Showing total 2,454,413 results

1. A new type of lipophilic hydrophobic self‐repairing cellulose insulating paper developed with ST‐110/FAS/PTFE ternary system as coating substrate.

Author

Zeng, Zhenglin, Qin, Jinshan, Wang, Zuhao, Tan, Weimin, and Tang, Chao

Published

2024

2. Preparation of superhydrophobic conductive micro/nano‐graphite/PDMS films on paper by simple spraying method.

Author

He, Qiang, Du, Zhicai, Jia, Yangyang, Liu, Yujie, Xu, Zehua, Xu, Yuan, and Li, Anling

Subjects

CHEMICAL stability, FILTER paper, SURFACE energy, ROLLING contact, METAL spraying, CONTACT angle, POLYDIMETHYLSILOXANE, GRAPHITE

Abstract

Paper‐based materials are widely used in various fields due to their advantages, such as environmental friendliness and sustainability. However, the highly hydrophilic nature of the cellulose that makes up paper‐based materials limits their use. In this paper, micron/nano‐graphite/polydimethylsiloxane (PDMS) coatings with excellent superhydrophobic and conductive properties were prepared on the surface of filter paper by a simple spraying method. A mixture of micro‐graphite and nano‐graphite was used to form a multistage rough structure on the surface of the filter paper by spraying, and the low surface energy PDMS enhanced the adhesion of the micro‐graphite and nano‐graphite on the surface of the filter paper. The results showed that the samples possessed the best superhydrophobic properties when the ratio of micro‐graphite to nano‐graphite was 1:1, at which time the contact and rolling angles of the samples were 165.4° and 3.2°, respectively. The prepared superhydrophobic samples have good bounce and self‐cleaning properties, while the samples have good mechanical stability and chemical resistance. Additionally, due to the conductivity of micro–nano‐graphite, both particle sizes closely contact the sample surface, creating a conductive network. With a 1:1 ratio of micro‐ and nano‐graphite, the coating exhibits minimal resistance at 1.89 KΩ, and the sample maintains stable conductivity even underwater. The above properties greatly extend the application range of paper‐based superhydrophobic materials. [ABSTRACT FROM AUTHOR]

Published

2024

3. 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

4. How do we achieve blinding in modern electronic and paper medical records during the conduct of transfusion trials?

Author

Santos, Sean, Gupta, Akash, Tinmouth, Alan, Butt, Amir, Berry, Brian, Musuka, Charles, Cserti‐Gazdewich, Christine, Leung, Elaine, Duncan, Jennifer, Mack, Johnathan, Yan, Matthew T. S., Bahmanyar, Mohammad, Shehata, Nadine, Prokopchuk‐Gauk, Oksana, Onell, Rodrigo, Nahirniak, Susan, Covello, Thomas, Lin, Yulia, Solh, Ziad, and Callum, Jeannie

Subjects

ELECTRONIC health records, ELECTRONIC records, BLOOD transfusion, ELECTRONIC paper, PRODUCT coding, BLOOD platelet transfusion

Abstract

Background: Regulatory aspects of transfusion medicine add complexity in blinded transfusion trials when considering various electronic record keeping software and blood administration processes. The aim of this study is to explore strategies when blinding transfusion components and products in paper and electronic medical records. Methods: Surveys were collected and interviews were conducted for 18 sites across various jurisdictions in North America to determine solutions applied in previous transfusion randomized control trials. Results: Sixteen responses were collected of which 11 had previously participated in a transfusion randomized control trial. Various solutions were reported which were specific to the laboratory information system (LIS) and electronic medical record (EMR) combinations although solutions could be grouped into four categories which included the creation of a study product code in the LIS, preventing the transmission of data from the LIS to the EMR, utilizing specialized stickers and labels to conceal product containers and documents in the paper records, and modified bedside procedures and documentation. Discussion: LIS and EMR combinations varied across sites, so it was not possible to determine combination‐specific solutions. The study was able to highlight solutions that may be emphasized in future iterations of LIS and EMR software as well as procedural changes that may minimize the risk of unblinding. [ABSTRACT FROM AUTHOR]

Published

2024

5. A novel approach to Hg2+ determination in water samples using carbon dots based on paper and fluorescence digital image analysis.

