. To evaluate the device performance, color intensity-based and distance-based results were analyzed by ImageJ and Tracker. Distance-based results showed a linear behavior in the range of 0.1–0.6 mM with an R2 = 0.967 and LOD of 0.2 mM. The results could be perceived by the naked eye without any need to further equipment or trained personnel in a relatively short time (3–5 minutes). Moreover, glucose concentration could be obtained non-invasively by tears collected by this µPAD.

Published
2022

4. Sterilization of paper during crisis

Author

Fwzah H. Alshammari and Hebat-Allah A. Hussein

Subjects
Paper structure, Infection risk, Materials science, Dry heating, Coronavirus disease 2019 (COVID-19), biology, Biophysics, Bacillus cereus, Human decontamination, Contamination, Sterilization (microbiology), Salmonella typhi, biology.organism_classification, Applied Microbiology and Biotechnology, Microbiology, QR1-502, Gamma radiation, Dry heat, Escherichia coli, Food science, Respiratory pathogen, TP248.13-248.65, Gamma irradiation, Biotechnology
Abstract

Paper sheets represent one of the infection risk sources inside educational and administrative institutions under biological pandemics. So, the present study aimed to validate the efficiency of gamma radiation or dry heat techniques to sterilize contaminated paper sheets with different indicator pathogens while retaining their structure. The results showed that gamma radiation at 6, 12, or 24 kGy can successfully kill Gram-positive bacteria such as Bacillus cereus and Staphylococcus aureus, Gram-negative bacteria such as Escherichia coli and Salmonella typhi, and fungi such as Candida albicans. Moreover, dry heating at 100 °C for 60 min, 150 °C for 30 min, or 200 °C for 15 min can be successful in paper decontamination of all tested species. Surprisingly, scanning electron microscopy (SEM) micrographs proved that gamma radiation at 6 kGy, dry heat at 100 °C for 60 min or 150 °C for 30 min or 200 °C for 15 min, is suitable for paper sheet sterilization while maintaining their structure. Ultimately, dry heat is a simple, effective, fast, safe, and inexpensive technique for paper sterilization. It may be used as a precautionary step inside educational institutions, especially during written examination periods, to ensure a safe life for academic members during biological pandemics such as COVID-19.

Published
2022

5. 3D MoS2 foam integrated with carbon paper as binder-free anode for high performance sodium-ion batteries

Author

Kaixin Zhu, Fangying Zheng, Yunchuan Tu, Zeyu Wei, Yan Yang, Jiao Zhao, Yimin Zhu, Huicong Xia, Dehui Deng, Xiangyu Meng, and Jianan Zhang

Subjects
High rate, business.product_category, Materials science, Macropore, Sodium, Energy Engineering and Power Technology, chemistry.chemical_element, Conductivity, Electrochemistry, Anode, Fuel Technology, Chemical engineering, chemistry, Carbon paper, Porosity, business, Energy (miscellaneous)
Abstract

Molybdenum sulfide (MoS2) with well-designed porous structure has the potential to be great electrode materials in sodium-ion batteries due to its high theoretical capacity and abundant resource, however, hindered by its intrinsic low conductivity and stability. Herein, MoS2 with 3D macroporous foam structure and high conductivity was obtained through SiO2 templates and integrated with carbon paper (3D F-MoS2/CP). It has showed superior specific capacity (225 mA h g−1, 0.4–3 V) and cycling stability (1000 cycles) at high rate (2000 mA g−1), with a low decay rate (0.033% per cycle) in sodium-ion batteries. The excellent electrochemical performance may originate from its unique integrated structure: 3D MoS2 macropores providing high surface area and abundant transfer channels while carbon paper enhancing the conductivity of MoS2 and avoiding unnecessary side reactions brought by binder addition.

Published
2022

6. Fire resistant bagasse paper as packaging material using 1,3-di-p-toluidine-2,2,2,4,4,4-hexachlorocyclodiphosph(V)azane with hydroxyethyl cellulose

Author

Salah A.A. Mohamed, A.A. Younis, and Mohamed El-Sakhawy

Subjects
Thermogravimetric analysis, Materials science, Mechanical properties, Oxygen index, Catalysis, law.invention, Limiting oxygen index, Fire resistant, chemistry.chemical_compound, Geochemistry and Petrology, law, UL/94, Ultimate tensile strength, Petroleum refining. Petroleum products, Cellulose, Renewable Energy, Sustainability and the Environment, Process Chemistry and Technology, Organic Chemistry, Azane, Ignition system, Fuel Technology, chemistry, Chemical engineering, Bagasse paper, 1,3-Di-p-toluidine-2,2,2,4,4,4-hexachlorocyclodiphosph(V)azane, Bagasse, TP690-692.5, Hydroxyethyl cellulose
Abstract

This manuscript aimed to enhance the mechanical, thermal, and ignition properties of bagasse paper when coated with different coatings synthesized from hydroxyethyl cellulose, 1,3-di-p-toluidine-2,2,2,4,4,4-hexachlorocyclodiphosph(V)azane, Talc powder, NaHCO3, cellulose nanocrystal. The effect of these coatings on the mechanical properties was studied by measuring elongation, tensile strength, and burst strength. The stages of degradation and ash residue of the measuring specimens were determined using thermal gravimetric analysis (TGA), behind that, the ignition properties as the flame chamber (UL/94), and limiting oxygen index (LOI) was measured according to standards. These tests proved that 1,3-di-p-toluidine-2,2,2,4,4,4-hexachlorocyclodiphosph(V)azane has a direct effect on improving the mechanical characteristics and enhancing the ignition properties of the coated specimens compared to uncoated. In this study the physical, mechanical, thermal, and ignition properties of the bagasse paper sheets were enhanced by easy and low-cost method via synthesis of new coatings based on commercially available chemicals in a reasonable cost.

Published
2021

7. In-situ joule heating-triggered nanopores generation in laser-induced graphene papers for capacitive enhancement

Author

Fu Liu, Guantao Wang, Meihong He, Yanan Wang, Yuxiang Zhu, and Sida Luo

Subjects
Fabrication, Materials science, business.industry, Graphene, Capacitive sensing, General Chemistry, Capacitance, law.invention, Nanopore, Amorphous carbon, law, Optoelectronics, General Materials Science, business, Joule heating, Graphene oxide paper
Abstract

Laser-induced graphene (LIG) technology featuring low-cost, high-efficiency and scalability has presented great advantages in micro-supercapacitors (MSCs) fabrication. However, the limited capacitance of LIG based MSCs is still hindering their further development. Herein, we introduce joule heating as a critical in-situ treatment merged with the assembly of laser-induced graphene paper based MSCs (LIGP-MSCs) toward capacitive enhancement. By increasing heating-treatment temperature from ∼20 to 500 °C, the number of nanopores in LIGP continuously increases, attributed to the gradual decomposition of amorphous carbon components. The resulting joule-heated LIGP (J-LIGP) with improved specific surface area (160.97–533.49 m2/g) and pore volume (0.179–0.553 cm3/g) as well as superhydrophilic surface is highly suitable to be employed as J-LIGP-MSCs microelectrodes. By investigating process dependent performance, the J-LIGP-MSCs heated at 500 °C for 60 min delivers a significantly improved specific areal capacitance (CA) of 13.71 mF/cm2 at 10 mV/s, which is approximately six-fold higher than that of unheated LIGP-MSCs. By further exploring and optimizing the process efficiency, J-LIGP-MSCs with a CA of 12.61 mF/cm2 has been achieved by 550 °C heating for only 5 min. Along with superior mechanical flexibility, cyclability and structural modularity, the proposed in-situ joule heating treatment is finally proved to be a universal approach for consistently enhancing the CA of LIG based MSCs processed under various chemical modifications.

Published
2022

8. Amorphous cobalt-iron decorated carbon paper with nanosheet structure for enhanced oxygen evolution reaction

Author

Zhuangzhuang Liu, Qianqian Jiang, Chengqiang Gan, Bin Wang, Yichi Zhang, and Jianguo Tang

Subjects
Tafel equation, business.product_category, Materials science, General Chemical Engineering, Oxygen evolution, chemistry.chemical_element, Overpotential, Amorphous solid, Chemical engineering, chemistry, Mechanics of Materials, Nano, Carbon paper, business, Cobalt, Nanosheet
Abstract

Tremendous attention has been paid on high efficiency, readily available and stability of electrocatalysts. Herein, we ingenious report a one-step reaction strategy synthesis of CoFe/CP grown on three-dimensional (3D) nanoarray carbon paper (CP) containing non-precious metals for oxygen evolution reaction (OER) with low-cost and unique hierarchical porous structure. This amorphous CoFe/CP hybrid exhibits commendable electrocatalytic performance in the OER process, requiring only overpotential of 278 mV to achieve 10 mAcm−2 in 1.0 M KOH solution and a lower Tafel slope of 49.12 mVdec-1. In addition, this sample shows a long-term durability even at 200 mAcm−2 without obvious decay, which attributes to peculiar multistage graded nano structure and the change of composition at the interface of CP. Therefore, the remarkable OER activity can provide a new strategy to construct potential candidates, which will replace the state-of-the-art precious metals for OER in the future.

