Showing total 3,886 results

1. Cold plasma‐induced N, Cu‐doping on carbon paper for high‐active catalytic electrode preparation.

Author

Yue, Xufeng, Xiang, Hongyu, Zhang, Peng, Shu, Song, Zhao, Yingxin, Zhang, Jiacheng, Liu, Jinwei, and Yu, Deping

Subjects

*CARBON paper, *LOW temperature plasmas, *ELECTRODES, *COLLISIONS (Nuclear physics), *PHYSISORPTION, *CARBON nanofibers, *PHYSIOLOGICAL effects of cold temperatures

Abstract

Carbon paper is commonly used for catalytic electrode preparation because of its high conductivity, corrosion resistance, and stability. However, traditional electrode preparation methods are inappropriate for highly hydrophobic carbon paper. In this paper, a high‐activity carbon paper catalytic electrode was prepared using multistrategies cold plasma modification to create atomic structural defects, dope N and Cu elements, and introduce oxygen‐containing functional groups. Analyses show that the bombardment of high‐energy particles caused atomic structural defects. Nitrogen and copper entered the carbon paper through plasma‐induced chemical recombination and physical adsorption, reaching 5.26% and 3.83%, respectively. Ethanol‐based plasma introduced oxygen‐containing functional groups to improve hydrophilicity. Finally, the plasma‐prepared electrode exhibited a reduction efficiency of 87.69% in an electrocatalytic nitrate reduction reaction. [ABSTRACT FROM AUTHOR]

Published

2024

2. Addition of fibers derived from paper mill sludge in paper coatings: impact on microstructure, surface and optical properties.

Author

Altay, Bilge Nazli, Aksoy, Burak, Huq, Anamika, Hailstone, Richard, Klass, Charles P., Demir, Muslum, and Williams, Scott

Subjects

*OPTICAL properties, *PAPER mills, *SURFACE properties, *SURFACE coatings, *MICROSTRUCTURE, *PETROPHYSICS, *CARBON nanofibers

Abstract

Traditionally, cellulose nanofiber (CNF) production has primarily relied on virgin cellulose sources. Yet, the shift to using paper mill sludge (PMS) as a source for CNF underscores the significance of reusing and recycling industrial byproducts. PMS contains significant amounts of cellulose that can be extracted as a raw material. The purpose of present study is to provide a sustainable approach to PMS utilization as a paper coating additive in the cellulose nanofibrils (CNFPMS) form via simply scalable wire-wound rod coating method. The effect of CNFPMS additive amounts at two coating layers on microstructure and surface properties of coatings such as porosity, air permeability surface roughness and optical properties such as brightness, gloss and CIE L*a*b* is studied, which they can also provide insight for the eventual print performance. Results indicated that the obtained CNFPMS in paper coating shows 52% decrease in porosity, presenting significant improvement in the coating microstructure. The marginal increase in permeability coefficient and surface roughness, 54% and 10%, respectively, suggests improving color reproduction and preventing color density losses. Optical analysis showed slight decrease in brightness and gloss, as was expected. Notably, the lightness was improved, which also indicates increasing color gamut volume in printing applications. As a result, the current work offers a sustainable approach to manage PMS for use in paper coatings as a high-value-added material. [ABSTRACT FROM AUTHOR]

Published

2023

3. Direct Ink Writing of Nanocellulose and PEDOT:PSS for Flexible Electronic Patterned and Supercapacitor Papers.

Author

Lay, Makara, Say, Mehmet Girayhan, and Engquist, Isak

Subjects

*ELECTRONIC paper, *CARBON nanofibers, *ORGANIC electronics, *FLEXIBLE electronics, *CLEAN energy, *ELECTRIC currents, *SUPERCAPACITORS

Abstract

Printed electronic paper identifies its interest in flexible organic electronics and sustainable and clean energy applications because of its straightforward production method, cost‐effectiveness, and positive environmental impact. However, current limitations include restricted material thickness and the use of supporting substrate for printing. Here, 2D and 3D electronic patterned paper are fabricated from direct ink writing (DIW) nanocellulose and PEDOT:PSS‐based materials using syringe deposition and 3D printing. The conductor patterns are integrated in the bulk of the paper, while non‐conductive sections are used as support to form free‐standing paper. The strong interface between the patterns of electronic patterned paper gives mechanical stability for practical handling. The conductive paper‐based electrode has 202 S cm−1 and is capable of handling electric current up to 0.7 A, which can be used for high‐power devices. Printed supercapacitor papers show high specific energy of 4.05 Wh kg−1, specific power of 4615 W kg−1 at 0.06 A g−1, and capacitance retention above 95% after 2000 cycles. The new design structure of electronic patterned papers presents a solution for additive manufacturing of paper‐based composites for supercapacitors, wearable electronics, or sensors for smart packaging. [ABSTRACT FROM AUTHOR]

Published

2023

4. Performance Enhancement of Proton Exchange Membrane Fuel Cell through Carbon Nanofibers Grown In Situ on Carbon Paper.

Author

Liu, Chang and Li, Shang

Subjects

PROTON exchange membrane fuel cells, CARBON paper, CARBON nanofibers, DIFFUSION, FUEL cells, POLYMERIZATION

Abstract

We developed an integrated gas diffusion layer (GDL) for proton exchange membrane (PEM) fuel cells by growing carbon nanofibers (CNFs) in situ on carbon paper via the electro-polymerization of polyaniline (PANI) on carbon paper followed by a subsequent carbonization treatment process. The CNF/carbon paper showed a microporous structure and a significantly increased pore volume compared to commercial carbon paper. By utilizing this CNF/carbon paper in a PEM fuel cell, it was found that the cell with CNF/carbon paper had superior performance compared to the commercial GDL at both high and low humidity conditions, and its power density was as high as 1.21 W cm−2 at 100% relative humidity, which is 26% higher than that of a conventional gas diffusion layer (0.9 W cm−2). The significant performance enhancement was attributed to a higher pore volume and porosity of the CNF/carbon paper, which improved gas diffusion in the GDL. In addition, the superior performance of the cell with CNF/carbon paper at low relative humidity demonstrated that it had better water retention than the commercial GDL. This study provides a novel and facile method for the surface modification of GDLs to improve the performance of PEM fuel cells. The CNF/carbon paper with a microporous structure has suitable hydrophobicity and lower through-plane resistance, which makes it promising as an advanced substrate for GDLs in fuel cell applications. [ABSTRACT FROM AUTHOR]

Published

2023

5. The Use of Eucalyptus Grandis Bark and Root as Raw Material in Pulp and Paper Production.

Author

Çiçekler, Mustafa, Tutus, Ahmet, and Üzüm, Velican

Subjects

*EUCALYPTUS grandis, *PAPER pulp, *SULFATE pulping process, *PAPER industry, *RAW materials, *CARBON nanofibers

Abstract

The suitability of Eucalyptus grandis bark and root for the pulp and paper industry was investigated. The bark of E. grandis was cooked using sodium borohydride (NaBH4) in the kraft process, while the root of E. grandis was cooked using the soda-anthraquinone (AQ) process. Four different charges (0.0, 0.3, 0.5, 0.7%) of NaBH4 and AQ used as catalysts were added to the cooking liquor used in the processes. The chemical, mechanical and optical properties of the produced pulps were investigated and characterized. The yields, viscosity values, kappa numbers, as well as the brightness, tensile, burst and tear indices of the pulps were determined. The yield (RP: 39.1%, BP: 36.8%), viscosity value (RP: 897 cm3/g, BP: 650 cm3/g) and the kappa numbers (RP: 90, BP: 50) of the pulps produced from the root (RP) were higher than those of the pulps produced from bark (BP). The catalysts generally affected all the pulp properties, improving the properties of BP and RP. It was concluded that E. grandis bark and root can be suitable for the pulp and paper industry. [ABSTRACT FROM AUTHOR]

Published

2023

6. Chinese ink-facilitated fabrication of paper-based composites as electrodes for supercapacitors

Author

Weili Yan, Zhuohao Xiao, Xiuying Li, Xiang Wu, and Ling Bing Kong

Subjects

chinese ink, carbon nanofibers, paper-based, electrodeposition, supercapacitors, Materials of engineering and construction. Mechanics of materials, TA401-492

Abstract

Commercial Chinese ink was employed to disperse pristine vapor-grown carbon nanofibers (VGCNFs) in aqueous suspensions via horizontal ball milling. The obtained suspension was used to fabricate conductive paper-based composites through filtration-deposition onto filter paper. It was found that the carbon black particles from the Chinese ink helped separate VGCNFs and acted as connection points between the VGCNFs, while the glue reinforced the conduction network. Thus, the VGCNF-ink/paper ternary composite showed sufficiently low sheet resistance. With merely 2.5 mg·cm−2 VGCNFs, the sheet resistance could be reduced to 4.5 Ω·sq−1. As a proof of concept, these paper-based composites were directly used as electrodes of solid-state symmetric electronic double-layer capacitors (EDLCs) and the substrate for the electrodeposition of MnO2 to achieve higher electrochemical performances. The EDLCs fabricated with 2.5 mg·cm−2 VGCNFs showed a specific capacitance of 224 mF·cm−2 at a current density of 1 mA·cm−2, which was retained by 86.4% after 10,000 charge-discharge cycles. Moreover, thanks to the high electrical conductivity and the porous structure, the MnO2 decorated paper-based composites exhibited dramatically enhanced specific capacitance. It is believed that our finding offers an idea to directly utilize commercial Chinese ink for the fabrication of electrode materials.

Published

2021

7. Surface ionization-induced tunable dynamic phosphorescence colors from carbon dots on paper for dynamic multimode encryption.