Author

Maia, Matheus Valentin, Suarez, Willian Toito, dos Santos, Vagner Bezerra, de Oliveira, Severino Carlos Bezerra, and de Almeida, João Paulo Barbosa

Subjects

DIGITAL images, ELECTRONIC paper, IMAGE analysis, WATER sampling, SUSTAINABLE chemistry, WATER use, QUANTUM dots, MERCURY

Abstract

BACKGROUND: This work proposes the use of a simple, inexpensive method for the hydrothermal synthesis of fluorescent carbon dot nanoparticles (CDs) from rice starch aimed at the determination of Hg2+ in water. The proposed method involved using a paper‐based analytical device coupled to a 3D plate, with a UV‐LED chamber and a smartphone for the acquisition and analysis of the fluorescence digital images of the CDs. RESULTS: The size of the carbon dots ranged from 0.5 to 3 nm, with an average particle size of ~1 nm. The functionalization of carbon dots with methimazole allowed a high selective for Hg2+ determination. The results obtained showed a linear response R2 of 0.997 and Hg2+ concentration in the range of 0.5–45.0 μmol L−1 with a limit of detection and limit of quantitation of 0.23 and 0.62 μmol L−1, respectively. The results of the study show that there were no significant differences, at 95% confidence level, between the data obtained from the application of the proposed method and the reference method. CONCLUSION: The proposed method is in line with the principles of green chemistry, as it involves the use of renewable sources for starch extraction and a hydrothermal synthesis process that does not employ toxic reagents. In addition, the method employs only 15 μL reagent/sample. © 2024 Society of Chemical Industry (SCI). [ABSTRACT FROM AUTHOR]

Published

2024

6. Author Index.

Subjects

PAPER arts, GOVERNMENT report writing, AUTHORS

Published

2020

7. KH550‐SiO2/polyimide insulating paper preparation and characterisation.

Author

Chi, Minghe, Sun, Xue, Zhang, Xiaorui, Shi, Jiahao, Weng, Ling, and Yu, Yang

Published

2024

8. Streptomyces spp. as biocatalyst sources in pulp and paper and textile industries: Biodegradation, bioconversion and valorization of waste.

Author

Cuebas‐Irizarry, Mara F. and Grunden, Amy M.

Subjects

PAPER industry, COLOR removal in water purification, BIOCONVERSION, STREPTOMYCES, ENZYMES, WASTE paper, COLOR removal (Sewage purification)

Abstract

Complex polymers represent a challenge for remediating environmental pollution and an opportunity for microbial‐catalysed conversion to generate valorized chemicals. Members of the genus Streptomyces are of interest because of their potential use in biotechnological applications. Their versatility makes them excellent sources of biocatalysts for environmentally responsible bioconversion, as they have a broad substrate range and are active over a wide range of pH and temperature. Most Streptomyces studies have focused on the isolation of strains, recombinant work and enzyme characterization for evaluating their potential for biotechnological application. This review discusses reports of Streptomyces‐based technologies for use in the textile and pulp‐milling industry and describes the challenges and recent advances aimed at achieving better biodegradation methods featuring these microbial catalysts. The principal points to be discussed are (1) Streptomyces' enzymes for use in dye decolorization and lignocellulosic biodegradation, (2) biotechnological processes for textile and pulp and paper waste treatment and (3) challenges and advances for textile and pulp and paper effluent treatment. [ABSTRACT FROM AUTHOR]

Published

2024

9. Cellulosic Nanofibers Utilizing a Silicone Elastomeric Core to Form Stretchable Paper.

Author

Dorsainvil, Joab S., Brown, Matthew S., Rafiee, Zahra, Elhadad, Anwar, Choi, Seokheun, and Koh, Ahyeon

Subjects

CELLULOSE acetate, BIOELECTRONICS, NANOFIBERS, WEARABLE technology, SILICONES, ELASTOMERS, CELLULOSE fibers, SILICONE rubber