Published
2021

9. Paper-based aptamer-antibody biosensor for gluten detection in a deep eutectic solvent (DES)

Author

Cristian Grazioli, Nicolò Dossi, Rosanna Toniolo, and Rossella Svigelj

Subjects
Pregnancy test, Materials science, Glutens, Coronavirus disease 2019 (COVID-19), Aptamer, Nanotechnology, Biosensing Techniques, Paper-based biosensor, Aptamers, Biochemistry, Antibodies, Analytical Chemistry, chemistry.chemical_compound, Deep eutectic solvents, Electrochemical detection, Gluten, Limit of Detection, Humans, Detection limit, chemistry.chemical_classification, COVID-19, Paper based, Aptamers, Nucleotide, Deep eutectic solvent, chemistry, Solvents, Biosensor, Research Paper
Abstract

Paper has been widely employed as cheap material for the development of a great number of sensors such as pregnancy tests, strips to measure blood sugar, and COVID-19 rapid tests. The need for new low-cost analytical devices is growing, and consequently the use of these platforms will be extended to different assays, both for the final consumer and within laboratories. This work describes a paper-based electrochemical sensing platform that uses a paper disc conveniently modified with recognition molecules and a screen-printed carbon electrode (SPCE) to achieve the detection of gluten in a deep eutectic solvent (DES). This is the first method coupling a paper biosensor based on aptamers and antibodies with the DES ethaline. Ethaline proved to be an excellent extraction medium allowing the determination of very low gluten concentrations. The biosensor is appropriate for the determination of gluten with a limit of detection (LOD) of 0.2 mg L−1 of sample; it can detect gluten extracted in DES with a dynamic range between 0.2 and 20 mg L−1 and an intra-assay coefficient of 10.69%. This approach can be of great interest for highly gluten-sensitive people, who suffer from ingestion of gluten quantities well below the legal limit, which is 20 parts per million in foods labeled gluten-free and for which highly sensitive devices are essential. Graphical abstract

Published
2021

10. Optimization of biodegradable paper cup packaging coated with whey protein isolate and rice bran wax as potential popcorn package

Author

Majid Javanmard Dakheli, Sedigheh Ganjizadeh Zavareh, and Behjat Tajeddin

Subjects
business.product_category, Materials science, biology, Nutrition. Foods and food supply, RSM, food and beverages, coating, Paper cup, engineering.material, Whey protein isolate, Coating, engineering, biology.protein, TX341-641, Food science, sense organs, Rice bran wax, business, WVTR, paper cup, snacks, Food Science, Original Research
Abstract

Biodegradable paper cups coated with rice bran wax and whey protein isolate were designed to package popcorn. Coatings with different concentrations of whey protein isolate (5.5, 7.75, and 10% w/v) and rice bran wax (0.2, 0.4, and 0.6% w/v) were applied on the outer surface of the paper cups. Thickness, color changes, Young's modulus and tensile strength, water vapor transmission rate (WVTR) of the coated and uncoated cups, and also popcorns properties (pH, texture, and sensory properties) were evaluated. Water vapor transmission rate, Young's modulus, thickness, total color change index, and tensile strength of coated cups with the optimal coating formulation was 19.785 (g/m2 day), 11.810 (MPa), 276.583 (µm), 1.839, and 11.222 (MPa), respectively. The results showed that paper cup coating increased thickness and yellowness and reduced the brightness, Young's modulus, and WVTR. Coating had a positive effect on the pH and texture of popcorns packaged in coated cups than samples packed in uncoated cups (p, Biodegradable packaging is one of the best types of packaging that wishes not to harm the environment. Paper packaging coated with materials, such as rice bran wax and whey protein isolate, both of which are food waste, can improve paper color and resistance, and provide a good moisture barrier. This type of coating can be used in paper packaging of food such as snacks, noodle packaging, semi‐prepared foods, etc. This type of packaging can also maintain the physicochemical and sensory properties of food for a long time. Also, due to the edible nature of this type of coating, this coating can be used inside the package so that the printability of the packaging surface is not affected.

Published
2021

11. Printability of bio-composite sheets made from paper mill and cardboard mill waste sludge

Author

Ahmet Akgül, Burcu Nilgün Çetiner, Garip Genç, Öznur Özden, Hüseyin Yüce, and Sinan Sönmez

Subjects
Materials science, business.industry, visual_art, Composite number, Materials Chemistry, visual_art.visual_art_medium, Mill, cardboard, Paper mill, business, Pulp and paper industry, Surfaces, Coatings and Films
Abstract

Purpose The purpose of this study is to reveal the usability of waste paper sludge on the production of composite materials and the printability of their surfaces were investigated. Design/methodology/approach First, composite plates were produced by using dried and milled waste sludge together with polyester resin and epoxy. Screen printing using water, solvent and UV-based inks were carried out. Findings It was determined that UV and solvent-based inks in both resin groups were permanently attached to the surface of composite plates produced using paper mill waste sludge, while it was found that the adhesion was not achieved sufficiently in cardboard factory waste sludge. Originality/value The unique aspect of this study is obtained the composite plates from paper mill and cardboard mill waste sludge and improved the printability of them.

Published
2021

12. Toward a Reversible Consolidation of Paper Materials Using Cellulose Nanocrystals

Author

Laura Micheli, Alessandra Operamolla, Claudia Mazzuca, Valter Castelvetro, Andrea Martinelli, Mattia Titubante, L. Capodieci, Francesca Di Benedetto, Leonardo Severini, Operamolla, A., Mazzuca, C., Capodieci, L., Di Benedetto, F., Severini, L., Titubante, M., Martinelli, A., Castelvetro, V., and Micheli, L.

Subjects
Materials science, Nanotechnology, Settore CHIM/06, Nanocellulose, chemistry.chemical_compound, Settore CHIM/01, Settore CHIM/02, amperometric sensors, Ultimate tensile strength, General Materials Science, paper conservation, Cellulose, Fourier transform infrared spectroscopy, Settore CHIM/12 - Chimica dell'Ambiente e dei Beni Culturali, cellulose nanocrystals, cellulose nanocrystals, FT-IR spectroscopy, nanotechnology, amperometric sensors, microscopy, cultural heritage, paper restoration, paper conservation, cultural heritage, FT-IR spectroscopy, microscopy, nanotechnology, paper restoration, Consolidation (soil), chemistry, Compatibility (mechanics), Surface modification, Degradation (geology)
Abstract

An innovative consolidation strategy for degraded paper is presented based on the reversible application of cellulose nanocrystals as sustainable fillers to reinforce mechanical properties and resistance to further degradation. The compatibility and efficacy of the proposed consolidation treatment are assessed first on pure cellulose paper, used as a model, by reliable techniques such as field emission scanning electron microscopy, atomic force microscopy, tensile tests, X-ray powder diffraction, and Fourier transform infrared spectroscopy, evidencing the influence of the surface functionalization of nanocellulose on the consolidation and protection effects. Then, the consolidation technique is applied to real aged paper samples from Breviarium romanum ad usum Fratrum Minorum S.P. (1738), demonstrating the promising potential of the suggested approach. Amperometric measurements, carried out with a smart electrochemical tool developed in our laboratory, demonstrate the reversibility of the proposed treatment by removal of the nanocrystalline cellulose from the paper surface with a suitable cleaning hydrogel. This completely new feature of the consolidation treatment proposed here satisfies a pivotal requisite in cultural heritage conservation because the methodological requirement for the ″reversibility″ of any conservation measure is a fundamental goal for restorers. A paper artifact, in fact, is subject to a number of natural and man-made hazards, inducing continuous degradation. With time, monitoring and consolidation actions need to be often performed to ensure conservation, and this tends to modify the status quo and compromise the artifact integrity. Removable treatments can potentially avoid erosion of the artifact integrity.

Published
2021

13. Eucalyptus Pulp Fibers with In-Situ Precipitated Calcium Carbonate – A 12-Inch Laboratory Paper Machine Study

Author

Bardhyl Bajrami and Klaus Dölle

Subjects
In situ, Materials science, business.product_category, Pulp (paper), engineering.material, Pulp and paper industry, Eucalyptus, chemistry.chemical_compound, Calcium carbonate, Paper machine, chemistry, Filler (materials), engineering, Precipitated calcium carbonate, business, Refining (metallurgy)
Abstract

Paper manufacturing on a global scale is a highly competitive market which requires to constantly improve the manufacturing process to be competitive. To decrease production cost paper manufactures, add filler material prior to sheet forming to replace costly wood fiber based raw material. This research project investigates the use of in-situ precipitated calcium carbonate produced in the presence of eucalyptus fiber material at a 41.0% filler level prior to beating. The in-situ filler containing eucalyptus fiber suspension was used on a 12’ (304mm) wide Laboratory Fourdrinier Paper Machine together with non-filler containing eucalyptus fiber material, and a commercial precipitated calcium carbonate filler material. The manufactured in-situ fiber suspension resulted in a higher ash retention compared to the addition of the powdered commercial PCC filler material. In addition to commercial filler material retention is improved at higher filler addition above 30%. The increased ash retention is linked to the increased micro fibrillation fiber material of the in-situ filler-fiber suspension forming neckless like particles on the fibers microfibrils. Mechanical paper properties showed an improvement for in-situ precipitated filler material compared to commercial filler material addition. Optical properties could be improved in comparison to the eucalyptus fiber without filler addition for in-situ precipitated filler material and a combination of in-situ and commercial filler material.