Author

Li, Qijun, Meng, Shuai, Li, Yuchen, Cheng, Dengke, Gu, Hailing, Zhao, Zhenxiao, Tang, Zikang, Tan, Jing, and Qu, Songnan

Subjects

*CARBON paper, *CARBON nanofibers, *RADIATIONLESS transitions, *SURFACE states, *PHOSPHORESCENCE, *SURFACE defects, *PRINTMAKING

Abstract

Stimuli-responsive phosphorescence materials with dynamic color-changing properties are highly promising for advanced information security. Herein, we demonstrate a novel strategy that effectively induces tunable dynamic phosphorescence color from carbon dots (CDs) on papers via surface ionization engineering for multimode encryption and information storage. Alkali-induced phenolic hydroxyl ionization on CDs can boost intersystem crossing rates, while surface-ionized groups with negative charges significantly passivate the surface defects and reduce non-radiative transitions, which can activate surface state-related blue phosphorescence emission. Combined with the carbon core state-related yellow-green phosphorescence, excitation/time-dependent phosphorescence color-changing from yellow-green to blue are realized from alkali (Na 2 CO 3) treated CDs on paper. Furthermore, benefiting from the transition from NaHCO 3 to Na 2 CO 3 under thermal treatment, dynamic color-changing phosphorescence can also be activated by thermally stimulating NaHCO 3 -treated CDs on paper. Finally, multi-stimuli (alkali or thermal) and multi-modal dynamic phosphorescent colors from a single CDs system are realized for the first time. Based on these unique features, multimode encryption and smart 3D codes with anti-counterfeiting and monitoring functions for medicine during transport or storage are demonstrated by combining an inkjet printing technique using CD inks. Multistimuli and excitation-dependent dynamic phosphorescence colors from a single CD system were realized for the first time for dynamic multimode encryption. Dynamic phosphorescence colors can be modulated from the dual phosphorescent centers of CDs in the surface triplet state and the carbon core-related triplet state, where the surface triplet state can be activated by external stimuli (alkali or thermal). [Display omitted] • A new surface ionization-activated RTP from CDs surface state strategy is proposed. • Multistimuli- and excitation/time-dependent RTP color variations from single CDs system are realized for the first time. • Smart 3D codes with monitoring function for medicine are developed for the first time. [ABSTRACT FROM AUTHOR]

Published

2022

8. Evaluation of food packaging paper for microbial load and storage effect on the microbial activity of paper.

Author

Zaidi, Saher, Vats, Mudita, Kumar, Nitin, Janbade, Anuradha, and Gupta, Manoj Kumar

Subjects

FOOD packaging, PLASTICS in packaging, PLASTICS, CARBON nanofibers, PACKAGING materials, CARDBOARD, STREET food

Abstract

Paper and paper board are an ideal choice of packaging material due to their biodegradability. They are safer than commonly used plastic packaging materials. But due to the presence of carbon sources like cellulose and starch in paper, various pathogenic and non‐pathogenic microbes can grow well in them. The migration of microorganisms or their spores from paper to food may cause serious health hazards. Taking consumer concerns into picture, the regulatory authorities should come up for food packaging standards with regard to microbial limits of paper used in food packaging. This study pinpoints the correct approach, that is, the disintegration method in comparison to direct plating in evaluating the microbial load of 14 different samples of paper by demonstrating the limitations of methods that were eliminated. The samples were also tested for storage effect on microbial load and found to have significant reduction in bacterial load during storage at 4°C, but for fungi, it remained nearly unchanged. Further identification of predominating microbes was performed, and conclusions have been drawn on the presence of harmful and harmless species in the samples of paper. It was found that all the identified fungi are mycotoxin producing and may lead to illness of the consumer. Unlike fungi, dominating bacterial strains were found to be non‐harmful for food packaging purposes and ultimately for human use. Overall, there is an immediate need to set microbial limit standards in food packaging paper and paperboard in order to supply safe and hygiene food to consumers. [ABSTRACT FROM AUTHOR]

Published

2022

9. Using Pulp and Paper Waste to Scrub Carbon from Emissions.

Subjects

*WASTE paper, *PAPER pulp, *CARBON emissions, *CARBON sequestration, *LIGHT sources, *CARBON nanofibers

Abstract

The text provides a summary of various articles related to air quality, climate change, and environmental initiatives. It mentions a report from the World Meteorological Organization (WMO) highlighting record-breaking climate change indicators in 2023, the use of pulp and paper waste to reduce carbon emissions, the development of national indoor quality standards for public buildings, the establishment of a hydrogen hub in the Pilbara region of Australia, and the U.S. Environmental Protection Agency's new tailpipe rules to reduce pollution from cars and light trucks. These articles offer insights into the current state of the environment and efforts to address climate change. [Extracted from the article]

Published

2024

10. ZIF-67/PEDOT modified carbon paper electrode for sensitive electrochemical determination of chlorogenic acids.

Author

Ma, Xuemei, Gao, Yali, Pang, Wanyu, Chang, Xile, Hu, Zhiyong, and Hu, Tuoping

Subjects

*CARBON paper, *CARBON electrodes, *ELECTROCHEMICAL electrodes, *CARBON nanofibers, *CHLOROGENIC acid, *ELECTRIC conductivity, *TRANSMISSION electron microscopy

Abstract

• Preparation of ZIF-67/PEDOT/CP self-supporting electrodes using simple in situ hydrothermal. • The addition of PEDOT to ZIF-67 helps to achieve high electrical conductivity and large specific surface area. • The sensor has a high detection performance for CGA. • ZIF-67/PEDOT/CP provided a new sensor for the detection of CGA in real sample. The design of efficient electrocatalysts for the determination of chlorogenic acids (CGA) is crucial in the biological and medical fields. In this paper, ZIF-67/poly(3,4-ethylenedioxythiophene) (PEDOT) nanocomposites were synthesised. The introduction of PEDOT increased the electrical conductivity of the ZIF-67/PEDOT composites, inhibited the Co atom agglomeration, led to the exposure of more active sites and increased the transport channels. An ultrasensitive CGA sensor based on ZIF-67/PEDOT nanocomposite modified carbon paper (CP) electrode was developed. The nanomaterials were characterised using scanning electron microscopy (SEM), transmission electron microscopy (TEM) and X-ray diffraction spectroscopy (XRD). Cyclic voltammetry (CV) and differential pulse voltammetry (DPV) were used to study the electrochemical properties of the modified CP electrode. In addition, the effects of different experimental conditions such as pH, scan rate and concentration on the peak current of CGA were investigated. Under the optimised conditions, the linear range of ZIF-67/PEDOT/CP for the determination of CGA was 0.1 ∼ 40 μM, and the limit of detection (LOD) was as low as 0.003 μM (S/N = 3). Furthermore, the sensor was successfully used for the quantitative analysis of CGA in real samples. [ABSTRACT FROM AUTHOR]

Published

2024

11. High‐rate metal‐free MXene microsupercapacitors on paper substrates.

Author

Xue, Han, Huang, Po‐Han, Lai, Lee‐Lun, Su, Yingchun, Strömberg, Axel, Cao, Gaolong, Fan, Yuzhu, Khartsev, Sergiy, Göthelid, Mats, Sun, Yan‐Ting, Weissenrieder, Jonas, Gylfason, Kristinn B., Niklaus, Frank, and Li, Jiantong

Subjects

FEMTOSECOND lasers, ENERGY storage, ELECTRIC capacity, ELECTRODES, CARBON nanofibers

Abstract

MXene is a promising energy storage material for miniaturized microbatteries and microsupercapacitors (MSCs). Despite its superior electrochemical performance, only a few studies have reported MXene‐based ultrahigh‐rate (>1000 mV s−1) on‐paper MSCs, mainly due to the reduced electrical conductance of MXene films deposited on paper. Herein, ultrahigh‐rate metal‐free on‐paper MSCs based on heterogeneous MXene/poly(3,4‐ethylenedioxythiophene)‐poly(styrenesulfonate) (PEDOT:PSS)‐stack electrodes are fabricated through the combination of direct ink writing and femtosecond laser scribing. With a footprint area of only 20 mm2, the on‐paper MSCs exhibit excellent high‐rate capacitive behavior with an areal capacitance of 5.7 mF cm−2 and long cycle life (>95% capacitance retention after 10,000 cycles) at a high scan rate of 1000 mV s−1, outperforming most of the present on‐paper MSCs. Furthermore, the heterogeneous MXene/PEDOT:PSS electrodes can interconnect individual MSCs into metal‐free on‐paper MSC arrays, which can also be simultaneously charged/discharged at 1000 mV s−1, showing scalable capacitive performance. The heterogeneous MXene/PEDOT:PSS stacks are a promising electrode structure for on‐paper MSCs to serve as ultrafast miniaturized energy storage components for emerging paper electronics. [ABSTRACT FROM AUTHOR]

Published

2024

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

Author

Yan, Liang and Zhang, Bing

Subjects

*CARBON paper, *HYDROGEN evolution reactions, *OXYGEN evolution reactions, *OXYGEN, *OXIDATION of water, *CARBON nanofibers

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 Co 3 O 4 –CoOOH heterostructure nanosheet arrays with oxygen vacancies grown on carbon paper (Co 3 O 4 –CoOOH/CP). Benefiting from the unique 3D architecture, large surface area, synergistic effects between Co 3 O 4 , CoOOH and oxygen vacancies, the obtained self-supporting Co 3 O 4 –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. [Display omitted] • Co 3 O 4 –CoOOH heterostructure with oxygen vacancies grown on carbon paper was synthesized. • Synergic effect between oxygen vacancies and Co 3 O 4 –CoOOH facilitates the activity. • The Co 3 O 4 –CoOOH/CP exhibited excellent activity and stability for OER. [ABSTRACT FROM AUTHOR]

Published

2021

13. PDIP/carbon paper photocatalyst sheet for enhanced photocatalytic water oxidation.

Author

Xia, Biyu, Qiu, Nan, Cheng, Lin, Shan, A., Ma, Huiyan, Yang, Jucai, and Liu, Juming

Subjects

*OXIDATION of water, *CARBON paper, *PHOTOCATALYTIC oxidation, *BAND gaps, *CORPORATE bonds, *CARBON nanofibers

Abstract

[Display omitted] • Facile and scalable self-assembly of perylene diimide polymer with carbon paper. • Effective facilitation of carrier separation by π-π built-in electric field. • Narrowed band gap and low VB due to the VB tail states induced by π-π interactions. • Enhanced photocatalytic water oxidation activity of the PDIP/CP photocatalyst sheet. • Suitability of the PDIP/CP photocatalyst sheet for large-scale applications. Photocatalytic water splitting is a highly promising future energy technology. In contrast to the extensive work on particulate photocatalysts, there is still a lack of sufficient investigation for regularized photocatalysts. Here, from perylene diimide polymer (PDIP) and commercial carbon paper (CP), we develop a self-assembled PDIP/CP photocatalyst sheet that is easily scalable and can be used for photocatalytic water oxidation. Driven by strong interfacial π-π interactions, the PDIP spontaneously adsorbs onto the CP, which leads to a narrowed band gap, down-shifted VB edge, and enhanced separation of the photogenerated charge carriers of the PDIP. Under visible light, the PDIP/CP photocatalyst sheet shows significantly enhanced photocatalytic water oxidation activity (4 h cumulative oxygen evolution is 1.7 times higher than that of the powder-suspended system) and considerable cycling stability. The PDIP/CP photocatalyst sheet has the potential for large-scale device applications. [ABSTRACT FROM AUTHOR]