Abstract

Paper, an inexpensive material with natural biocompatibility, non‐toxicity, and biodegradability, allows for affordable and cost‐effective substrates for unconventional advanced electronics, often called papertronics. On the other hand, polymeric elastomers have shown to be an excellent success for substrates of soft bioelectronics, providing stretchability in skin wearable technology for continuous sensing applications. Although both materials hold their unique advantageous characteristics, merging both material properties into a single electronic substrate reimagines paper‐based bioelectronics for wearable and patchable applications in biosensing, energy generation and storage, soft actuators, and more. Here, a breathable, light‐weighted, biocompatible engineered stretchable paper is reported via coaxial nonwoven microfibers for unconventional bioelectronic substrates. The stretchable papers allow intimate bioconformability without adhesive through coaxial electrospinning of a cellulose acetate polymer (sheath) and a silicone elastomer (core). The fabricated cellulose‐silicone fibers exhibit a greater percent strain than commercially available paper while retaining hydrophilicity, biocompatibility, combustibility, disposable, and other natural characteristics of paper. Moreover, the nonwoven stretchable cellulose‐silicone fibrous mat can adapt conventional printing and fabrication process for paper‐based electronics, an essential aspect of advanced bioelectronic manufacturing. [ABSTRACT FROM AUTHOR]

Published

2024

10. Is There a Difference between Paper and Electronic Chinese Signatures?

Author

Luo, Ji-Feng, Pu, Yun-Zhu, Yin, Jie-Yang, Liu, Xiaohong, Tan, Tao, Zhang, Yudong, and Hu, Menghan

Subjects

ARTIFICIAL neural networks, ELECTRONIC paper, DIGITAL signatures, CONVOLUTIONAL neural networks, WILCOXON signed-rank test

Abstract

The purpose of this study is to investigate whether there are differences in handwritten Chinese signatures on different media including paper and electronic devices. Participants were asked to sign specified names on various types of media and the signatures were scanned or saved digitally for subsequent analysis. In this study, using convolutional neural networks and Siamese neural networks as classifiers and comparators, the performance plunge is revealed and thus considerable dissimilarity between the signatures on different media is implied. To further explore this, cubic Bézier curves are fitted to the signatures using the least square method for quantitative statistical analysis. By analyzing the visual changes in the morphology of strokes, several features of signatures are selected and computed, and the paired t‐test and the Wilcoxon signed‐rank test are implemented, which provides a deeper substantiation and explanation of the findings. [ABSTRACT FROM AUTHOR]

Published

2023

11. Dynamics of an impurity ion transport in oil‐paper insulation under various electric fields.

Author

Ren, Yuanyang, Wang, Yang, Zhang, Qiankai, Xiong, Jiayu, Cao, Wen, Lv, Zepeng, and Wu, Kai

Published

2024

12. Risks of abuse of large language models, like ChatGPT, in scientific publishing: Authorship, predatory publishing, and paper mills.

Author

Kendall, Graham and Teixeira da Silva, Jaime A.

Subjects

LANGUAGE models, CHATGPT, AUTHORSHIP, PREDATORY open access publishing, SCIENCE publishing, PAPER mills, PAPER industry

Abstract

Key points: Academia is already witnessing the abuse of authorship in papers with text generated by large language models (LLMs) such as ChatGPT.LLM‐generated text is testing the limits of publishing ethics as we traditionally know it.We alert the community to imminent risks of LLM technologies, like ChatGPT, for amplifying the predatory publishing 'industry'.The abuse of ChatGPT for the paper mill industry cannot be over‐emphasized.Detection of LLM‐generated text is the responsibility of editors and journals/publishers. [ABSTRACT FROM AUTHOR]

Published

2024

13. Open-source electrochemical cell for in situ X-ray absorption spectroscopy in transmission and fluorescence modes.

Author

Lopez-Astacio, Hiram, Vargas-Perez, Brenda Lee, Del Valle-Perez, Angelica, Pollock, Christopher J., and Cunci, Lisandro