Published
2021

15. Composite paper from an agricultural waste of bagasse sugarcane and pineapple leaf fibre: a novel random and multilayer hybrid fibre reinforced composite paper

Author

Rohah A. Majid, Arif Fahim Ezzat Chan, Rafidah Rusman, Wira Jazair Yahya, Dayangku Intan Munthoub, Hasannuddin Abd Kadir, and Sarah Salleh

Subjects
Agricultural waste, Materials science, Composite number, General Materials Science, Forestry, Pulp and paper industry, Bagasse, Hybrid fibre
Abstract

Bagasse sugarcane (BSC) has low fibre strength due to low cellulose content. Hence, by adding a strong secondary fibre that is high in cellulose such as pineapple leaf fibre (PALF), the fibre strength of the system can be improved. High portion of PALF decreased the composite paper performance because the high composition of PALF tends to produce flocs and agglomerates fibres. The arrangement of the fibres in composite paper should be improved so that this agglomerate’s effect could be overcome. A novel multilayer hybrid fibre composite was used. BSC/PALF with several hybrid ratios was studied in terms of the mechanical and moisture properties of the produced paper sheet and the results showed that multilayer hybrid composite paper produced higher in hybrid composite paper’s properties compared with random hybrid composite paper. The colour of multilayer hybrid fibre composite paper resembled the natural bright colour of BSC and the multilayer hybrid fibre composite paper also shown a slightly low weight loss percentage compared with the random hybrid fibre composite paper after 60 days of soil burial test. As a conclusion, multilayer hybrid fibre composite produced the stronger interfibre bonding and overcome the agglomerate’s effect between BSC/PALF compared with random hybrid fibre composite.

Published
2021

16. Analyzing the effects of thermal stress on insulator papers by solid-state 13C NMR spectroscopy

Author

Elisabeth Schwaiger, Antje Potthast, Thomas Rosenau, Paul Jusner, Jonas Simon, Florian Bausch, Markus Bacher, Sonja Schiehser, Ivan Sumerskii, and Hajar Khaliliyan

Subjects
Coalescence (physics), chemistry.chemical_compound, Materials science, Polymers and Plastics, chemistry, Transformer oil, Resonance, Insulator (electricity), Thermal treatment, Crystallite, Cellulose, Composite material, Kraft paper
Abstract

Million tons of cellulosic paper have been used for insulating coils in oil-filled electrical power transformers, thereby assuring the electricity supply for our societies. The high working temperatures in transformers constantly degrade paper insulators throughout their service life of up to 40 years. We approached the structural changes in oil-immersed cellulosic paper samples upon thermal stress in a study that compared unbleached softwood Kraft paper used as insulator paper with pure cotton cellulose paper. The model experiments used a thermal treatment in transformer oil at 170 °C for up to 14 days. The samples were characterized by means of 13C CP/MAS NMR spectroscopy, mainly based on deconvolution of the C4 resonance. An automated, fast, and reproducible C4 resonance deconvolution employing the “Peak Analyzer” tool of OriginPro 2020 (OriginLab Corporation, USA) was developed and used to exploit 13C CP/MAS NMR spectroscopy for the characterization of thermally stressed paper samples. Our results show that thermally induced structural changes depend heavily on the composition of paper, that hornification and coalescence of fibrils take place, and that the allomorph composition of cellulose crystallites is altered under the given conditions. Graphical abstract

Published
2021

17. Mechanical and Dynamic Mechanical Analysis of PBO Paper-based Composites

Author

Jian Hu, Jin Long, Ziqi Huang, and Yi Wang

Subjects
Materials science, Polymers and Plastics, business.industry, Honeycomb, Chemical Engineering (miscellaneous), Dynamic mechanical analysis, Paper based, Composite material, Raw material, Aerospace, business
Abstract

Poly ( p-phenylene benzoisoxazole; PBO) paper is a potential raw material for use in honeycomb sandwich composites in the aerospace industry, which are able to sustain high temperatures exceeding 300°C. This work presents a wet-forming method of making PBO paper, consisting of PBO chopped fibers. The paper was impregnated with phenolic resin to simulate honeycomb wall material. The structure and mechanical and dynamic mechanical properties of the raw and impregnated paper were characterized. The performance of PBO paper was tested against p-aramid paper. The comparative results showed the tensile strength of PBO raw paper was 2.17 kN/m, which was slightly worse than p-aramid raw paper: 2.66 kN/m. After impregnation, the tensile strength of the PBO paper was 13.93 kN/m due to the increase in the number of bonding points—better than p-aramid paper: 7.99 kN/m. The tearing resistance value for PBO raw paper versus p-aramid raw paper was 3252 mN against 845 mN. The morphology of the torn samples in the impregnated paper revealed higher levels of PBO fiber pullout than p-aramid fiber, therefore the tearing resistance value was 6000 mN for PBO impregnated paper, which was again superior to p-aramid impregnated paper: 675 mN. The PBO paper also showed higher storage modulus than p-aramid paper after impregnation. Experimental studies showed that PBO paper could be used in load-bearing structures and in honeycomb components where high resistance to deformation and thermal stability is necessary.

Published
2021

18. Characterization of absorbency properties on tissue paper materials with and without 'deco' and 'micro' embossing patterns

Author

Ana M. M. S. Carta, Joana M. R. Curto, Joana Vieira, Paulo Torrão Fiadeiro, Ana Paula Cabral Seixas Costa, Flávia P. Morais, Maria Emília Amaral, and António de Oliveira Mendes

Subjects
Materials science, Absorption of water, Polymers and Plastics, Kraft process, Capillary action, Fiber, Composite material, Porosity, Embossing, Characterization (materials science), Tissue paper
Abstract

Water absorption is a key property in several tissue paper materials and can be a differentiating factor in terms of consumer choice. The converting modifications applied in the tissue industry can improved absorbency properties. For this purpose, the main goal of the present work is to study the influence of “deco” and “micro” embossing on water absorption capacity, Klemm capillary rise, and liquid spreading kinetics in tissue papers. An industrial never-dried bleached eucalyptus kraft pulp, a creped industrial base tissue paper, and a disintegrated fibrous suspension obtained from the same industrial paper were used to produce structures with and without “deco” and “micro” embossing patterns. The results indicate that the “micro” embossing process promoted bulky and porous structures, enhancing water absorption capacity and Klemm capillary rise properties, while the “dec” embossing pattern decreased water absorption capacity properties. The creping process also increased the water absorption capacity but decreased Klemm capillary rise properties along with the fiber mixtures. Regarding the liquid spreading kinetics, both embossing patterns decreased this property in uncreped isotropic structures, contrary to creped anisotropic structures. The eucalyptus and softwood fibers mixture improved the spreading kinetics compared to the creping process. The performance of structures with and without embossing allowed to quantify the liquid retention properties, combining ISO experimental methods and an optical system that records the liquid interaction with fibrous structures. In conclusion, this laboratory embossing method can be used as an alternative method to optimize converting operations and the final tissue paper characterization, on a laboratory scale.

Published
2021

19. Preparation of eco-friendly wax-coated paper and its rheological and water-resistant characteristics

Author

Kwang-Hee Lim and Eun Ju Lee

Subjects
Dilatant, Coated paper, Wax, Shear thinning, Materials science, General Chemical Engineering, General Chemistry, Shear rate, Viscosity, Paraffin wax, visual_art, Ultimate tensile strength, visual_art.visual_art_medium, Composite material
Abstract

The blend (wax M) of crude by-product polyolefin wax (wax K) and a fractionated commercial paraffin wax (wax J) was suggested to replace the wax J as a coating agent for wax-coated papers. The rheological properties of waxes J, K, and M were examined and compared. The correlation between viscosity and shear rate applied on these waxes maintained at 90 oC and 130 oC was identified. In particular, this paper, for the first time, presented non-Newtonian shear thinning behavior of not only wax K but also its blend of wax M in terms of their viscosity affected by shear rate at an operating temperature below their melting temperature of higher-melting-temperature DSC endothermic peaks (HMTEPs). They showed non-Newtonian behavior, so-called shear thinning behavior, at 90 oC in the light of characteristics of both suspension systems and polymer systems. In addition, the profiles of viscosity at 130 oC of all the waxes versus the shear rate exhibited Newtonian fluid behavior. Wax J also showed the behavior of a dilatant fluid. Then, the physical properties including water vapor transmission rates (WVTR), surface roughness, and coated weights, of thin papers coated with waxes J (WJP), K (WKP), and M (WMP) were evaluated, characterized, and compared. As a result, WMP had an equivalent value to that of WJP or the lowest value among wax-coated papers in terms of WVTR. The surface roughness and the barrier property of WVTR were minimized and enhanced, respectively, by blending waxes J and K. The additional physical properties, including dynamic contact angles, surface tension, wet and dry tensile strength, optical examination of the wax-coated fiber structure, and antimicrobial properties of the wax-coated papers, were evaluated. The excellent antimicrobial properties of clinoptilolite added to wax J or wax M appeared.

Published
2021

20. Role of cellulose nanofibrils in improving the strength properties of paper: a review

Author

Thabisile Brightwell Jele, Bruce Sithole, and Prabashni Lekha

Subjects
Materials science, Polymers and Plastics, Papermaking, Modulus, Stiffness, Paper quality, Crystallinity, chemistry.chemical_compound, chemistry, Ultimate tensile strength, medicine, Composite material, medicine.symptom, Cellulose
Abstract

The pursuit for sustainability in the papermaking industry calls for the elimination or reduction of synthetic additives and the exploration of renewable and biodegradable alternatives. Cellulose nanofibrils (CNFs), due to their inherent morphological and biochemical properties, are an excellent alternative to synthetic additives. These properties enable CNFs to improve the mechanical, functional, and barrier properties of different types of paper. The nanosize diameter, micrometre length, semicrystalline structure, high strength, and modulus of CNFs have a direct influence on the mechanical properties of paper, such as tensile index, burst index, Scott index, breaking length, tear index, Z-strength, E-modulus, strain at break, and tensile stiffness. This review details the role played by CNFs as an additive to improve strength properties of paper and the factors affecting the improvement in paper quality when CNFs are added as additives. The paper also includes techno-economic aspects of the process and identifies areas that need further research.