Published

2024

14. Sustainability assessment and pathways for U.S. domestic paper recycling.

Author

Jin, Enze, van Ewijk, Stijn, Kanaoka, Koichi S., Alamerew, Yohannes A., Lin, Hui, Cao, Zhi, Jabarivelisdeh, Banafsheh, Ehmann, Kornel F., Chertow, Marian R., and Masanet, Eric

Subjects

PAPER recycling, RECYCLED paper, RESOURCE recovery facilities, INDUSTRIAL energy consumption, CARBON dioxide mitigation, CARBON nanofibers

Abstract

• A technology-rich system model is created by integrating operations at MRFs and recycling paper mills. • Our model assesses sustainable pathways for U.S. domestic paper recycling industry. • Domestic recycling rate can increase by 15 % with better collection rate and sorting efficiency. • Use of recycled fibers can reduce energy and carbon intensities for most paper products. Dramatic changes in global recovered paper markets, triggered in large part by Chinese import restrictions, challenge the U.S. to find sustainable pathways for increasing the domestic paper recycling rate. This study presents a technology-rich process model of the U.S. domestic paper recycling industry to assess the energy consumption, carbon emissions, and system costs. A scenario analysis shows the viability of three potential pathways for achieving the national goals of a 15 % increase in both the paper recycling rate and the recycled paper utilization rate. The results suggest that the national goals can be achieved by recovering 80 % of recyclable papers from households and commercial stores, while trading all exported bales to domestic recovery with additional investments in processing capacity expansion. The deployment of advanced technology can enable material recovery facilities (MRFs) and paper mills to produce most recycled paper products that are more energy efficient with fewer CO 2 emissions. [ABSTRACT FROM AUTHOR]

Published

2023

15. Chinese Calligraphy Inspired Design of Humidity/Light Dual Responsive Magic Paper.

Author

Gao, Jushan, Zhao, Xinxin, Wen, Jinpeng, Hu, Datao, Li, Ruilin, and Wang, Ke

Subjects

CALLIGRAPHY, WEDDING decorations, POLYVINYL butyral, MAGIC, CUT flowers, HUMIDITY, CARBON nanofibers

Abstract

Paper flowers are frequently, for example as indoor decorations and in wedding bouquets. But these traditional paper flowers can only maintain static conditions, greatly affecting their sensory effects, vividness, and appreciation. The design of novel paper flowers with dynamic shape deformation could effectively broaden the application of paper flowers. Here, inspired by Chinese calligraphy, a novel polyvinyl butyral (PVB)/carbon/cellulose composite (PCC) magic paper with a sandwiched structure is prepared. The hygroscopicity difference between hydrophobic PVB and hydrophilic cellulose layer endows the PCC paper with humidity responsiveness, and the maximum bending angle is up to 91.4° upon exposure to humidity environment. Carbon in the interlayer with strong light–heat conversion capacity could further accelerate water desorption and deformation speed, resulting in highly sensitive light responsiveness. The recovery time of PCC paper from maximum bending to the original flat state is shorter than 1 s. The PCC paper has good flexibility and processability, which can be cut and assembled into flowers with different shapes, and these unique magic flowers could freely bloom and furl upon external stimulus. All these results indicate that PCC paper has great potential in the production of magic props, artworks, and intelligent household decorations fields. [ABSTRACT FROM AUTHOR]

Published

2021

16. Embodied Carbon and Influencing Factors of China's Paper Industry's Export Trade to the United States.

Author

Limin Geng, Wenxing Shen, and Zenan Xu

Subjects

*TECHNOLOGICAL progress, *CARBON nanofibers, *PAPER industry, *CARBON emissions, *CARBON offsetting, *GREENHOUSE gas mitigation, *ENERGY conservation

Abstract

The paper industry is a high-carbon emission and energy-intensive industry. From the perspective of low-carbon trade and carbon neutrality, its energy conservation and emission reduction are worthy of attention. This study used the input-output model to calculate the embodied carbon emissions of China’s paper industry’s export trade to the United States from 2006 to 2020 and used the logarithmic mean division index (LMDI) method to analyze influencing factors of the change of embodied carbon emissions. The study found that the embodied carbon emissions of China’s paper industry’s export trade to the United States generally shows a stable downward trend after reaching the peak with the increase of export trade scale; scale effect is the main factor that causes the embodied carbon emissions, while technological progress, policy support, and environmental regulations are important driving forces to promote carbon emission reduction. The research results of this paper not only can test and guide China’s paper industry trade policies and industrial policies, but they can also provide decision-making reference for China and the United States to promote the carbon emission reduction of the paper industry. [ABSTRACT FROM AUTHOR]

Published

2022

17. Fit-for-Use Nanofibrillated Cellulose from Recovered Paper.

Author

Balea, Ana, Monte, M. Concepcion, Fuente, Elena, Sanchez-Salvador, Jose Luis, Tarrés, Quim, Mutjé, Pere, Delgado-Aguilar, Marc, and Negro, Carlos

Subjects

*CARBON nanofibers, *NANOFIBERS, *PRODUCTION methods, *HYDROLYSIS, *CELLULOSE

Abstract

The cost-effective implementation of nanofibrillated cellulose (CNF) at industrial scale requires optimizing the quality of the nanofibers according to their final application. Therefore, a portfolio of CNFs with different qualities is necessary, as well as further knowledge about how to obtain each of the main qualities. This paper presents the influence of various production techniques on the morphological characteristics and properties of CNFs produced from a mixture of recycled fibers. Five different pretreatments have been investigated: a mechanical pretreatment (PFI refining), two enzymatic hydrolysis strategies, and TEMPO-mediated oxidation under two different NaClO concentrations. For each pretreatment, five high-pressure homogenization (HPH) conditions have been considered. Our results show that the pretreatment determines the yield and the potential of HPH to enhance fibrillation and, therefore, the final CNF properties. These results enable one to select the most effective production method with the highest yield of produced CNFs from recovered paper for the desired CNF quality in diverse applications. [ABSTRACT FROM AUTHOR]

Published

2023

18. Feature of Review Papers in Nanotechnology and Applied Nanosciences.

Author

Lambin, Philippe

Subjects

NANOTECHNOLOGY, CARBON nanofibers, APPLIED sciences, PLASMONICS, MATERIALS science, NANOSCIENCE, SUSTAINABLE chemistry

Abstract

This document is a summary of a special issue in the journal Applied Sciences titled "Feature of Review Papers in Nanotechnology and Applied Nanosciences." The special issue aims to gather review papers that highlight recent developments and applications in the field of nanosciences. The seven contributions in this special issue cover a range of topics, including the use of nanocellulose for cultural heritage preservation, protective coatings for metal-based bipolar plates in water electrolysis, carbon dioxide electrocatalytic reduction reactions using transition metal sulfide nanomaterials, plasmonic techniques for detecting micro- and nano-plastics, graphene-based perfect absorbers, nano titanium dioxide for hydrogen production and storage, and X-ray spectroscopy studies of metal-salen complexes. The special issue provides a sample of the diverse applications of nanotechnology and addresses important issues in our polluted and climate-degraded world. [Extracted from the article]

Published

2024

19. A FREE-STANDING PAN/PMMA/rGO CARBON PAPER AS AN EFFECTIVE INTERLAYER FOR HIGH PERFORMANCE LITHIUM-SULFUR BATTERIES.

Author

Ya LI, Leigen LIU, Zhenfeng LIN, and Shao-Wen YAO

Subjects

*LITHIUM sulfur batteries, *CARBON paper, *CARBON nanofibers, *DENDRITIC crystals

Abstract

The limitations of the polysulfides shuttling and lithium dendrites have been obstacles to improve the lithium-sulfur battery technology, resulting in low active material utilization and poor cycle life. Here we report a simple modification of the traditional lithium-sulfur battery configuration to achieve high capacity with a long cycle life and high reversible rate. Great improvement was observed with a carbonized PAN/PMMA/rGO paper between the anode and the separator in the active material utilization and capacity retention. The adding of a free-standing PAN/PMMA/rGO carbon interlayer demonstrated the feasibility of enhancing the performance of lithium-sulfur batteries. [ABSTRACT FROM AUTHOR]

Published

2020

20. The design of binder-free self-supporting carbon paper electrode based on biomass derived hierarchical porous carbon/cellulose nanofibers for sustainable flexible supercapacitors.

Author

Bai, Qiuhong, Zhang, Guoyan, Bai, Xue, Liu, Yihang, Wang, Yan, Li, Cong, Shen, Yehua, and Uyama, Hiroshi

Subjects

*CARBON-based materials, *POROUS materials, *CARBON electrodes, *ENERGY storage, *CARBON paper, *SUPERCAPACITORS, *CARBON nanofibers

Abstract

[Display omitted] The design and synthesis of advanced electrodes with high conductivity and flexibility are the key to the development of wearable energy storage devices. Herein, a strategy for preparing conductive carbon paper electrode for flexible supercapacitors is reported by vacuum filtration of a mixture of biomass hierarchical porous carbon materials (HPC), cellulose nanofibers (CNFs) from polysaccharide cellulose of plant origin and silver nanowire (AgNWs), in which CNFs serve as substrates for dispersion and crosslinking of HPC. The prepared self-supporting electrode showed multi-scale pore structure and excellent conductivity (14.1 S cm−1). The electrode exhibited the highest specific capacitance of 383 F g−1 at 0.5 A g−1. Even after 10,000 charge and discharge cycles, 95 % of the original capacitance was remained, which means excellent cyclic stability. High strength and flexibility of the as-assembled flexible supercapacitor make the electrochemical performance of this device remain unchanged when bent at any angle. The present research delineates a simple and convenient method to prepare green, efficient and low-cost flexible supercapacitor. [ABSTRACT FROM AUTHOR]

Published

2024

21. Has the development of the digital economy raised or lowered the level of carbon emissions in cities?-Evidence from China.