Subjects

ELECTRIC batteries, X-ray absorption, FLUORESCENCE spectroscopy, CARBON paper, STANDARD hydrogen electrode, X-ray spectroscopy

Abstract

X-ray spectroscopy is a valuable technique for the study of many materials systems. Characterizing reactions in situ and operando can reveal complex reaction kinetics, which is crucial to understanding active site composition and reaction mechanisms. In this project, the design, fabrication and testing of an open-source and easy-to-fabricate electrochemical cell for in situ electrochemistry compatible with X-ray absorption spectroscopy in both transmission and fluorescence modes are accomplished via windows with large opening angles on both the upstream and downstream sides of the cell. Using a hobbyist computer numerical control machine and free 3D CAD software, anyone can make a reliable electrochemical cell using this design. Onion-like carbon nanoparticles, with a 1:3 iron-to-cobalt ratio, were drop-coated onto carbon paper for testing in situ X-ray absorption spectroscopy. Cyclic voltammetry of the carbon paper showed the expected behavior, with no increased ohmic drop, even in sandwiched cells. Chronoamperometry was used to apply 0.4 V versus reversible hydrogen electrode, with and without 15 min of oxygen purging to ensure that the electrochemical cell does not provide any artefacts due to gas purging. The XANES and EXAFS spectra showed no differences with and without oxygen, as expected at 0.4 V, without any artefacts due to gas purging. The development of this open-source electrochemical cell design allows for improved collection of in situ X-ray absorption spectroscopy data and enables researchers to perform both transmission and fluorescence simultaneously. It additionally addresses key practical considerations including gas purging, reduced ionic resistance and leak prevention. [ABSTRACT FROM AUTHOR]

Published

2024

14. Establishment of a measurement system to evaluate breast milk transfer of biological agents using dry filter paper: A multi‐institutional study.

Author

Saito, Jumpei, Yakuwa, Naho, Hosokawa, Yoshihiko, Hamada, Hiromi, Suzuki, Tomo, Sago, Haruhiko, Kaneko, Kayoko, Yamatani, Akimasa, and Murashima, Atsuko

Subjects

BREAST milk, FILTER paper, BREAST milk collection & preservation, DRYING agents, BREASTFEEDING, ENZYME-linked immunosorbent assay, GOLIMUMAB, ABATACEPT

Abstract

Aims: Information on breastfeeding and safety of biologics in infants is lacking due to difficulties in case collection. We evaluated methods for determining the concentration of biologics in breast milk using a dry filter method that can simplify the collection, storage and transport of breast milk. Methods: To generate dried filter paper (DFP) samples, approximately 30 μL of breast milk was placed onto a Whatman 903 card and punched out. After extraction, the supernatant was measured using an enzyme‐linked immunosorbent assay. Three concentrations of each drug were prepared in liquid breast milk (LBM) and DFP samples to determine their stability up to 28 days after storage at 2–8°C or −20°C for LBM and 25 ± 5°C for DFP. LBM and DFP samples were also provided by nursing mothers using biologics during lactation, and drug concentrations in both samples were compared. The agreement between the two measurement methods was confirmed by Bland–Altman analysis. Results: Breast milk was provided by 12 mothers who used biologics (tocilizumab, abatacept, etanercept, golimumab, sarilumab and belimumab). The coefficients of variation for within‐run and between‐run precision for the six drugs were within 15% for both LBM and DFP, and accuracy was within 90%–110% of the quality controls. After 28 days, concentrations remained at more than 90%. The difference between the values obtained by each method was within the acceptable range of error (−12.1 to +16.6 ng/mL). Conclusions: A method for determining the concentration of biologics using DFP is expected to help improve pharmacotherapy for lactating women. [ABSTRACT FROM AUTHOR]

Published

2024

15. Integrated Ink Printing Paper Based Self‐Powered Electrochemical Multimodal Biosensing (IFP−Multi) with ChatGPT–Bioelectronic Interface for Personalized Healthcare Management.