Published
2021

21. Mechanical performance of nano-silica modified insulating paper with mechanical-thermal synergy

Author

Yongjin Yu, Xu Kong, and Changyun Li

Subjects
Materials science, Mechanics of Materials, Mechanical Engineering, Thermal, Nano, Electrical insulation paper, Electrical and Electronic Engineering, Composite material, Condensed Matter Physics, Electronic, Optical and Magnetic Materials
Abstract

In this paper, the mechanical properties of nano-silica modified insulating paper under the combined action of mechanical vibration and temperature conditions are studied. Unmodified and nano-silica modified cellulose insulating paper with 2 wt% and 4 wt% were prepared, respectively, and a series of mechanical-thermal synergy experiments were carried out. With the same mechanical stress and temperature, and with the same aging duration of 144 h (6d), the tensile strength of modified insulating paper with 4 wt% nano-silica, increased 0.99 kN/m and 0.55 kN/m, respectively, compared with those of the unmodified and the 2 wt% nano-silica modified insulating paper. The experiments indicate that the nano-silica modification can effectively improve the mechanical properties of insulating paper. In this work, the modified mechanism of nano-silica is analyzed from the interface effect of modified polymer and the quantum effect of the modified polymer interface two aspects. It is shown that the interface formed in the modified insulating paper can transfer the mechanical stress acted on the insulating paper and prevent the cracks formed in the aging process of the test sample from further expansion, while the quantum effect discretizes the electron energy level, which can restrict the motion of the molecular chain segment to some extent. The conclusion can be used for reference to improve the performance of insulating paper.

Published
2021

22. High strength, flexible, and conductive graphene/polypropylene fiber paper fabricated via papermaking process

Author

Quanbo Huang, Wenjiao Ge, Shan Cao, Yang Yang, and Xiaohui Wang

Subjects
Polypropylene, Materials science, Polymers and Plastics, Graphene, Materials Science (miscellaneous), Papermaking, Composite number, Conductivity, law.invention, chemistry.chemical_compound, Synthetic fiber, chemistry, law, Materials Chemistry, Ceramics and Composites, Fiber, Composite material, Graphene oxide paper
Abstract

Graphene paper with good mechanical strength, flexibility, and high conductivity is an emerging functional material for wide applications, but its feasible and scalable preparation remains a challenge. Herein, a high strength, flexible, and conductive graphene/polypropylene (PP) fiber paper was prepared by a traditional papermaking process. In the composite paper, graphene nanosheets were well stabilized on the PP fibers forming a stable three-dimensional conductive interleaved network. Chitosan was found able to build a polar active interface on PP fibers and graphene nanosheets, which can not only promote PP fiber dispersion in water yielding a uniform pulp, but also favor the retention of graphene in the composite paper. As a result, the composite paper presents high strength (15.32 MPa), good conductivity (11,995 S/m), shielding effectiveness (31.1 dB), water resistance, fungi-proof, and thermal conductivity (10.17 W m−1 k−1) properties. This work demonstrates the feasibility of large-scale preparation of graphene composite paper with commercial synthetic fibers through a traditional papermaking process, and expands the potential industrial application of graphene materials. Graphene/chitosan co-aggregates were absorbed on the surface of graphene/chitosan/PP fiber under the electrostatic interaction of CPAM to form graphene/PP fiber.

Published
2021

23. Preparation and application of water-based nano-silver conductive ink in paper-based 3D printing

Author

Lini Lu, Jun Wang, and Chenfei Zhao

Subjects
Rapid prototyping, Materials science, business.industry, Mechanical Engineering, Conductive ink, Silver Nano, 3D printing, Nanotechnology, Paper based, business, Industrial and Manufacturing Engineering, Water based
Abstract

Purpose In flexible electronics applications, organic inks are mostly used for inkjet printing. Three-dimensional (3 D) printing technology has the advantages of low cost, high speed and good precision in modern electronic printing. The purpose of this study is to solve the high cost of traditional printing and the pollution emissions of organic ink. It is necessary to develop a water-based conductive ink that is easily degradable and can be 3 D printed. A nano-silver ink printed circuit pattern with high precision, high conductivity and good mechanical properties is a promising strategy. Design/methodology/approach The researched nano-silver conductive ink is mainly composed of silver nanoparticles and resin. The effect of adding methyl cellulose on the ink was also explored. A simple 3 D circuit pattern was printed on photographic paper. The line width, line length, line thickness and conductivity of the printed circuit were tested. The influence of sintering temperature and sintering time on pattern resistivity was studied. The relationship between circuit pattern bending performance and electrical conductivity is analyzed. Findings The experimental results show that the ink has the characteristics of low silver content and good environmental protection effect. The printing feasibility of 3 D printing circuit patterns on paper substrates was confirmed. The best printing temperature is 160°C–180°C, and the best sintering time is 30 min. The circuit pattern can be folded 120°, and the cycle is folded more than 60 times. The minimum resistivity of the circuit pattern is 6.07 µΩ·cm. Methyl cellulose can control the viscosity of the ink. The mechanical properties of the pattern have been improved. The printing method of 3 D printing can significantly reduce the sintering time and temperature of the conductive ink. These findings may provide innovation for the flexible electronics industry and pave the way for alternatives to cost-effective solutions. Originality/value In this study, direct ink writing technology was used to print circuit patterns on paper substrates. This process is simple and convenient and can control the thickness of the ink layer. The ink material is nonpolluting to the environment. Nano-silver ink has suitable viscosity and pH value. It can meet the requirements of pneumatic 3 D printers. The method has the characteristics of simple process, fast forming, low cost and high environmental friendliness.

Published
2021

24. Shear Strength Behavior of Sand Reinforced by Kraft Paper Using the Ring Shear Apparatus

Author

Wan-li Xie, Nelson N.S. Chou, Maosheng Zhang, Rongsen Zhu, and Qianyi Guo

Subjects
Materials science, Article Subject, Plane (geometry), Engineering (General). Civil engineering (General), Shear (sheet metal), Friction angle, Perpendicular, Cohesion (geology), Shear strength, TA1-2040, Composite material, Reinforcement, Kraft paper, Civil and Structural Engineering
Abstract

To explore the reinforcement effects of different reinforcement methods, kraft paper was used as reinforcement material, and shear tests were carried out in sand to study the reinforcement effects of kraft paper perpendicular and parallel to the shear plane. The test results show that the two reinforcement methods can effectively improve the strength of sand and the orthogonal reinforcement form is more superior. The existence of reinforced materials greatly improves the cohesion of sand, but does not significantly improve the internal friction angle. The width of reinforcement material has little effect on the reinforcement effect and shows different variation laws under different reinforcement forms.

Published
2021

25. Programmable-Printing Paper-Based Device with a MoS2 NP and Gmp/Eu-Cit Fluorescence Couple for Ratiometric Tetracycline Analysis in Various Natural Samples

Author

Xiaobo Zou, Xuechao Xu, Zeng Niu, Zongbao Sun, Yunlong Gao, Haodong Pan, and Wen Zhang

Subjects
Fluid Flow and Transfer Processes, Materials science, Quenching (fluorescence), business.industry, Process Chemistry and Technology, Process (computing), Bioengineering, Paper based, Sense (electronics), Smartphone application, River water, Fluorescence, Optoelectronics, business, Instrumentation
Abstract

Paper-based fluorescence devices, with smartphone aids, bring considerable operation convenience for tetracycline (TC) sensing. Nevertheless, they must meet the challenge in real determination against complicated backgrounds. Considering that, we present a programmable-printing paper-based device and then apply it to TC determination for various natural samples. MoS2 NPs and Gmp/Eu-Cit are synthetized as composite probes. A static quenching process is found with MoS2 NP fluorescence at 430 nm, while significant magnification of Gmp/Eu-Cit emission is obtained at 617 nm, establishing a valuable ratiometric indicator. Remarkably, two-stage programmable printing maximizes the proposed sensing capability. A transitive device, containing a gradually changing amount of a certain probe, is prepared to sense TC. With a homemade smartphone application and 3D-printed measurement chamber, the corresponding signals are examined to explore optimal setups. These setups are automatically processed to prepare the final-version device, not requiring manual operations. Benefitting from this interesting feature, the proposed device gains many rewards in performances. It effectively senses TC in a wide range from 12.7 nM to 80 μM and simultaneously provides naked eye-legible signals and smartphone-based readouts with confident selectivity and stability. This device is consequently applied for various samples of soil, river water, milk, and serum and meets well with HPLC-MS and recovery tests.

Published
2021

26. Regulating the Deformation Properties of Paper by Varying the Degree of Its Anisotropy

Author

Anastasiia N. Potasheva, B.P. Techpap Sas, Yakov V. Kazakov, and Didier Rech

Subjects
Materials science, Tension (physics), Ultimate tensile strength, medicine, Stiffness, Deformation (meteorology), medicine.symptom, Composite material, Anisotropy, Elastic modulus, Kraft paper, Tensile testing
Abstract

Mechanical properties are crucial in assessing the paper quality. Deformation and strength properties of paper are determined by the strength and stiffness of the interfiber and intermolecular hydrogen bonds. The contribution ratio of interfiber and intermolecular hydrogen bonds to the strength of paper can be changed by adjusting the degree of its anisotropy. The article presents the results on a study of the deformation properties of laboratory anisotropic paper samples from kraft bleached softwood pulp with a beating degree of 30 °SR. The samples had basic weight of 90 g/m2 and the degree of stiffness anisotropy TSIMD/CD of 1.75–4.08. They were made by using Techpap SAS automatic dynamic handsheet former (Grenoble, France), with varying forming parameters – diameter of the nozzle, motion speed of the forming wire, and injecting speed of pulp. Deformation properties were determined by tensile test and processing of the stress-strain dependence (σ−ε). The outcomes have shown that, an increase of the fiber orientation degree in paper structure by changing the forming parameters caused a change in the nature of the paper deformation under tension. Increasing the fiber orientation degree in the structure of paper made it possible to increase the strength by 55 %, tensile stiffness by 63 % in the machine direction, while reducing the extensibility by 10 %. In the cross direction, it was possible to decrease tensile stiffness by 33 %, strength by 55 %, and increase the extensibility by 5 %. Anisotropy of tensile strength was 1.73–6.00. The greatest effect was obtained for the elasticity modulus in the pre-failure zone E2 (2.8–38.6). It means that, fiber orientation had a key importance when large deformations in the samples took place. The established quantitative regularities allowed optimizing the values of the deformation and strength properties of paper, and their ratio in the machine direction and cross direction due to the variation of the forming parameters. For citation: Rech D., Potasheva A.N., Kazakov Ya.V. Regulating the Deformation Properties of Paper by Varying the Degree of Its Anisotropy. Lesnoy Zhurnal [Russian Forestry Journal], 2021, no. 5, pp. 174–184. DOI: 10.37482/0536-1036-2021-5-174-184