Author

Mingxuan Liu

Subjects

HIGH technology industries, CARBON emissions, CITIES & towns, ENERGY consumption, ELECTRONIC paper, CARBON nanofibers, ENVIRONMENTAL management, INDUSTRIAL energy consumption

Abstract

This paper studies the impact of digital economy development on carbon emissions, which is a hot topic in the field of environmental economics. This topic is within the scope of the Frontiers in Environmental Science and is particularly in line with the theme of Environmental Economics and Management section in the journal. Firstly, this paper constructs the Digital Economy Development Index and its variable indicators to measure the development of the digital economy. Secondly, this paper uses urban panel data to reveal the impact of digital economy development on carbon emissions, and further adopts IV method to deal with endogeneity issues. Thirdly, this paper performs the heterogeneity analyses depending on the characteristics of the city. The results can provide a basis for formulating differentiated policies. Fourthly, this paper further explores the mechanism by which the digital economy affects carbon peaking. The results show that the digital economy may influence carbon peaking through upgrading of the industrial structure, technical innovation, and energy consumption. [ABSTRACT FROM AUTHOR]

Published

2024

22. Toward scalable fabrication of electrochemical paper sensor without surface functionalization.

Author

Wang, Cheng, Wu, Rui, Ling, Hao, Zhao, Zhiling, Han, Wenjia, Shi, Xiaowen, Payne, Gregory F., and Wang, Xiaohui

Subjects

ELECTROCHEMICAL sensors, GRAPHENE oxide, CARBON fibers, PAPERMAKING, ANALYTICAL chemistry, CARBON nanofibers

Abstract

Paper-based electrochemical sensors provide the opportunity for low-cost, portable and environmentally friendly single-use chemical analysis and there are various reports of surface-functionalized paper electrodes. Here we report a composite paper electrode that is fabricated through designed papermaking using cellulose, carbon fibers (CF), and graphene oxide (GO). The composite paper has well-controlled structure, stable, and repeatable properties, and offers the electrocatalytic activities for sensitive and selective chemical detection. We demonstrate that this CF/GO/cellulose composite paper can be reduced electrochemically using relatively mild conditions and this GO reduction confers electrocatalytic properties to the composite paper. Finally, we demonstrate that this composite paper offers sensing performance (sensitivity and selectivity) comparable to, or better than, paper-based sensors prepared by small-batch surface-modification (e.g., printing) methods. We envision this coupling of industrialized papermaking technologies with interfacial engineering and electrochemical reduction can provide a platform for single-use and portable chemical detection for a wide range of applications. [ABSTRACT FROM AUTHOR]

Published

2022

23. Exploring greenhouse gas emissions pathways and stakeholder perspectives: In search of circular economy policy innovation for waste paper management and carbon neutrality in Hong Kong.

Author

Chen, Peixiu, Sauerwein, Meike, and Steuer, Benjamin

Subjects

*GREENHOUSE gases, *WASTE paper, *WASTE management, *CIRCULAR economy, *PAPER recycling, *CARBON offsetting, *GREENHOUSE gas mitigation, *CARBON nanofibers

Abstract

Waste paper disposed in landfills notably contributes to greenhouse gas (GHG) emissions and impedes more sustainable, circular alternatives, such as recycling. In Hong Kong, this unsustainable approach is currently dominant as 68% of waste paper products are treated in landfills in 2020. To contextualize the impact of local waste paper management and explore mitigation potentials of circular alternatives, this paper develops a quantitative assessment framework around GHG emissions development trajectories. Combining guidelines of the Intergovernmental Panel on Climate Change (IPCC), national GHG inventories, and local parameters from life cycle analysis, five GHG emissions projections were simulated along the Shared Socioeconomic Pathways (SSPs) until 2060. Most recent baselines indicate that Hong Kong's current waste paper treatment generated 638,360 tons CO 2 -eq in 2020, comprising 1,821,040 tons CO 2 -eq from landfill and 671,320 tons CO 2 -eq from recycling, and −1,854,000 tons CO 2 -eq from primary material replacement. Proceeding along a Business-as-Usual scenario under SSP5, GHG emissions will dramatically increase to a net 1,072,270 tons CO 2 -eq by 2060, whereas a recycling-intensive scenario will lead to a net saving of −4,323,190 tons CO 2 -eq. To complement the quantitative evidence on the benefits of waste paper recycling, field research was conducted to explore the feasibility of circular policy innovation from the perspective of recycling stakeholders. These empirical qualitative and quantitative findings from stakeholders' business routines and material transactions provide crucial indications for policy and institutional innovation: Essentially, for Hong Kong to improve waste paper recycling capacities and facilitate a circular economy (CE), local stakeholders require support via fiscal policy measures (financial subsidies or tax reductions) and infrastructure improvements (delivery access and material storage). In sum, this study employs a novel analytical framework combining original qualitative and quantitative evidence to provide policy innovation towards circular, GHG emission-saving waste paper management. [Display omitted] • A new framework assessing greenhouse gas emissions from waste paper treatment. • Exploring long-term carbon neutrality pathways for managing waste paper. • Using empirical evidence from recycling stakeholders for circular policy innovation. [ABSTRACT FROM AUTHOR]

Published

2023

24. High-performance carbon nanofiber coated cellulose filter paper for electromagnetic interference shielding.

Author

Mondal, Subhadip, Ganguly, Sayan, Das, Poushali, Bhawal, Poushali, Das, Tushar, Nayak, Lalatendu, Khastgir, Dipak, and Das, Narayan

Subjects

CARBON nanofibers, CELLULOSE, FILTER paper, ELECTROMAGNETIC interference, SCANNING electron microscopy

Abstract

A high-performance electromagnetic interference (EMI) shielding material based on carbon nanofiber (CNF) and cellulose filter (CF) paper has been fabricated by a cost-efficient and convenient dip-coating method. The EMI shielding performance of the CF papers with micron level thickness tolerance (2.5-12.7 µm) have been explored by considering the microstructure, serviceability, electrical conductivity, and number of dip-coating cycles. Field emission scanning electron microscopy of the surface and edge of the composites support the good electrical conductivity, which showed distinct increment in electrical conductivity from 6.6 × 10 to 0.85 S/cm. The number of dip-coating cycles have a significant impact on electrical conductivity, and this has also been studied and inferred after alteration of dipping cycles. The electromagnetic shielding efficiency of CNF-coated CF paper exhibits 24.6 dB with only 25 dip coating cycles. Moreover, from commercially viable points of view, extensive study has been executed to investigate CNF-coated CF papers in the simulated ageing environments viz. water, thermal ageing, and thermo-degradability over a wide range of temperature (ambient to 600 °C). All the environmental factors have been simulated on a laboratory scale. The CNF-coated CF papers possess significantly higher mechanical properties than pure CF paper. This type of conductive CNF-coated CF paper is a promising candidate to be used as highly flexible, lightweight, and cost-efficient EMI shielding material in advanced multifunctional application areas. [ABSTRACT FROM AUTHOR]

Published

2017

25. Study on the Performance of Acrylic Polyurethane for the Protection of Handwriting on Paper Relics.

Author

Mao, Tan, Li, Xufeng, Shi, Xiaoting, Hu, Ying, Zha, Junyan, Luo, Xueke, and Cheng, Youliang

Subjects

POLYURETHANES, HANDWRITING, RELICS, PERFORMANCE theory, LASER microscopy, CARBON nanofibers

Abstract

There are many important cultural relics in China, including many paper relics. Therefore, it is particularly important to find methods of protecting the handwriting in paper relics. This study focuses on the effects acrylic polyurethane materials have on preserving handwriting in paper relics by examining the color change and diffusion of handwriting before and after reinforcement treatments on handwriting materials, including ink, carbon ink, blue-black ink, pure blue ink, red ink, and pencil. The acrylic polyurethane materials have a certain degree of stability and enhance the handwriting of paper relics. We analyzed the acrylic polyurethane reinforcement material in terms of acid resistance, alkali resistance, oxidation resistance, dry heat aging resistance, and durability. The experimental results show that the optimal reinforcement concentration is within 15% for ink, 10% for carbon ink, 20% for blue-black ink, 15% to 20% for pure blue ink, and 3% for red ink and pencil. Finally, the surface of the reinforced paper and handwriting were observed through laser microscopy, SEM, EDS, and infrared spectroscopy and the protective effect of acrylic polyurethane reinforcement material on handwriting was determined. [ABSTRACT FROM AUTHOR]

Published

2023

26. Reinforcement of dry and wet paper sheets by cellulose nanofibers.

Author

Liu, Haoyue, Yano, Hiroyuki, and Abe, Kentaro

Subjects

CELLULOSE fibers, YOUNG'S modulus, CARBON nanofibers, CELLULOSE, NANOFIBERS, TENSILE strength

Abstract

The objective of this study was to evaluate how a wide range (10–100%) of cellulose nanofiber (CNF) addition affects the mechanical properties of paper sheets. Young's modulus and tensile strength in the dry and wet states were measured and compared. In the dry state, the Young's modulus increased with the increase of CNF addition. However, the dry specific Young's modulus was constant for all CNF additions, which was one interesting result. The tensile strength increased as the CNF addition increased to 70%; however, there was no further improvement when the CNF addition was greater than 70%, which was another interesting finding. In the wet state, although the Young's modulus decreased when the CNF addition was greater than 20%, the wet tensile strength of the sheets increased almost linearly with increasing CNF addition up to 50%, followed by a slight decline. The maximum wet strength retention reached nearly 10% with 40% CNF addition, despite the higher water uptake (108%). One of advantages of utilizing CNFs as reinforcement agent in paper is that they can improve the wet strength while making paper sheets maintain a higher moisture content. [ABSTRACT FROM AUTHOR]

Published

2023

27. Chinese ink-facilitated fabrication of paper-based composites as electrodes for supercapacitors.

Author

Yan, Weili, Xiao, Zhuohao, Li, Xiuying, Wu, Xiang, and Kong, Ling Bing

Subjects

SUPERCAPACITORS, CARBON nanofibers, ELECTRODES, ELECTRIC conductivity, FILTER paper, CARBON-black

Abstract

Commercial Chinese ink was employed to disperse pristine vapor-grown carbon nanofibers (VGCNFs) in aqueous suspensions via horizontal ball milling. The obtained suspension was used to fabricate conductive paper-based composites through filtration-deposition onto filter paper. It was found that the carbon black particles from the Chinese ink helped separate VGCNFs and acted as connection points between the VGCNFs, while the glue reinforced the conduction network. Thus, the VGCNF-ink/paper ternary composite showed sufficiently low sheet resistance. With merely 2.5 mg·cm−2 VGCNFs, the sheet resistance could be reduced to 4.5 Ω·sq−1. As a proof of concept, these paper-based composites were directly used as electrodes of solid-state symmetric electronic double-layer capacitors (EDLCs) and the substrate for the electrodeposition of MnO2 to achieve higher electrochemical performances. The EDLCs fabricated with 2.5 mg·cm−2 VGCNFs showed a specific capacitance of 224 mF·cm−2 at a current density of 1 mA·cm−2, which was retained by 86.4% after 10,000 charge-discharge cycles. Moreover, thanks to the high electrical conductivity and the porous structure, the MnO2 decorated paper-based composites exhibited dramatically enhanced specific capacitance. It is believed that our finding offers an idea to directly utilize commercial Chinese ink for the fabrication of electrode materials. [ABSTRACT FROM AUTHOR]