Author

Xiong, Chuanyin, Dang, Weihua, Yang, Qi, Zhou, Qiusheng, Shen, Mengxia, Xiong, Qiancheng, An, Meng, Jiang, Xue, Ni, Yonghao, and Ji, Xianglin

Subjects

PRINTING ink, ELECTROCHEMICAL apparatus, WRIST, MUSCLE contraction, PATIENT monitoring, WEARABLE technology

Abstract

Personalized healthcare management is an emerging field that requires the development of environment‐friendly, integrated, and electrochemical multimodal devices. In this study, the concept of integrated paper‐based biosensors (IFP−Multi) for personalized healthcare management is introduced. By leveraging ink printing technology and a ChatGPT–bioelectronic interface, these biosensors offer ultrahigh areal‐specific capacitance (74633 mF cm−2), excellent mechanical properties, and multifunctional sensing and humidity power generation capabilities. More importantly, the IFP−Multi devices have the potential to simulate deaf‐mute vocalization and can be integrated into wearable sensors to detect muscle contractions and bending motions. Moreover, they also enable monitoring of physiological signals from various body parts, such as the throat, nape, elbow, wrist, and knee, and successfully record sharp and repeatable signals generated by muscle contractions. In addition, the IFP−Multi devices demonstrate self‐powered handwriting sensing and moisture power generation for sweat‐sensing applications. As a proof‐of‐concept, a GPT 3.5 model‐based fine‐tuning and prediction pipeline that utilizes recorded physiological signals through IFP−Multi is showcased, enabling artificial intelligence with multimodal sensing capabilities for personalized healthcare management. This work presents a promising and ecofriendly approach to developing paper‐based electrochemical multimodal devices, paving the way for a new era of healthcare advancements. [ABSTRACT FROM AUTHOR]

Published

2024

16. Fabrication of biodegradable kraft paper from buffing dust and jute fiber: Green solutions for packaging.

Author

Noyon, Ashikur Rahaman, Karim, Suzaul, Rouf, Abdur, Jamal, Mamun, Layek, Rama Kanta, Sivanantham, Gokulkumar, and Uddin, Elias

Subjects

KRAFT paper, JUTE fiber, WASTE recycling, WASTE management, SOLID waste, PACKAGING recycling, DUST

Abstract

Addressing solid waste recycling, this study aims to develop biodegradable kraft paper from buffing dust (BD) and post‐consumed jute fiber (JF). Employing a simple solution casting method with a polyurethane binder, the kraft paper was fabricated and characterized using UV–Vis spectroscopy, FTIR, XRD, SEM, TGA, OTR, biodegradability, and tensile tests. The findings revealed covalent and hydrogen bonding between BD and JF, forming a uniform surface. Notably, the composite exhibited improved thermal stability, enhanced gas barrier properties, and biodegradability compared to individual components. Furthermore, the composite also showed 57% higher tensile strength, 38% greater elongation, 20% increased hardness, and 9% higher density compared to buffing dust. Compared to jute fiber, the increases were 125%, 91%, 30%, and 19% respectively. Moreover, the composite excelled in gas barrier performance, surpassing BD and JF by a remarkable 61% and 73% increase respectively. These significant findings underscore the vast potential of the composite kraft paper as a versatile material suitable for various applications, including packaging, interior furnishing industries, and reinforcing elements in the footwear industry. By addressing waste management and promoting sustainability, this research contributes to the development of eco‐friendly materials that align with contemporary environmental concerns. Highlights: Covalent and hydrogen bonding enhance uniformity.Biodegradable kraft paper with improved properties.Impressive tensile strength, elongation, and hardness.Versatile material for eco‐friendly applications.Promotes sustainability and waste management. [ABSTRACT FROM AUTHOR]

Published

2023

17. Evaluating Properties of Green Concrete Produced Using Waste Marble Powder, Quarry Dust, and Paper Pulp.

Author

Disale, Anil, Nayak, Chittaranjan, Suryawanshi, Nagesh, Jadhav, Nitin, Jagdale, Umesh, Kate, Gunwant, Thakare, Sunil, Pandey, Shri Prakash, Sharma, Prakhakar, and Saxena, Amit