Published
2021

27. Shape-Designable and Reconfigurable All-Paper Sensor through the Sandwich Architecture for Pressure/Proximity Detection

Author

Xiaoli Zhao, Yanhong Tong, Ruimin Zhang, Yichun Liu, Xue Wang, Pengfei Zhao, Tao Zhang, and Qingxin Tang

Subjects
Flexibility (engineering), Materials science, Cost effectiveness, Capacitive sensing, Proximity sensor, Electronic engineering, Control reconfiguration, General Materials Science, Omnidirectional antenna, Pressure sensor, Tissue paper
Abstract

All-paper sensors that are capable of free cutting and folding maximize the merits of papers, which fully utilize the unique potential of papers in cost effectiveness, flexibility, disposability, biodegradability, and a flexible design. However, most of the paper sensors have applied metals as the electrodes and polyimide/polydimethylsiloxane as the encapsulation/sensitive layers, limiting the advantages of the paper sensor. In this work, an all-paper, shape-designable, and reconfigurable capacitive pressure/proximity sensor is fabricated with multilayered tissue paper as the dielectric and polypyrrole printer paper as the electrode/encapsulation. Without the restriction of heterogeneous materials, the all-paper components enable the sensors' flexible shape design for freely cuttable and foldable 2D and 3D sensors including a 2D braille keyboard and even allow reconfiguration from a 3D box sensor to a 3D candy sensor. The all-paper sensor presents superior pressure-sensing performance (0.96 kPa-1 at

Published
2021

28. Microscopic Reaction Mechanisms of Formic Acid Generated During Pyrolysis of Cellulosic Insulating Paper

Author

Zijian Wang, Chenvao Liu, Hanbo Zheng, Enchen Yang, Wei Yao, Xufan Li, and Tao Yana

Subjects
Materials science, Formic acid, Electrical insulation paper, Accelerated aging, chemistry.chemical_compound, Chemical engineering, chemistry, Cellulosic ethanol, Silanization, mental disorders, Electrical and Electronic Engineering, Cellulose, ReaxFF, Pyrolysis
Abstract

Cellulosic insulating paper is the essential component of the insulation in power transformers. Under the thermal stress inside the transformer, the cellulosic insulating paper degrades and generates formic acid. Meanwhile, the presence of formic acid further accelerates the aging process of cellulosic insulating paper. This study takes the cellulose molecule composed of D-glucose as the research object. The ReaxFF reactive force field is applied to simulate the high-temperature thermal aging process of cellulosic insulating paper. During pyrolysis process, the number of formic acid molecules presents short-term fluctuations and continuous increases. Though simulation, the main reaction pathways of cellulose pyrolysis to generate formic acid are obtained. In addition, an accelerated thermal aging experiment of oil-paper insulation is designed. The formic acid in the experimental samples is detected by the silanization derivatization method. Through the combination of simulation and experimental results, the feasibility of formic acid as an aging indicator for cellulosic insulating paper is further demonstrated.

Published
2021

29. Electrochemical Microfluidic Paper-Based Aptasensor Platform Based on a Biotin–Streptavidin System for Label-Free Detection of Biomarkers

Author

Juntao Liu, Shuai Sun, Gang Mao, Fanli Kong, Jinping Luo, Yu Xing, Hongyan Jin, Yan Cheng, Ming Tao, and Xinxia Cai

Subjects
Paper, Streptavidin, Materials science, Working electrode, Aptamer, Microfluidics, Immobilized Nucleic Acids, Biotin, Metal Nanoparticles, Nanotechnology, Biosensing Techniques, Thionine, chemistry.chemical_compound, Limit of Detection, Phenothiazines, Humans, General Materials Science, Electrodes, Detection limit, Chitosan, Estradiol, Electrochemical Techniques, Aptamers, Nucleotide, Microfluidic Analytical Techniques, Linear range, chemistry, Colloidal gold, Graphite, Gold, Biomarkers
Abstract

Timely and rapid detection of biomarkers is extremely important for the diagnosis and treatment of diseases. However, going to the hospital to test biomarkers is the most common way. People need to spend a lot of money and time on various tests for potential disease detection. To make the detection more convenient and affordable, we propose a paper-based aptasensor platform in this work. This device is based on a cellulose paper, on which a three-electrode system and microfluidic channels are fabricated. Meanwhile, novel nanomaterials consisting of amino redox graphene/thionine/streptavidin-modified gold nanoparticles/chitosan are synthesized and modified on the working electrode of the device. Through the biotin-streptavidin system, the aptamer whose 5'end is modified with biotin can be firmly immobilized on the electrode. The detection principle is that the current generated by the nanomaterials decreases proportionally to the concentration of targets owing to the combination of the biomarker and its aptamer. 17β-Estradiol (17β-E2), as one of the widely used diagnostic biomarkers of various clinical conditions, is adopted for verifying the performance of the platform. The experimental results demonstrated that this device enables the determination of 17β-E2 in a wide linear range of concentrations of 10 pg mL-1 to 100 ng mL-1 and the limit of detection is 10 pg mL-1 (S/N = 3). Moreover, it enables the detection of targets in clinical serum samples, demonstrating its potential to be a disposable and convenient integrated platform for detecting various biomarkers.

Published
2021

30. Enhanced Conductivity and Flexibility in Reduced Graphene Oxide Paper by Combined Chemical-Thermal Reduction

Author

Kai Gao, Jiale Yang, Honglie Shen, Yan Yang, Xueming Ren, and Zehui Wang

Subjects
Materials science, Graphene, Scanning electron microscope, Oxide, Conductivity, Nanoindentation, Condensed Matter Physics, Electronic, Optical and Magnetic Materials, law.invention, chemistry.chemical_compound, chemistry, law, Electrical resistivity and conductivity, Materials Chemistry, Electrical and Electronic Engineering, Composite material, Thin film, Graphene oxide paper
Abstract

Free-standing reduced graphene oxide (rGO) papers were prepared by chemical reduction, thermal reduction and combined chemical-thermal reduction, respectively. Four-point probe and nanoindentation experiments were conducted to investigate the electrical and mechanical properties of rGO papers. The rGO paper prepared by soaking in L-ascorbic acid and thermal annealing in argon at 1000 °C (labeled rGO-AsA-T) showed superior electrical and mechanical properties when compared with rGO papers prepared merely by chemical reduction or thermal reduction. The as-prepared rGO-AsA-T paper exhibited an electrical conductivity of 5.7 × 104 S/m, showing an increase of 90% compared to that in the thermally annealed rGO paper and nearly 40 times that of rGO paper reduced by L-ascorbic acid. It was also found that the rGO-AsA-T paper had the lowest elastic modulus of 288 MPa, showing enhanced flexibility. The nearly free voids in rGO-AsA-T paper proved by scanning electron microscopy (SEM) were due to the capillary action in chemical reduction and were significant in improving the electrical conductivity and flexibility of the paper. The rGO-AsA-T paper with high conductivity and flexibility has a promising application in flexible electronics.

Published
2021

31. Self-assembled graphene oxide-based paper/hollow sphere hybrid with strong bonding strength

Author

Fan Wu, Yue Zhao, Ben Jiang, Chao Sui, Chao Wang, Junjiao Li, Huifeng Tan, Yifan Zhao, and Miao Linlin

Subjects
chemistry.chemical_classification, Materials science, Scanning electron microscope, Graphene, Oxide, Nanotechnology, 02 engineering and technology, General Chemistry, Polymer, 010402 general chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, 0104 chemical sciences, Nanomaterials, law.invention, chemistry.chemical_compound, Molecular dynamics, chemistry, law, General Materials Science, Wetting, 0210 nano-technology, Graphene oxide paper
Abstract

Graphene-based nanomaterials possess broad applications because of their excellent multi-functional properties. In this work, a facile self-assembling method was presented for preparing one kind of graphene oxide-based paper/hollow microspheres hybrid. It was found that most of the hollow microspheres can strongly anchored on the surface of graphene oxide paper (GOP) by an in-situ scanning electron microscope peeling testing combining with molecular dynamics (MD) simulation. In addition, the uniform distribution of hollow microspheres on the surface of GOP cannot only provide a better surface wettability, but also can effectively improve the interfacial stress-transfer capability between such hybrid and polymer matrix. Our work provides a guidance for the structural designs of graphene-based nanomaterials and broaden their applications.