Published

2021

28. Stacked-Cup Carbon Nanotube Flexible Paper Based on Soy Lecithin and Natural Rubber

Author

Amirreza Shayganpour, Sara Naderizadeh, Silvia Grasselli, Annalisa Malchiodi, and Ilker S. Bayer

Subjects

soy lecithin, carbon nanotubes, carbon nanofibers, natural rubber, biocomposites, conductive paper, thermal conductivity, Chemistry, QD1-999

Abstract

Stacked-cup carbon nanotubes (SCCNTs) are generally referred to as carbon nanofibers (CNFs). SCCNTs are much less expensive to fabricate and are regarded as good polymer modifiers suitable for large-scale production. Flexible, SCCNT-based soy lecithin biocomposites were fabricated using liquid natural rubber latex as binder. Natural polymers and the SCCNTs were dispersed in a green solvent using a benchtop high-pressure homogenizer. The inks were simply brush-on painted onto cellulose fiber networks and compacted by a hydraulic press so as to transform into conductive paper-like form. The resulting flexible SCCNT papers demonstrated excellent resistance against severe folding and bending tests, with volume resistivity of about 85 Ω·cm at 20 wt % SCCNT loading. The solvent enabled formation of hydrogen bonding between natural rubber and soy lecithin. Thermomechanical measurements indicated that the biocomposites have good stability below and above glass transition points. Moreover, the SCCNT biocomposites had high through-plane thermal conductivity of 5 W/mK and 2000 kJ/m3K volumetric heat capacity, ideal for thermal interface heat transfer applications.

Published

2019

29. In situ N-doped carbon nanofiber paper-based 3D anode materials for highly flexible lithium-ion batteries.

Author

Chen, Dong, Li, Hailong, Liu, Mengru, and Zhao, Shuangshuang

Subjects

*CARBON-based materials, *LITHIUM-ion batteries, *DOPING agents (Chemistry), *CARBON paper, *CARBON fibers, *CARBON nanofibers, *CARBON composites

Abstract

Wearable electronic energy storage devices usually require the integration of flexible mechanisms and uncompromising electrochemistry of lithium-ion batteries (LIBs). Most of the studies in this field have mainly focused on enhancing the electrochemical properties of the material, while the significance of its flexibility and mechanical properties has been relatively ignored. In this study, the 20 wt % carbon fibers (CFs) composite N-doped flexible carbon nanofiber paper (NFCFP) was prepared through a facile PFI refiner and Bauer sieve of pulping and papermaking machinery sieve-assisted methods combined with annealing technology. The NFCFP-700 with high pyridine N content shows good ion transport and storage performance, the specific capacity remained 308 mAh⸱g−1 after 100 cycles at 0.1 C, and even at 1 C, the specific capacity of the electrode material instead increases constantly at 142 mAh⸱g−1. According to density functional theory (DFT) calculations, the coexistence of pyridine N content and defects in carbon materials was found to enhance the adsorption energy (E ad) of lithium, and the N4V2 locally show the most negative electrostatic potential (ESP) distribution, which was more favorable for the adsorption of Li+ being positively charged. This insight from DFT studies combined with experimental data emphasizes the favorable impact of pyridine N content and defects on the lithium adsorption process in carbon materials, also providing valuable information for the design and optimization of materials for lithium storage applications. [ABSTRACT FROM AUTHOR]

Published

2024

30. Overestimated carbon emission of the pulp and paper industry in China.

Author

Man, Yi, Yan, Yukun, Wang, Xu, Ren, Jingzheng, Xiong, Qingang, and He, Zhenglei

Subjects

*PAPER industry, *CARBON emissions, *GREENHOUSE gases, *PRODUCT life cycle assessment, *ENERGY consumption, *CARBON nanofibers

Abstract

China is the top emitter of greenhouse gases in the world. Pulp and paper industry is one of eight the strictly regulated industries about carbon emission in China. However, estimates of carbon emissions from China's pulp and paper industry have been suffered from remarkable uncertainty. It is summarized that is aroused by the inaccuracy of factors evaluating energy consumption, and the huge gap between the calculation standards for assessing energy consumption in the production process and the actual level recorded in the factories. This paper re-evaluated the carbon emission of China's pulp and paper industry from the perspective of life cycle assessment, and applied more accurate emission factors, taking account of the actual energy consumption of the production process in factories, to estimate the actual carbon emissions in maximum. It is found that the national standards about the energy consumption quota of China's pulp and paper industry is no longer applicable, and the actual energy consumption regulated in the production process is far better than the advanced level given by the national standards. The greenhouse gas emission have been seriously overestimated approximately 12.00%–56.17% by international organizations. • Life Cycle Analysis of the China's pulp and paper Industry is conducted thoroughly. • The pulp flow of China's pulp and paper Industry is analyzed. • Energy regulated in factory is far better than the national standards' required. • Carbon emissions of China's pulp and paper Industry are overestimated. [ABSTRACT FROM AUTHOR]

Published

2023

31. Flexible Prussian blue/Carbon dots nanocomposite modified exfoliated graphite paper based sensor for simultaneous monitoring of hypertension and Parkinson disease.

Author

Pandey, Indu, Tiwari, Jai Deo, Furukawa, Hidemitsu, Khosla, Ajit, and Sekhar, Praveen K.

Subjects

CARBON nanofibers, PRUSSIAN blue, PARKINSON'S disease, ELECTROCHEMICAL sensors, URIC acid, CARBON paper

Abstract

Patients with hypertension are seriously affected by Parkinson's disease than patients with normal blood pressure. Thus, early detection of hypertension and Parkinson disease by monitoring subtle changes in specific biomarkers from body fluids can minimize the risk. This paper proposes a flexible, portable paper-based sensor for simultaneous electrochemical sensing of dopamine and uric acid, using differential pulse voltammetry and electrochemical impedance spectroscopy on electrodeposited Prussian blue on carbon dots@graphite paper. The characteristic peaks of dopamine and uric acid in the differential pulse voltammogram are well separated. Further surface characterization of Prussian blue/carbon dots@graphite paper was carried out by Raman Spectra and Scanning Electron Microscope (SEM). The proposed sensor promoted the fast electrochemical detection of dopamine and uric acid with the linear response for concentrations from 0.2–920.0 μM with a limit of detection 0.015 μM, respectively in an aqueous sample. Excellent flexing stability is demonstrated by the proposed sensor, which can maintain its initial current after being bent more than 300 times. [ABSTRACT FROM AUTHOR]

Published

2022

32. Rethinking the paper product carbon footprint accounting standard from a life-cycle perspective.

Author

Liang, Ziyang, Deng, Huijing, Xie, Hongyi, Chen, Bin, Sun, Mingxing, and Wang, Yutao

Subjects

*PAPER products, *ACCOUNTING standards, *ECOLOGICAL impact, *CARBON nanofibers, *CARBON paper, *PRODUCT life cycle, *CARBON offsetting, *INCINERATION

Abstract

Paper products are carbon-intensive and having a huge potential for carbon reduction due to their biomass-oriented characteristics. A uniform standard for total carbon footprint (CF) accounting is vital. However, the existing standards have not yet been unified. Inconsistencies between standards cause difficulties in their use and significantly weaken the credibility and comparability of the carbon footprint of a product (CFP). This work rethought the three most widely used standards (Publicly Available Specification 2050 (PAS2050), Product Life Cycle Accounting and Reporting Standard (GHG Protocol), and Product Life Cycle Accounting and Reporting Standard (ISO14067)) from the life-cycle perspective, and established a more appropriate and comprehensive CF accounting standard for paper products (CFASPP). Sanitary pads were selected as a case study to illustrate the discrepancies between PAS 2050, the GHG Protocol, ISO 14067, and CFASPP, for which the annual production CF results were 1424.60, 1481.08, 1453.57, and 1427.04 tons of carbon dioxide equivalent (CO 2 e) respectively. The main reasons for the different CF results were the cut-off criteria and the inclusion or exclusion of carbon storage, delayed emissions, and energy recovery. Each element increased or decreased 22.57 (carbon storage), 29.96 (cut-off criteria), 10.4 (delayed emissions), and 27.52 (incineration with energy recovery) tons of CO 2 e in the results. With increasing demand, these discrepancies will become increasingly significant and may lead to corporations shouldering more or less carbon emission responsibilities by selecting different standards, which will challenge the fairness of product carbon neutrality management. CFASPP covers all paper product life-cycle stages and places greater emphasis on the aspects of carbon storage, delayed emissions, and energy recovery in incineration, which cannot be ignored for the CF accounting of paper products and other biomass-oriented products. This study aims to provide a more applicable and comprehensive guide for corporations to evaluate the CF of paper products, and to provide a reference for the construction of a carbon-neutral evaluation system. [ABSTRACT FROM AUTHOR]

Published

2023

33. Atomic Dual‐Site Ni/Co‐Decorated Carbon Nanofiber Paper for Efficient O2 Electrocatalysis and Flexible Zn‐Air Battery.

Author

Liu, Nianxi, Kumar, Anuj, Li, Zongge, Liu, Zhicheng, Zhao, Changkai, Meng, Xiangshe, Wang, Yaqun, Yang, Lei, and Zhang, Guoxin

Subjects

CARBON nanofibers, CARBON paper, ELECTROCATALYSIS, OXYGEN evolution reactions, OXYGEN reduction, CATALYTIC activity, WEARABLE technology

Abstract

The fabrication of flexible catalytic films with isolated single/dual‐atomic sites and their integration in wearable electronics is challenging. Herein, an efficient method to prepare atomically dispersed binary Ni/Co‐decorated flexible carbon nanofiber (NiCo‐CNF) film using formamide‐derived cyano‐specific NiCo‐NC as nanofillers was developed. The optimized Ni1Co1‐CNF catalytic film, having large‐area, high density of adjacent Ni‐N4 and Co‐N4 active sites, and good mechanical properties under repeated bending and release conditions, possessed high catalytic activity towards oxygen reduction reaction (ORR) and oxygen evolution reaction (OER). The ORR/OER potential difference (ΔE10) for Ni1Co1‐CNF at 10.0 mA cm−2 was highly comparable with the Pt/C+RuO2 mixture. In addition, flexible Ni1Co1‐CNF‐assembled Zn‐air battery displayed very good mechanical robustness and cycling stability. Our work may inspire the fabrication of other atomic metal‐decorated films for membrane electrocatalysis. [ABSTRACT FROM AUTHOR]

Published

2022

34. Cellulose Nanofibers/Pectin/Pomegranate Extract Nanocomposite as Antibacterial and Antioxidant Films and Coating for Paper.

Author

Hassan, Enas, Fadel, Shaimaa, Abou-Elseoud, Wafaa, Mahmoud, Marwa, and Hassan, Mohammad

Subjects

*PECTINS, *CARBON nanofibers, *POMEGRANATE, *CELLULOSE, *SUGAR beets, *NANOCOMPOSITE materials, *NANOFIBERS, *PACKAGING materials

Abstract

Bio-based polymer composites find increasing research and industrial interest in different areas of our life. In this study, cellulose nanofibers (CNFs) isolated from sugar beet pulp and nanoemulsion prepared from sugar beet pectin and pomegranate extract (PGE) were used for making films and used as coating with antioxidant and antimicrobial activities for paper. For Pectin/PGE nanoemulsion preparation, different ratios of PGE were mixed with pectin using ultrasonic treatment; the antibacterial properties were evaluated to choose the formula with the adequate antibacterial activity. The antioxidant activity of the nanoemulsion with the highest antimicrobial activity was also evaluated. The nanoemulsion with the optimum antibacterial activity was mixed with different ratios of CNFs. Mechanical, greaseproof, antioxidant activity, and antibacterial properties of the CNFs/Pectin/PGE films were evaluated. Finally, the CNFs/Pectin/PGE formulation with the highest antibacterial activity was tested as a coating material for paper. Mechanical, greaseproof, and air porosity properties, as well as water vapor permeability and migration of the coated layer from paper sheets in different media were evaluated. The results showed promising applicability of the CNFs/Pectin/PGE as films and coating material with antibacterial and antioxidant activities, as well as good stability for packaging aqueous, fatty, and acidic food products. [ABSTRACT FROM AUTHOR]

Published

2022

35. Multifunctional recycled carbon fiber-Ti3C2Tx MXene paper with superior electromagnetic interference shielding and photo/electro-thermal conversion performances.

Author

Wang, Kaifeng, Chen, Chi, Zheng, Qitan, Xiong, Juan, Liu, Hezhou, Yang, Lei, Chen, Yujie, and Li, Hua

Subjects

*ELECTROMAGNETIC shielding, *ELECTROMAGNETIC interference, *CARBON nanofibers, *CARBON fibers, *ELECTRONIC equipment, *DEFORMATIONS (Mechanics)

Abstract

The electromagnetic wave irradiation has obstructed the precise operation of the high-tech electronic equipment and threatened the health of the bodies during the 5G era. It is critical to develop electromagnetic interference (EMI) shielding materials with remarkable shielding effectiveness along with lightweight and flexible properties, while the integrations of the heat management performances have been gradually indispensable, especially in wearable electronic device applications. Anchoring the Ti 3 C 2 T x MXene nanosheets on the surfaces of the recycled carbon fibers (RCF) and assembling heterostructure can be regarded as effective strategies, while simultaneously solving the conductivity reduction and the corresponding performance degradation bottlenecks of the thermal-recycling carbon fiber. The construction of the RCF-MXene paper performs remarkable EMI shielding performance of 45.7 dB, while the specific SE/t can be improved to 7723.85 dB cm2 g-1, along with impressive photothermal and electrothermal conversion abilities. After coating PDMS layers, the flexible RCF-MXene@PDMS film maintains stable EMI shielding performance when experiencing in-situ electrothermal conversion and after 10000-cycle mechanical deformation processes. Exhibiting multifunctionality by facile synthesis strategies, the RCF-MXene-based materials provide great potential as next-generation candidates in wearable electronic devices, together with promoting the advancement of the sustainable reuse of the carbon fibers resources. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2022

36. An origami microfluidic paper device based on core-shell Cu@Cu2S@N-doped carbon hollow nanocubes.

Author

Li, Yuanyuan, Chen, Huinan, Huang, Rong, Deng, Dongmei, Yan, Xiaoxia, and Luo, Liqiang

Subjects

*CARBON nanofibers, *MICROFLUIDIC devices, *DNA folding, *ORIGAMI, *COPPER, *ALKALINE solutions, *TRANSITION metals

Abstract

The global prevalence of diabetes mellitus, a serious chronic disease with fatal consequences for millions annually, is of utmost concern. The development of efficient and simple devices for monitoring glucose levels is of utmost significance in managing diabetes. The advancement of nanotechnology has resulted in the indispensable utilization of advanced nanomaterials in high-performance glucose sensors. Modulating the morphology and intricate composition of transition metals represents a viable approach to exploit their structure/function correlation, thereby achieving optimal electrocatalytic performance of the synthesized catalysts. Herein, a sensitive and rapid Cu-encapsulated Cu 2 S@nitrogen-doped carbon (Cu@Cu 2 S@N–C) hollow nanocubes-functionalized microfluidic paper-based analytical device (μ-PAD) was fabricated. Through a delicate sacrificial template/interface technique and thermal decomposition, inter-connected hollow networks were formed to boost the active sites, and the carbon shell was coated to protect Cu from being oxidation. For application, the constructed μ-PAD is used for glucose sensing utilizing an origami automated sample pretreatment system enabled by a simple application of strong alkaline solution on wax paper. Under optimal circumstances, the Cu@Cu 2 S@N–C electrochemical biosensor exhibits broad detection range of 2–7500 μM (R2 = 0.996) with low detection limit of 0.16 μM (S/N = 3) and high sensitivity of 1996 μA mM−1 cm−2. Additionally, the constructed μ-PAD also exhibited excellent selectivity, stability, and reproducibility. By rationally designing the double-shell hollow nanostructure and introducing Cu-encapsulated inner layer, the synthesized Cu@Cu 2 S@N–C hollow nanocubes show large specific surface area, short diffusion channels, and high stability. The proposed origami μ-PAD has been successfully applied to serum samples without any additional sample preparation steps for glucose determination, offering a new perspective for early nonenzymatic glucose diagnosis. [Display omitted] • Cu@Cu 2 S@N–C hollow nanocubes-based origami μ-PAD sensor was fabricated. • Cu@Cu 2 S@N–C hollow nanocubes possessed large specific surface area and high stability. • Cu@Cu 2 S@N–C hollow nanocubes exhibited excellent electrocatalytic performance for glucose. • The proposed sensor was applied for glucose detection without any additional sample preparation steps. [ABSTRACT FROM AUTHOR]

Published

2024

37. Role of nanocellulose in colored paper preparation.

Author

Dai, Lei, Wang, Xiaowan, Jiang, Xue, Han, Qing, Jiang, Feng, Zhu, Xianqi, Xiong, Chuanyin, and Ni, Yonghao

Subjects

*CELLULOSE, *MANUFACTURING processes, *NANOFIBERS, *FUNCTIONAL groups, *REACTIVE dyes, *CARBON nanofibers, *SURFACE area

Abstract

Colored paper is an important industrial paper grade that has applications in various industrial sectors. The increase in coloring efficiency is a key in decreasing the use of dyes, thus can be considered as a "green" process concept; the coloring efficiency depends on the dye retention and dispersion. This work explores the use of nanocellulose, specifically, TEMPO-oxidized cellulose nanofibers (TOCNF), on the coloring efficiency of the preparation of colored paper. Two dyes (i.e. direct blue GL and reactive red 195 (RR195)) were used. Thanks to the large specific surface area and abundant active sites of TOCNF, its use largely improves the direct blue GL retention during the process. The coloring difference (∆E* ab) reached 5.334 with the addition of 13.6 wt% TOCNF and 1.8 wt% direct blue GL in the pulp furnish. The functional group in the dye is a vital factor in determining the dye retention when one chooses TOCNF to enhance the coloring efficiency in the production of colored paper. Furthermore, TOCNF significantly improved the strength properties of both direct blue GL and RR 195 dyed papers. This work demonstrates the potential of nanocellulose in the production of colored paper in improving the coloring efficiency, thus decreasing the environmental impact of the manufacturing process. [Display omitted] • Nanocellulose (i.e. TOCNF) adopted for colored paper preparation • Coloring efficiency improved by TOCNF due to the dye retention improvement • -COO− in TOCNF deteriorating its combination with negatively-charged dye [ABSTRACT FROM AUTHOR]

Published

2022

38. Nanofibers isolated from unbleached date palm residues pulps and their use for paper coating.

Author

Hassan, Mohammad L., Fadel, Shaimaa M., Abou Elseoud, Wafaa S., and Hassan, Enas A.

Subjects

*DATE palm, *CARBON nanofibers, *PAPER pulp, *NANOFIBERS, *SULFATE pulping process, *YOUNG'S modulus, *VAPOR barriers

Abstract

In the current work, cellulose nanofibers (CNF) were isolated from unbleached kraft pulps of date palm fruit stalks (DPFS) and date palm rachis (DPR) residues by ultrafine grinding. The isolated CNF were characterized by high-resolution transmission electron microscopy (HR-TEM), X-ray diffraction (XRD), zeta potential measurement, tensile strength properties, contact angle, as well as oil-proof testing. The CNF were applied as a coating material for cardboard paper sheets made from unbleached kraft DPFS and DPR pulps. The results showed that CNF from DPFS and DPR had close dimensions (4–14 nm in width and several microns in length) but their zeta potential was different (−44.65 eV and −51.46 eV for CNF from DPFS and DPR pulps, respectively), as well as their crystallinity (79.4% and 75.5% for CNF from DPFS and DPR pulps, respectively). CNF films from DPFS had tensile stress and Young's modulus of 113.3 MPa and 3.81 GPa, respectively, while those from DPR had tensile stress and Young's modulus of 71.0 MPa and 2.93 GPa, respectively. Films from DPFS CNF showed lower hydrophilicity than that from DPR, nevertheless excellent oil-proof property was obtained in both kinds of films. Coating of cardboard sheets prepared from unbleached kraft DPFS and DPR pulps with CNF layer of about 7-µm thickness resulted in significant changes in some physical properties of paper sheets, such as decreasing their air permeability, water vapor transmission rate, and water absorption; both kinds of CNF imparted paper sheets good oil-proof properties. CNF coating also imparted paper sheets remarkable wet tensile strength properties. The results showed the feasibility of utilizing date palm wastes in producing CNF films with distinct properties from low-cost unbleached kraft pulp, as well as using these CNF as a multi-functional coating material in papermaking industry. • Cellulose nanofibers (CNF) were isolated from unbleached date palm pulps. • The properties of CNF were dependent on the date palm residue used. • CNF films had excellent oil-proof and good mechanical properties. • CNF were successfully used for coating cardboard sheets. • CNF coating improved wet strength, air, oil, and moisture barrier properties. [ABSTRACT FROM AUTHOR]