Published
2021

32. Filter paper method for suction measurement using electrical resistivity

Author

Eng Choon Leong, Hossam Abuel-Naga, and S. Bulolo

Subjects
Materials science, Suction, Filter paper, Electrical resistivity and conductivity, Acoustics, Earth and Planetary Sciences (miscellaneous), Measure (physics), Range (statistics), Geotechnical Engineering and Engineering Geology
Abstract

The filter paper method is an economical, easily accessible, and simple-to-use method to measure total or matric suction over a wide suction range. Difficulty in handling the filter paper can result in inaccurate water content determination of the filter paper leading to poor estimation of the suction. This paper examines the feasibility of using electrical resistivity of the filter paper in the non-contact mode to determine equilibrium time and to infer the total suction. It was shown that for a specific set-up, electrical resistance (ER) can be used in place of electrical resistivity. Relationships between ER and water content of the filter paper and between ER and total suction were first established. Finally, a prototype set-up is used to demonstrate how it can be used to measure the total suction of soil specimens. It was demonstrated that ER of the filter paper can be used to provide a reasonable estimate of total suction greater than 100 kPa with an error between −18 and +10%. Better accuracy can be achieved if each filter paper is calibrated before use.

Published
2021

33. Cr2O3–TiO2-Modified Filter Paper-Based Portable Nanosensors for Optical and Colorimetric Detection of Hydrogen Peroxide

Author

Sohail Nadeem, Yaqeen Ali, Muhammad Yaqoob Javed, Akhtar Hayat, Sidra Rashid, Sundas Jamil, and Muhammad Nasir

Subjects
Detection limit, Materials science, Filter paper, business.industry, General Chemical Engineering, General Chemistry, Article, Matrix (chemical analysis), Chemistry, Transducer, Linear range, Nanosensor, Figure of merit, RGB color model, Optoelectronics, business, QD1-999
Abstract

In the present approach, a Cr2O3-TiO2-modified, portable, and biomimetic nanosensor was designed to meet the requirement of a robust and colorimetric sensing of hydrogen peroxide. Cr2O3-TiO2 nanocomposites prepared via the hydrothermal method were fabricated as a transducer surface on the filter paper using the sol-gel matrix. The color on the filter paper sensor changed from green to blue upon the addition of hydrogen peroxide in the presence of TMB. This change in the color intensity was linear with the concentration of H2O2. RGB software was used as a color analyzing model to evaluate the optical signals. This paper-based colorimetric platform provided us with an improved analytical figure of merit with a linear range of 0.005-100 μM with 0.003 μM limit of detection. The real sample analysis and excellent anti-interference potential results proved the good analytical performance of the proposed design, providing a more promising tool for colorimetric H2O2 detection. Introducing Cr2O3-TiO2 nanocomposite-based paper sensors, being a novel method for optical and colorimetric detection, can pave the way for the development of other sensing devices for the detection of different analytes.

Published
2021

34. Soft actuators built from cellulose paper: A review on actuation, material, fabrication, and applications

Author

Yan Liu, Bin Yin, Peng Wang, Shuting Mo, Siyao Shang, and Jiaming Wei

Subjects
Materials science, Fabrication, Bionics, Materials Science (miscellaneous), Soft actuator, Mechanical engineering, 02 engineering and technology, 010402 general chemistry, 01 natural sciences, Material, Biomaterials, chemistry.chemical_compound, Electronics, Cellulose, Materials of engineering and construction. Mechanics of materials, Programmable action, 021001 nanoscience & nanotechnology, Actuation mechanism, Flexible electronics, 0104 chemical sciences, Electronic, Optical and Magnetic Materials, chemistry, Grippers, Ceramics and Composites, TA401-492, Robot, Cellulose paper, 0210 nano-technology, Actuator
Abstract

Cellulose paper, a material that is naturally derived, low cost, lightweight, eco-friendly, and mechanically deformable, plays important roles in producing next-generation flexible electronics. Following the booms in the development of functional electronics, the soft actuators built from cellulose paper have attracted great attention. In this focused review, the milestones and recent achievements of cellulose paper-based actuators are summarized. Electro-, thermal, moisture and magnetic actuation mechanisms are utilized to acquire energy from external stimuli. Corresponding functional materials and available fabrication techniques like film assembly and layer deposition are described. Programmable actions for the emerging applications in bionics, paper grippers and robots are realized by pursuing different strategies to control the responding deformation. Along with a conclusion, the existing challenges and possible solutions in evaluating and improving the performance of cellulose paper are summarized in the final section.

Published
2021

35. Research on low temperature performance of ZnO/SiO2 composite superhydrophobic paper mulch

Author

Qiang He, Zhang Fangyuan, Kangshuai Li, Fengwei Zhang, Anling Li, and Shuaiyang Ren

Subjects
Delayed icing, Materials science, Mining engineering. Metallurgy, Scanning electron microscope, Composite number, Low temperature environment, Metals and Alloys, TN1-997, chemistry.chemical_element, Zinc, Microstructure, Paper mulch, Surfaces, Coatings and Films, Biomaterials, Contact angle, chemistry, Ceramics and Composites, Transmittance, Bouncing, Composite material, Mulch, Superhydrophobic, Self-cleaning, Icing
Abstract

Paper mulch has the advantages of simple process, low production cost and strong degradability, but it is still a great challenge to prepare paper mulch with excellent water resistance and light transmittance. In this paper, through a simple physical brushing method, Zinc oxide (ZnO) solution and silica (SiO2) solution were brushed on the surface of paper mulch film respectively, and ZnO/SiO2 composite superhydrophobic paper mulch film (CSPMF) with micro-nano rough structure was constructed. The microstructure of original paper mulch film (OPMF) and ZnO/SiO2 CSPMF was studied by scanning electron microscope (SEM), and the superhydrophobic surface elements were analyzed by energy dispersive spectrometer (EDS). The contact angle (CA) and rolling angle (RA) of two kinds of sample surfaces are measured by contact angle meter. The static CA and RA of ZnO/SiO2 CSPMF were 160 ± 0.4° and 3 ± 0.3°, respectively. The self-cleaning behavior of soil simulated dust environment was tested on the surface of OPMF and ZnO/SiO2 CSPMF respectively. The horizontal bounce performance and tilt bounce performance of the superhydrophobic surface were tested by high-speed camera. In addition, frost experiments and delayed icing experiments were carried out. The results show that ZnO/SiO2 CSPMF has good self-cleaning performance, bouncing performance and delayed icing performance.

Published
2021

36. Electrochemical fabrication of polyaniline/graphene paper (PANI/GP) supercapacitor electrode materials on free-standing flexible graphene paper

Author

Jia Chu, Zhen Li, Fengyan Lv, Ming Gong, Zhongfu Yang, Xiaoqin Wang, Shanxin Xiong, Cheng Yang, Bohua Wu, Runlan Zhang, and Changyong Zhu

Subjects
Supercapacitor, Materials science, Fabrication, Polymers and Plastics, Organic Chemistry, Nanotechnology, 02 engineering and technology, Substrate (electronics), 010402 general chemistry, 021001 nanoscience & nanotechnology, Electrochemistry, 01 natural sciences, Energy storage, 0104 chemical sciences, chemistry.chemical_compound, chemistry, Electrode, Polyaniline, Materials Chemistry, 0210 nano-technology, Graphene oxide paper
Abstract

Free-standing flexible supercapacitive electrodes have practical application for wearable energy storage devices. In this paper, graphene paper (GP), a flexible electrode substrate, was prepared by one-step reduction of graphene oxide (GO) using HI solution. GP can be used independently as a flexible electrode with specific capacitance of 227 F/g. In order to make up for the shortage of GP specific capacitance storage, polyaniline (PANI) with high specific capacitance and good electrical conductivity was selected to composite with GP by electrochemical polymerization approach. This method to fabricate electrode material by direct electrochemical polymerization avoids the use of conductive binder and organic solvent. Owing to the specific capacitance contribution of PANI and GP, the PANI/GP composites exhibit higher specific capacitance when the polymerization time is 30 s and the polymerization voltage is 0.8 V. At 1 A/g current density, the specific capacitance of composite is up to 759 F/g, which is 3.34 times of neat GP.

Published
2021

37. Production and Characterization of Paper Board Mill ETP Sludge Derived Hydrochar

Author

P. Balasubramaniam, M. Maheswari, J. Ejilane, K. Sabarish, and S. Paul Sebastian

Subjects
Adsorption, Materials science, Materials Chemistry, Production (economics), Mill, Point of zero charge, Pulp and paper industry, Characterization (materials science)
Abstract

Hydrothermal Carbonization an emerging technology for the conversion of biomass into carbon rich materials called as hydrochar. In this study, the paper board mill ETP sludge has been used for the production of hydrochar. The characterization of point of zero charge, Heavy metals, proximate and ultimate constituents, structural morphology (SEM), and molecular surface functionalities (FTIR) were also analysed. The results of Hydrochar showed slightly acidic pH (6.40), EC (1.33), and the pHPZC (point of zero charge) of 7.8 and the heavy metals content were found to be below detectable limit. FTIR analysis revealed that, the produced hydrochar have oxygen containing functional groups (-OH, C-O-C, -C=O). SEM analysis has the morphological features such as spongy, fuzzy and fluffy porous network on surfaces. These results of hydrochar can be act as an active adsorbent with further activation.