Published

2024

39. Cellulose nanofibers from residues to improve linting and mechanical properties of recycled paper.

Author

Balea, Ana, Merayo, Noemí, Fuente, Elena, Negro, Carlos, Delgado-Aguilar, Marc, Mutje, Pere, and Blanco, Angeles

Subjects

CARBON nanofibers, AGROFORESTRY, RECYCLED paper, POLYACRYLAMIDE, PAPER mills

Abstract

The production of high filler-loaded recycled papers is often affected by high values of linting and low values of strength. In the first case, the accumulation of lint particles from paper’s surface on the printing blanket affects the quality of the printed paper and the pressroom’s productivity. In the second case, increasing the use of fillers and recycling cycles lead to poor paper strength. Cellulose nanofibers (CNFs) are receiving a great deal of attention due to their potential as a reinforcement aid for high filler-loaded papers through filler–fiber interaction and interfiber bonding. It is already proven that high quality CNFs can reduce linting, although their industrial application is limited by their high production cost. The objective of this research is, therefore, to quantify the effect of applying lower grade, more sustainable CNFs on linting phenomena and on the mechanical properties of recycled papers. Eucalyptus, pine and triticale residues were used as cellulose sources, and the CNFs were produced minimizing the chemical pretreatment before homogenization. Addition of 3 wt% of CNFs from pine residues into the recycled paper with 15.7 wt% of total filler reduced linting by 40% and increased tensile strength by 15.1%; further improvements on linting and mechanical properties were achieved at 5 wt%. Moreover, the increase in drainage time can be overcome by the addition of a retention aid, in this case a coagulant-cationic polyacrylamide-bentonite system, commonly used in paper mills. [ABSTRACT FROM AUTHOR]

Published

2018

40. A simple and tailor‐made fabrication of porous silicon carbide from functionalized kraft pulp paper.

Author

Bernard, Mégane, Lucas, Romain, Laadoua, Hatim, Khaldi, Zineb, Pradeilles, Nicolas, Rapaud, Olivier, Foucaud, Sylvie, Zerrouki, Rachida, and Brouillette, François

Subjects

PAPER pulp, KRAFT paper, SULFATE pulping process, POROUS silicon, SILICON carbide, CARBON nanofibers, HEMICELLULOSE, SCANNING electron microscopy

Abstract

Porous silicon carbide (SiC) materials were fabricated using the polymer‐derived ceramics method with kraft pulp papers (KPP) and a commercial polycarbosilane, the allylhydridopolycarbosilane (AHPCS), as starting materials. For this, KPP, propargylated KPP, or phosphorylated KPP were used to be impregnated by the AHPCS, with or without Karstedt catalyst. The pyrolysed materials were characterized at different stages, by using thermogravimetric analysis (TGA) coupled with mass spectrometry, X‐ray diffraction (XRD), and scanning electron microscopy (SEM). Depending on the nature of the initial template, various architectured SiC ceramics were successfully obtained with adjustable porosities. The key role of the previous functionalization of the papers was highlighted in terms of interactions at the interface between the polymer and the lignocellulosic handsheets. It led to either replica or sacrificial template methods. Thus, it was possible to tune the open porosity of the porous carbon and β‐SiC materials between 14.8% and 92.9%, with ceramic yields varying from 12% to 71%. [ABSTRACT FROM AUTHOR]

Published

2020

41. Hydrophobic microcapsule modification of nitrogen–phosphorus flame retardant and its application in lignocellulosic materials.

Author

Yang, Guochao, Zhang, Qiuhui, Li, Yan, and Ouyang, Yunshu

Subjects

FIREPROOFING agents, KRAFT paper, FLAME spread, CARBON nanofibers, SURFACE energy, CONTACT angle

Abstract

The microencapsulation of flame retardants can avoid the problems of water absorption and loss. In this paper, hydrophobic microcapsule-encapsulated ammonium polyphosphate (HMAPP) was prepared by ion exchange and Stöber method and applied to the preparation of hydrophobic flame-retardant kraft paper by impregnation. The microscopic morphology and element analysis of the hydrophobic microcapsules tested by TEM and SEM showed that nano-scale particles with a size of about 100 nm have been successfully prepared, and the core–shell structure has been formed. HMAPP constructed a rough structure with low surface energy on the surface of kraft paper and provided the kraft paper with hydrophobic property. The water contact angle of kraft paper reached 122.7 ° after treated by HMAPP, while it also enhanced the physical strength of the paper. Kraft had the self-extinguishing phenomenon after treated by HMAPP, which attached to the surface of kraft paper were heated and melted to release ammonia to dilute combustible gas and oxygen, and formed a flame-retardant layer containing SiO2 particles, phosphoric acid, metaphosphoric acid, pyrophosphoric acid, and carbon flakes on the fiber surface. There were C–C, C–O–C bonds in the carbon layer after flame-retardant treatment, indicating that the pentose contained in fiber has not been completely destroyed. In addition, the presence of Si and P elements in the residual carbon indicates that the decomposed flame retardant adheres to the surface of the fiber to block the heat transfer and flame spread. [ABSTRACT FROM AUTHOR]

Published

2022

42. Cerium oxide nanorods anchored on carbon nanofibers derived from cellulose paper as effective interlayer for lithium sulfur battery.

Author

Azam, Sakibul, Wei, Zhen, and Wang, Ruigang

Subjects

*LITHIUM sulfur batteries, *CARBON nanofibers, *CERIUM oxides, *NANORODS, *CELLULOSE, *CARBON fibers

Abstract

[Display omitted] Investigation of sluggish redox kinetics and polysulfide shuttling is crucial to design advanced lithium sulfur battery. Cerium oxide (CeO 2) has remarkable polysulfide adsorption capability and has been recently investigated in lithium sulfur battery application. With the goal of bridging towards commercialization of lithium sulfur battery, cellulose paper derived carbon fiber decorated with CeO 2 nanorods using hydrothermal method has been fabricated and used as interlayer material for lithium sulfur battery. In this novel design, the carbon fiber provides physical confinement with its 3-D interconnected conductive structure and CeO 2 adsorbs lithium polysulfides chemically to reduce shuttle effect to achieve long lifetime and high capacity for lithium sulfur battery. With a sulfur content of 2 mg, a high capacity of 1177 mAhg−1 was achieved at 0.2C with an excellent stability of only 0.11% capacity decay per cycle over 300 cycles. The improved performance is attributed to the binding of lithium polysulfides by CeO 2 and the blocking of polysulfides physically by the compact conducting carbon fiber. [ABSTRACT FROM AUTHOR]

Published

2022

43. Handheld detection strategy: Real-time on-site assay of Mn(VII) and GSH integrating ratiometric fluorescent carbon dots paper strip, smartphone, and 3D-printed accessory.

Author

Shi, Lihong, Feng, Jianyang, Li, Xianchan, Zhou, Wei, Zhang, Guomei, Zhang, Yan, Zhang, Caihong, and Shuang, Shaomin

Subjects

*CARBON paper, *SMARTPHONES, *FLUORESCENCE, *CARBON nanofibers, *PHOSPHORIC acid, *MOBILE apps

Abstract

Handheld detection platform integrating ratiometric fluorescent N,P co-doped carbon dots (N,P-CDs) paper strip, smartphone, and 3D-printed accessory corroborates its efficacy for visual quantitative detection of Mn(VII) and GSH via a continuous fluorescence color shift. N,P-CDs were synthesized by hydrothermal treatment of 1,8-diaminonaphthalene, phosphoric acid, and formamide. Inspiringly, with increasing Mn(VII) concentrations, blue emission of N,P-CDs decreases gradually at 445 nm and a ratio rising orange band emerges at 600 nm under 340 nm excitation, which concurrently exhibits continuous fluorescence color variation of blue, purplish blue, purplish pink, pink, to orange. Subsequent addition of GSH renders orange fluorescence of N,P-CDs@Mn(VII) gradually quench but blue peak slightly enhance, accompanied by the fluorescence color successively returning from orange to blue. The RGB values of the resulting images were precisely defined by a color recognition application within the smartphone, and the R/B values could be employed for Mn(VII) and GSH quantification with linear ranges of 0 − 40 μM and 0 − 28 μM, respectively, as well as limits of detection of 24.49 nM and 21.41 nM, respectively. It is solicitously anticipated that our research will provide novel insight for the development of effective sensing protocol and the enlargement of practical application prospect. • Handheld detection integrates FL paper strip, smartphone and 3D-printed accessory. • Paper strip is stained by single ratiometric-FL CDs for Mn(VII) and GSH sensing. • High sensitivity is gotten due to well-resolved FL color shift of paper strip. [ABSTRACT FROM AUTHOR]

Published

2023

44. One-step solvothermal method synthesizes petal-like Cu2WSx supported on carbon paper used in dye-sensitized solar cells.

Author

Liu, Mingzhu, Zhang, Kailiang, Cao, Ying, Liang, Chengyang, Geng, Shitong, Guo, Haipeng, Liu, Ying, Luo, Yanhong, Zhang, Wenming, and Li, Ling

Subjects

*DYE-sensitized solar cells, *CARBON paper, *METAL sulfides, *CARBON nanofibers, *ENERGY conversion, *TRANSITION metals

Abstract

Sheet-like transition metal sulfides have promising applications in photocatalysis and energy conversion. This study provides a petal-like Cu 2 WS x nanosheet structure supported on carbon paper (CP) synthesized by a simple one-step solvothermal method. Cu 2 WS x microstructures with different morphologies were synthesized by solvothermal vulcanization of thioacetamide (TAA) at different concentrations. The Cu 2 WS x /CP was used as the counter electrode of DSSCs and compared with the Pt FTO electrode. It was proved that Cu 2 WS x -7 M/CP had the best electrocatalytic performance and obtained 9.01% photoelectric conversion efficiency. The different sulfide concentration changes the morphology of Cu 2 WS x and continuously affects the specific surface area and catalytic activity of the material. The better electrochemical performance shows that Cu 2 WS x /CP is expected to become a substitute for expensive Pt CE materials in dye-sensitized solar cells (DSSCs). [Display omitted] • One-step solvothermal method for the growth of petal-like Cu 2 WS x on carbon paper. • The effect of sulfide concentration on Cu2WSx was explored for the first time by TAA. • For the first time, Cu 2 WS x /CP was used as a counter electrode for DSSCs. • At a sulfide concentration of 7 M, Cu 2 WS x /CP exhibited a value of 9.01% PCE (Pt 7.67%). [ABSTRACT FROM AUTHOR]

Published

2023

45. Use of Cellulose for the Production of Photocatalytic Films for Hydrogen Evolution Along the Lines of Paper Production.