Published
2021

38. Study on the Use of Coating Pigment for Inkjet Printing (I) : Effect of Zeolite Particle Size on the Rheological Properties of Coating Color and Coated Paper Quality for Inkjet Printing

Author

Yong-Kyu Lee and Min-Je Kim

Subjects
Coated paper, Materials science, General Chemistry, engineering.material, Pigment, Rheology, Chemical engineering, Coating, visual_art, Media Technology, engineering, visual_art.visual_art_medium, General Materials Science, Particle size, Zeolite, Inkjet printing
Published
2021

39. Aligned Co3O4–CoOOH heterostructure nanosheet arrays grown on carbon paper with oxygen vacancies for enhanced and robust oxygen evolution

Author

Bing Zhang and Liang Yan

Subjects
Materials science, business.product_category, Renewable Energy, Sustainability and the Environment, Rational design, Oxygen evolution, Energy Engineering and Power Technology, chemistry.chemical_element, Nanotechnology, Heterojunction, Condensed Matter Physics, Oxygen, Metal, Fuel Technology, chemistry, visual_art, visual_art.visual_art_medium, Carbon paper, business, Nanosheet
Abstract

Developing efficient and stable non-noble metal oxygen evolution reaction (OER) electrocatalysts for sustainable overall water-splitting is extremely desirable but still a great challenge. Herein, we developed a facile strategy to fabricate Co3O4–CoOOH heterostructure nanosheet arrays with oxygen vacancies grown on carbon paper (Co3O4–CoOOH/CP). Benefiting from the unique 3D architecture, large surface area, synergistic effects between Co3O4, CoOOH and oxygen vacancies, the obtained self-supporting Co3O4–CoOOH/CP presents excellent electrocatalytic OER activity (low overpotentials of 245 and 390 mV at 10 and 100 mA cm−2) and robust long-term stability in alkaline condition. The present strategy provides the opportunities for the future rational design and discovery of high-performance non-noble metal based electrocatalysts for advanced water oxidation and beyond.

Published
2021

40. Modification of cellulose filter paper with bimetal nanoparticles for catalytic reduction of nitroaromatics in water

Author

Sher Bahadar Khan, Tahseen Kamal, Yasir Anwar, and Esraa M. Bakhsh

Subjects
Thermogravimetric analysis, Materials science, Polymers and Plastics, Filter paper, Selective catalytic reduction, Catalysis, Carboxymethyl cellulose, Bimetal, chemistry.chemical_compound, Reaction rate constant, chemistry, Chemical engineering, medicine, Cellulose, medicine.drug
Abstract

In this research work, we present a synthesis of silver and cobalt bimetal nanoparticles stabilized by a carboxymethyl cellulose biopolymer (CMC-AgCo) and its coating on a cellulose filter paper (CFP) to prepare the dip-catalyst. All the prepared samples were subjected to characterization by scanning electron microscopy for surface morphology, EDX, XRD and thermogravimetric analysis. The catalytic properties of the CFP/CMC-AgCo as dip-catalysts were evaluated in the reduction of organic nitroaromatic pollutants of 2,6-dinitrophenol to 2,6-diaminophenol as well as the 4-nitrophenol to 4-aminophenol. It was found that the reduction reaction advanced with the pseudo-first-order kinetics. The CFP/CMC-AgCo catalyzed the 2,6-diaminophenol and 4-nitrophenol with a reaction rate constant of 0.1244 and 0.177 min− 1, respectively. The separation of the CFP/CMC-AgCo was easy as it required a simple pulling of the strip from the reaction medium. Importantly, the catalytic reaction rates and conversion percentages of the two nitroaromatics were well-maintained for multiple times during recycling experiments.

Published
2021

41. Optimization of image writer modes for optically rewritable electronic paper

Author

Vladimir G. Chigrinov and Aleksey Kudreyko

Subjects
Materials science, business.industry, law, Liquid crystal, Optoelectronics, General Materials Science, General Chemistry, Electronic paper, Condensed Matter Physics, business, law.invention, Image (mathematics)
Abstract

Time-limited exposure of electrode-free optically rewritable electronic paper is essential for applications, but performance characteristics can be modest. In this study we investigate whether imag...

Published
2021

42. Enhancement of High Strength Concrete Performance By Utilising Nano Waste Paper Sludge Ash

Author

Muhd Norhasri Muhd Sidek, Aidan Newman, Nuradila Izzaty Halim, Hamidah Mohd Saman, and Anizahyati Alisibramulisi

Subjects
Materials science, Waste management, Nano, Waste paper, High strength concrete
Abstract

High strength concrete (HSC) is an amazing breakthrough in the history of construction material. Due to its high strength, durability, and economic value, it has been used in large-scale construction with a unique structure design not achievable by conventional concrete. However, HSC uses a high amount of cement powder which contributes to its overall strength. However, it will require high cement consumption and increases carbon dioxide emission. Waste paper sludge ash (WPSA) is utilised in cement and has improved concrete properties. Nano engineered WPSA might further enhance HSC capabilities. This research focused on the physical and fresh properties of HSC with partial replacement of nano-engineered WPSA to cement through experimental investigation. The HSC produced in this research has a targeted strength of more than 40MPa with a fixed water-cement ratio of 0.2. The WPSA was oven-dried and was sieved to a particle size of 212 micrometers. Then, it was milled until a nano-size particle is obtained. The nano WPSA is used to replace cement in the HSC mix with a replacement percentage of 1%, 3%, 5%, 7%, and 10%. The new properties of the concrete were measured by conducting the flow table test, and the physical property was determined by conducting the compressive test. Compressive tests were conducted for 1, 3, 7, 14, and 28 days with a cube sample size of 50mm x 50mm x 50mm. This research shows that 1% of nano WPSA replacement tends to improve the compressive strength of the HSC concrete by 10.7% compared to the control sample. On the other hand, the 1% replacement of nano WPSA in HSC did not affect the concrete's workability compared to the control sample. The conventional HSC properties were improved with less usage of cement with the use of WPSA.

Published
2021

43. Preparation of Carboxymethylcellulose from Waste Paper

Author

Yali Huang, Chunxiang Cui, Dali Wang, Shengyang Yang, Yuchang Wang, Lirong Long, Jie He, and Jiajia Yi

Subjects
musculoskeletal diseases, Materials science, Living environment, technology, industry, and agriculture, Waste paper, Raw material, Pulp and paper industry, chemistry.chemical_compound, Hydrolysis, chemistry, Homogeneous, Yield (chemistry), General Materials Science, Cellulose, Sodium chloroacetate
Abstract

We aimed at producing sodium carboxymethylcellulose (CMC) from waste paper cellulose. For this etherification, the raw material was waste paper, the cellulose was initially alkalized with NaOH, the etherifying agent was sodium chloroacetate, and the reaction medium was water or ethanol. The method provided by us, i e, a method for preparing CMC from waste paper, was environment-friendly, could be easily implemented, and could be conveniently applied to make waste paper efficiently used with high profit, and to expand the range of usable raw materials for CMC production. We successfully synthesized CMC and prepared CMC plastic membrane. This practice changes waste into valuables, which is beneficial to our living environment. For preparation of CMC, one of the crucial factors is appropriate pretreatment of the cellulose from waste paper. The pretreatment was done with a self-built hydrolysis method. We experimentally examined the effects of the mass ratios of reactants, reaction temperature, time, and reaction environment of homogeneous or heterogeneous on CMC yield. The innovative points of this research could be stated as follows: the reaction activity of cellulose was improved by pre-hydrolysis; synthesizing CMC with cellulose from waste paper changes waste into valuables is beneficial to our living environment; and a freezing treatment for the cellulose-alkali mixture was innovatively added. The effects were exhibited by a desired final conversion efficiency.

Published
2021

44. Thermal Behavior of Insulation Fiberboards Made from MDF and Paper Wastes

Author

Bita Moezzipour and Aida Moezzipour

Subjects
Materials science, Waste management, Thermal, Forestry, Waste paper, Thermal stability, insulation fiberboards, recycling, thermal stability, MDF wastes, waste paper, izolacijske ploče vlaknatice, recikliranje, toplinska stabilnost, MDF otpad, otpadni papir
Abstract

Today, recycling is becoming increasingly important. In recycling process, the product performance should also be considered. In this study, manufacturing insulation fiberboard, as a practical wood product from recycled fibers, was investigated. For this purpose, two types of waste (MDF wastes and waste paper) were recycled to fibers and used for producing insulation fiberboards. The target fiberboard density was 0.3 g/cm3. The ratio of waste paper to MDF waste recycled fibers (WP/RF) was considered at two levels of 70/30 and 50/50. Polyvinyl acetate adhesive was used as a variable in the board manufacturing process. The mechanical properties, dimensional stability, thermal conductivity, and fire resistance of the boards were evaluated. Besides, the thermal stability of fiberboards was studied using thermal analysis including thermogravimetric analysis (TGA) and differential thermal analysis (DTA). The results showed that the insulation fiberboards had admissible mechanical properties and dimensional stability. The manufactured boards displayed low thermal conductivity, which proved to be well competitive with other insulation materials. The fiberboards manufactured with PVAc adhesive and WP/RF ratio of 50/50 had higher fire resistance compared to other treatments. Additionally, results of thermal analysis showed that the use of PVAc adhesive and WP/RF ratio of 50/50 leads to improved thermal stability. Overall, the recycled fibers from MDF and paper wastes appear to be appropriate raw materials for manufacturing thermal insulation panels, and use of PVAc adhesive can significantly improve thermal and practical properties of insulation fiberboards., Danas recikliranje postaje sve važnije, a u tom postupku treba uzeti u obzir i svojstva proizvoda koji se recikliranjem dobivaju. U ovom je radu istražena proizvodnja izolacijske ploče vlaknatice kao praktičnoga drvnog proizvoda od recikliranih vlakana. Za tu su namjenu u vlakna reciklirane dvije vrste otpada (MDF otpad i papirni otpad), koje su iskorištene za proizvodnju izolacijskih ploča vlaknatica. Ciljana gustoća ploče vlaknatice bila je 0,3 g/cm3. Planirani je omjer vlakana recikliranih od otpadnog papira i MDF otpada (WP/RF) iznosio 70 : 30 i 50 : 50. U procesu proizvodnje ploča upotrijebljeno je polivinilacetatno ljepilo. Eksperimentom su određena ova mehanička svojstva ploča: dimenzijska stabilnost, toplinska vodljivost i vatrootpornost. Osim toga, uz pomoć toplinske analize koja je podrazumijevala termogravimetrijsku analizu (TGA) i diferencijalnu toplinsku analizu (DTA) istražena je toplinska stabilnost ploča vlaknatica. Rezultati su pokazali da izolacijske ploče vlaknatice imaju odgovarajuća mehanička svojstva i dimenzijsku stabilnost. Usto, proizvedene su ploče imale nisku toplinsku vodljivost, što potvrđuje njihovu konkurentnost s ostalim izolacijskim materijalima. Ploče vlaknatice proizvedene s PVAc ljepilom i uz omjer WP/RF od 50 : 50 imale su veću vatrootpornost od ploča proizvedenih ostalim postupcima (omjerima sastojaka). Usto, rezultati toplinske analize pokazali su da upotreba PVAc ljepila i omjer WP/RF od 50 : 50 pridonose poboljšanoj toplinskoj stabilnosti. Zaključno, reciklirana vlakna od MDF otpada i otpadnog papira čine se prikladnom sirovinom za proizvodnju termoizolacijskih ploča, a uporaba PVAc ljepila može znatno poboljšati toplinska i uporabna svojstva takvih izolacijskih ploča vlaknatica.

Published
2021

45. New alternatives to single‐use plastics: Starch and chitosan‐ graft ‐polydimethylsiloxane‐coated paper for water‐ and oil‐resistant applications

Author

Aditya Nair, Ajmir Khan, Dhwani Kansal, and Muhammad Rabnawaz

Subjects
Coated paper, Microplastics, Water resistant, microplastics, Single use, Materials science, oil‐resistant, Polydimethylsiloxane, latex, Starch, paper, PFAS remediation, Chitosan, chemistry.chemical_compound, chemistry, Chemical engineering, TA401-492, plastics, Materials of engineering and construction. Mechanics of materials
Abstract

An increase in the environmental and health concerns over fluorochemical‐based, wax‐based, and extrusion‐based paper coatings has led to a growing interest in bio‐based, biodegradable, and repulpable alternatives to obtain water‐ and oil‐repellent coatings. Reported herein is a fluorine‐free, plastic‐free, and cost‐effective water and grease resistant paper coating approach that utilizes blends of corn‐starch (S) and a novel chitosan‐graft‐polydimethylsiloxane (CP) copolymer. The hydrophobic and oleophobic performance of the S/CP‐coated paper was evaluated by varying the ratio of S and CP in the overall blend. The S/CP‐coated papers were observed to have low cobb60 values (water absorptivity) of 13 ± 0.9 g m−2 and an excellent kit rating (oil resistance) of 12/12. The S/CP‐coated paper substrate surface profile was analyzed via scanning electron microscopy (SEM). The repulpability of the coated paper is also demonstrated by washing the coating materials from the paper and recovering the pulp.

Published
2021

46. Fabrication of super-hydrophobic filter paper via mixed wax phase separation for efficient oil/water separation

Author

Yating Wang, Xiaochun Chen, Chenghua Yu, and Yaqi Liang

Subjects
Wax, Coated paper, Environmental Engineering, Materials science, Filter paper, Papermaking, Bioengineering, Beeswax, Micrometre, Contact angle, chemistry.chemical_compound, Chemical engineering, chemistry, visual_art, visual_art.visual_art_medium, Carnauba wax, Waste Management and Disposal
Abstract

Despite previous efforts, the fabrication of superhydrophobic substrate via an environment friendly and easy approach remains a great challenge. In this study, a low cost, simple, and green procedure was developed to prepare a superhydrophobic paper surface that is acceptable for the papermaking industry. First, a wax mixture (beeswax & carnauba wax) was emulsified and coated on the filter paper surface. Then, the coated paper was annealed at different temperatures. The further heat-treatment-rendered wax-coated paper hydrophobic or superhydrophobic because submicrometer or micrometer wax structures were present on the paper surface. The water contact angle of the annealed filter paper sample reached 151.5° at 60 °C, and the sliding angle was under 10°. Further, the relationship between surface composition and the hydrophobic properties of the coated paper samples was discussed. The obtained paper samples showed great potential in water/oil separation, as they had an efficiency over 99%. This work proposed a new simple and mild approach to fabricate superhydrophobic filter papers and explored the hydrophobicity and water/oil separation properties.

Published
2021

47. Assessment of the UV inkjet ink penetration into laboratory papers within triticale pulp and its influence on print quality

Author

Valentina Radić Seleš, Ivana Plazonić, Katja Petric Maretić, Maja Rudolf, and Irena Bates

Subjects
Materials science, Inkwell, Chemistry (miscellaneous), Materials Science (miscellaneous), General Chemical Engineering, Pulp (paper), engineering, Penetration (firestop), Triticale, engineering.material, Laboratory paper, Penetration, Print quality, Triticale pulp, UV inkjet, Pulp and paper industry
Abstract

Today the print quality of digital printing techniques has improved and is considered satisfactory and competitive to analogue techniques for certain graphic products. Satisfactory print quality mostly depends on the interaction of ink and printing substrate where ink penetration has an important role. Namely, the ink penetration affects the parameters that describe the print quality together with visual appearance of print density and mottling. Therefore, it is important to select an adequate printing substrate for each printing technique. Awareness of environmental problems related to the shortage of wood raw materials has led to an increase in the use of recycled printing paper and in particular the implementation of new alternative sources of cellulose fibres instead of virgin wood fibres in the papermaking process. In this research the emphasis is precisely on defining the influence of ink penetration into laboratory papers made of triticale pulp on the final print quality. The laboratory printing papers were obtained by mixing triticale pulp with pulp from recycled fibres in three different portions. Papers were thereafter printed by ultraviolet (UV) inkjet printer and the ink penetration within laboratory papers with and without straw pulp was analysed using two methods of ink penetration analysis (microscopic/spectroscopic). The influence of ink penetration on the final print quality was observed and analysed based on several quality parameters (optical ink density, mottling and colorimetric values). These results confirmed that triticale pulp in laboratory papers provides equal print quality compared to laboratory papers made only from pulp from recycled fibres.

Published
2021

48. Application of modified cellulose nanofibrils as coating suspension on recycled paper using size press

Author

Tamer Sözbir, Ahmet Tutuş, Recai Arslan, Ufuk Killi, Bayram Poyraz, Selva Sertkaya, Ayhan Tozluoğlu, Hakan Fidan, and [Belirlenecek]

Subjects
0106 biological sciences, Materials science, size press, Pulp, 02 engineering and technology, mechanical properties, engineering.material, Modified cellulose, 01 natural sciences, Nano-Fibrillated Cellulose, Coating, 010608 biotechnology, Cationic Starch, General Materials Science, Barrier Properties, Suspension (vehicle), cellulose nanofibers, Nanocellulose, Eucalyptus, coating, Forestry, 021001 nanoscience & nanotechnology, Microfibrillated Cellulose, Chemical engineering, Improve, recycled paper, engineering, Strength, 0210 nano-technology
Abstract

Cellulose based nanomaterials have the great potential to be applied to paper as bulk additive or coating material to improve overall final properties, especially in secondary fiber. In the present work, the effect of applying different kinds of cellulose nanofibrils (CNF) to papers obtained from recycled fibers using size press on physical, mechanical and barrier properties was investigated and compared with the sole use of starch as coating material. The coating process of CNF was carried out by the addition of size press grade starch to coating suspension. As a cellulose source, wheat straw was evaluated and CNF was obtained through oxidative and enzymatic pretreatments. Results indicate that starch/CNF suspension improves the overall paper properties. As a result of the deposition of coating suspension contains of 4 % wt. periodate-oxidized CNF onto paper surface, tensile and burst indices of papersheets increased as 52.2 % and 194.4 %. Significant decreases were observed in air permeability as 69.8 %. Compression tests also have been conducted to evaluate papersheets end-use properties. In comparison to the other pretreated CNF, due to is lower viscosity, applying periodate-oxidized CNF as size press significantly increased the mechanical properties of the papers fabricated from the recycled pulps. TUBITAK-TEYDEBTurkiye Bilimsel ve Teknolojik Arastirma Kurumu (TUBITAK) [1505]; Scientific and Technological Research Council of Turkey, Technology and Innovation Funding Programs Directorate [1505, 5180044] This work was supported by TUBITAK-TEYDEB 1505 (The Scientific and Technological Research Council of Turkey, Technology and Innovation Funding Programs Directorate 1505), Project No. 5180044. WOS:000703585400013 2-s2.0-85108063350

Published
2021

49. Potentials of lignocellulosic agricultural residues in paper production

Author

Valentina Radić Seleš, Irena Bates, Katja Petric Maretić, Maja Rudolf, and Ivana Plazonić

Subjects
Materials science, business.industry, Environmental engineering, Paper production, laboratory paper, straw pulp, contact angle, surface free energy, sessile drop method, food and beverages, Environmental protection, Surface energy, Contact angle, Sessile drop technique, Agriculture, TD169-171.8, business
Abstract

Surface characteristics of printing substrates are of the utmost importance to all types of paper that interact with ink. During all types of printing processes, the behaviour of the liquid phase (ink or dye) on the paper is directly defined by the paper cellulose-based surface. The printed ink spreads and penetrates more into paper fibres when the paper surface is rougher and more permeable. Contact angle measurements by sessile drop method are considered the most appropriate for determining the paper sheet surface energy. Paper as hydrophilic material has a high absorption rate resulting in a low contact angle. The objective of this study was to evaluate the surface free energy of laboratory-made papers containing straw pulp obtained from residues after the harvest of the most cultivated cereals in Croatia (wheat, barley and triticale). The obtained surface free energy results are promising for straw pulp usage in the manufacture of printing paper.

Published
2021