Author

Schwarze, Michael, Thiel, Tabea A., Tasbihi, Minoo, Schroeter, Michael, Menezes, Prashanth W., Walter, Carsten, Driess, Matthias, and Schomäcker, Reinhard

Subjects

CELLULOSE, PLATINUM nanoparticles, CARBON nanofibers, HYDROGEN production, FILMMAKING, ATOMIC hydrogen, STEAM reforming

Abstract

Following the example of photovoltaics, one approach to large‐scale photocatalytic hydrogen production is the irradiation of a correspondingly large catalyst area. Paper production is a process in which large areas can already be produced based on the main component: cellulose. Herein, the TiO2 photocatalyst modification PC500, which also uses platinum nanoparticles as a cocatalyst, is supported in two different ways using cellulose. On the one hand, the catalyst is fixed to the surface of a commercial filter paper and, on the other hand, a photocatalytic paper is produced. For comparison, the catalyst is immobilized by means of drop coating using Nafion and measured as a suspension. The cellulose‐stabilized films are active and hydrogen production is comparable with the activity obtained from the drop‐coating method. The experiments show that the aggregation behavior of cellulose can be used to produce photocatalytically active films. The preparation is easy and can be applied to different kinds of (photo)catalysts. Although the films are very active, their stability during reaction due to swelling and hydrogen production must be further improved. [ABSTRACT FROM AUTHOR]

Published

2022

46. Developing Cheap and Mass‐Producible Graphite‐Filled Paper as an Anode Material for Microbial Electrochemical Technologies.

Author

Alvarez Esquivel, Diana Y., Brown, Robert Keith, Knohl, Stefan, and Schröder, Uwe

Subjects

TECHNOLOGY, MATERIALS, ELECTRODES, CARBON nanofibers, BIOMASS

Abstract

This study details, in‐depth, the development of graphite paper as electrodes, specifically anodes, for microbial electrochemical technologies. Processed natural graphite powders were used as an active filler substance in paper composites. Mechanical and electrical properties were balanced during development. Graphite papers with 80 wt% natural graphite content had tear lengths of 730±58 m and resistivities of 0.014±0.001 Ω cm. Electrochemically active biofilms on these materials, cultivated from biomass taken from the bioanodes of an already running bioelectrochemical reactor, were fed with acetate and yielded an average maximum current density of 0.855±0.135 as well as 0.489±0.148 mA cm−2 with a complex substrate mixture. All anodes exhibited similar performance to commonly used carbonaceous electrodes fed the same substrates. This places them as flexible and cheap electrode materials suitable for large‐scale microbial electrochemical technologies. [ABSTRACT FROM AUTHOR]

Published

2020

47. Black liquor gasification with calcium looping for carbon-negative pulp and paper industry.

Author

Santos, Mónica P.S., Manovic, Vasilije, and Hanak, Dawid P.

Subjects

SULFATE waste liquor, PAPER industry, SOLID oxide fuel cells, CARBON sequestration, CARBON dioxide, CARBON nanofibers

Abstract

• Black liquor gasification was coupled with calcium looping. • Calcium looping for CO 2 capture and H 2 production was compared. • CO 2 capture route (39 €/t) was less expensive than H 2 production route (48.8 €/t). • CO 2 avoided cost was highly dependent on capital cost of black liquor gasification. • Export of H 2 had the lowest CO 2 avoided cost among black liquor gasification cases. Although considered one of the major energy-intensive industries (EIIs), the pulp and paper industry has also the potential for energy production from an industrial waste, black liquor. This study proposes black liquor gasification (BLG) coupled with calcium looping (CaL) as a CO 2 capture route for the pulp and paper industry. BLG with H 2 production (BLG-CaL-H 2), BLG with gas turbine combined cycle (BLG-CaL-GT) or with solid oxide fuel cell (BLG-CaL-SOFC) were considered. The dependence of carbon capture and storage (CCS) cost on the natural gas, limestone, electricity imported and H 2 sale prices aside the expenditures related with BLG-CaL were evaluated. The CCS route, based on CaL retrofitted to the pulp and paper plant, was found to have a lower cost of CO 2 avoided (39.0 €/tCO 2) when compared with BLG-CaL (48.8–57.1 €/tCO 2). Between the BLG-CaL scenarios, BLG-CaL-H 2 presented the lowest cost of CO 2 avoided (48.8 €/tCO 2) but the highest energy penalty. Based on the thermodynamic performance, it was shown that CaL retrofit and BLG-CaL-SOFC presented the best overall performance, turning the electricity importer reference plant into electricity exporter. The economic sensitivity showed that the capital requirement of BLG-CaL has a strong effect on the cost of CO 2 avoided for all alternatives. The H 2 production is also strongly affected by the H 2 sale price while BLG-CaL-SOFC and BLG-CaL-GT are strongly dependent on natural gas price. [ABSTRACT FROM AUTHOR]

Published

2021

48. MWCNTs modified α-Fe2O3 nanoparticles as anode active materials and carbon nanofiber paper as a flexible current collector for lithium-ion batteries application.

Author

Chen, Xu, Zhao, Zhen, Zhou, Yan, Shu, Yun, Sajjad, Muhammad, Bi, Qinsong, Ren, Yang, Wang, Xu, Zhou, Xiaowei, and Liu, Zhu

Subjects

*NANOPARTICLES, *MULTIWALLED carbon nanotubes, *SEMICONDUCTORS, *ANODES, *ELECTRODES, *CURRENT density (Electromagnetism), *CARBON nanofibers

Abstract

Abstract α-Fe 2 O 3 nanoparticles/multi-wall carbon nanotubes (MWCNTs) hybrids were successfully prepared via a facile one-step hydrothermal method. The MWCNTs enhances the conductivity and provides space for stress and strain during volume expansion of α-Fe 2 O 3 semiconductor as the anode for LIBs. The composite shows impressive electrochemical performance when it was used as the electrodes of coin cells. The α-Fe 2 O 3 electrode with 50 wt% MWCNTs retains its capacity of 816.8 mAh g−1 after 50 cycles at the current density of 200 mA g−1, which is superior to those of contrast samples (bare α-Fe 2 O 3 , pure MWCNTs, 10 wt%, 30 wt%, 70 wt% MWCNT/α-Fe 2 O 3 hybrids). Furthermore, the flexible carbon nanofiber paper (CNP) has also been investigated as a novel current collector with lithium storage for application in LIBs, and the capacity of free-standing α-Fe 2 O 3 /50 wt%MWCNTs/CNP hybrids electrode can retain 467.2 mAh g−1 after 50 cycles under the current density of changes from 2500 mA g−1 to 200 mA g−1. The MWCNTs improved cycle performance, enhanced reversible capacities and rate capability of MWCNTs/α-Fe 2 O 3 anodes can attribute to the inherent conducting network, shorten electron pathway and faster reaction kinetics. Highlights • α-Fe 2 O 3 /MWNT nanocomposite electrodes for flexible LIBs. • α-Fe 2 O 3 embedded in the outer carbon nanotube. • Hybrids electrode exhibits superior electrochemical properties. • Free-standing carbon nanofiber paper applied to light-weighted LIBs. [ABSTRACT FROM AUTHOR]

Published

2019

49. Modelling of carbon utilisation efficiency and its application in milling parameters optimisation.

Author

Deng, Zhaohui, Lv, Lishu, Huang, Wenliang, Wan, Linlin, and Li, Shichun

Subjects

CARBON, CARBON nanofibers, CARBON paper, MANUFACTURING processes

Abstract

At present, the evaluation index for low carbon manufacturing was mainly focused on the relationship between carbon emission and economic benefits or removal volume. But there was rarely comprehensive evaluation index to evaluate the carbon utilisation level of processing. Based on this, this paper presented the carbon utilisation efficiency as the comprehensive evaluation index in low carbon manufacturing. The carbon utilisation efficiency was defined as the ratio of the carbon emission of materials removal to the whole carbon emission in manufacturing process. A carbon utilisation efficiency model was established in milling process, based on flow characteristics and removal mechanism of carbon emission during milling. Then a multi-objective optimisation model was established based on Particle Swarm Optimisation, and the minimum processing time and high carbon utilisation efficiency were set as the optimisation objectives. And the experiment was performed to confirm the undetermined constant in the optimisation model and verify the effectiveness of the optimisation model. The optimised milling parameters were verified to reduce the processing time and improve the carbon utilisation efficiency. [ABSTRACT FROM AUTHOR]

Published

2020

50. Magnetic Ti3C2Tx/Fe3O4/Aramid nanofibers composite paper with tunable electromagnetic interference shielding performance.

Author

Jia, Fengfeng, Xie, Fan, Chen, Shanshan, Wang, Danni, Jin, Zhanfan, Zhuo, Longhai, and Lu, Zhaoqing

Subjects

*ELECTROMAGNETIC shielding, *ELECTROMAGNETIC interference, *NANOFIBERS, *YOUNG'S modulus, *ELECTRONIC equipment, *ELECTRIC conductivity, *CARBON nanofibers

Abstract

Increasingly popularity of electronic devices and wireless apparatus requires advanced materials to cope with severe electromagnetic wave pollution. Herein, magnetic EM wave shielding material, Ti3C2Tx/Fe3O4/aramid nanofibers composite paper, composed of low-dimensional Ti3C2Tx flakes and carboxylation Fe3O4 nanoparticles, was developed via vacuum-assisted filtration. At the meanwhile, uniform dispersion of components was achieved to overcome magnetic through ingenious electrostatic force regulation originated from negative functional groups. The Ti3C2Tx/Fe3O4/aramid nanofibers composite paper exhibited suitable magnetic performance, outstanding electrical conductivity, and excellent electromagnetic interference shielding performance. Moreover, the Ti3C2Tx/Fe3O4/aramid nanofibers composite paper demonstrated favorable mechanical properties, whose tensile strength and Young's modulus reached 132.2 ± 2.1 MPa and 5.23 ± 0.14 GPa, respectively. The combination of electromagnetic shielding capacity (derived from Ti3C2Tx flakes, carboxylation Fe3O4 nanoparticles) and mechanical properties (derived from aramid nanofibers) provided feasible strategy in fabricating advanced EMI shielding composite with astonishing comprehensive performance. [ABSTRACT FROM AUTHOR]

Published

2021