Subjects

PAPER pulp, CONCRETE, INDUSTRIAL wastes, ALKALI-aggregate reactions, CONSTRUCTION materials, DETERIORATION of concrete

Abstract

Industrial waste locks are used as raw materials to reduce harmful effects on the environment and improve environmental performance. Marble clay powder can be used as a filling aid and can fill voids in concrete structures. This article will show you how to use a maximum natural sand alternative in concrete with marble powder and quarry dust. The challenge of the 21st century is to change to a new form that can support the natural system. This necessitates a radical rethinking of how to give the community infrastructure and housing. Making a concerted effort to develop novel, innovative, and alternative construction materials may be necessary. Jungles of concrete around cause's impact on the Environment and it would result in climate change. Mankind must avoid the use of things that are detrimental to the environment. So in this paper, it is decided to address the issue by adopting the use of the green concrete concept which is environmentally friendly. Green concrete is concrete made up using industrial wastes such as marble powder, quarry dust, wood ash, paper pulp, etc. Green concrete, which is capable of sustainable development, helps to reduce the consumption of natural resources, energy use, and environmental pollution. Green concrete is more cost‐effective than ordinary concrete and reduces the cost of resultant concrete by 14%–20%. It is also observed that the alkali‐aggregate reaction and sulfate attack resistance of concrete are both significantly improved. Green concrete is a useful tool for lowering environmental pollution and enhancing concrete's resistance to harsh conditions. All stages of infrastructure construction and rehabilitation will follow this trend of using new cement and techniques. Green concrete's adaptability and its performance derivatives will meet a variety of future needs. [ABSTRACT FROM AUTHOR]

Published

2024

18. Soy protein isolate/MXene decorated acidified carbon paper interlayer for long‐cycling Li–S batteries.

Author

Chen, Siying, Chen, Dongdong, Yang, Zhuohong, Liu, Ju, Lin, Jiamian, Xie, Zhuang, and Yang, Yu

Subjects

LITHIUM sulfur batteries, SOY proteins, CARBON paper, ADSORPTION, ENERGY storage

Abstract

The terrible shuttling of lithium polysulfides (LiPSs) is a major obstacle for commercializing lithium–sulfur (Li–S) batteries as high‐performance energy storage systems. In this study, a carbon‐based interlayer with effective suppression capability on the shuttle effect is developed by simply coating a well‐dispersed mixture of soybean protein isolate/MXene onto the acidified carbon paper (ACP). The resultant composite interlayer (SM@ACP) is able to synergistically diminish the shuttle effect through chemical adsorption and physical blocking. Meanwhile, this interlayer displays excellent conductivity and facilitates the diffusion of Li ions due to the composite coating to promote both electron/ion conduction as well as the porous structure of ACP. Benefiting from the unique properties of the composite interlayer, the as‐assembled Li–S batteries with SM@ACP interlayers show a great improvement in the cycling stability and rate performance, delivering a very low‐capacity decay rate of 0.071% per cycle at 0.5 C even after 800 cycles. This work provides a feasible route to realize rational design and commercial mass production of desirable interlayers for promoting the commercialization of Li–S batteries. [ABSTRACT FROM AUTHOR]

Published

2024

19. Biochemical characterization of an acid‐thermostable glucoamylase from Aspergillus japonicus with potential application in the paper bio‐deinking.

Author

Pasin, Thiago Machado, Betini, Jorge Henrique Almeida, de Lucas, Rosymar Coutinho, and Polizeli, Maria de Lourdes Teixeira de Moraes

Subjects

GLUCOAMYLASE, AMYLASES, ASPERGILLUS, RECYCLED paper, MANUFACTURING processes, CELLULASE

Abstract

Aspergillus species have been highlighted in enzyme production looking for industrial applications, notably, amylases are one of the most interesting enzymes. They are capable of hydrolyzing α‐glycosidic linkages of starch and widely used in industrial processes to produce ethanol, glucose, and fructose syrup as well as in the textiles, detergents, and paper industries applications. In this context, this work aimed at the biochemical characterization of the glucoamylase from Aspergillus japonicus and its application in the bio‐bleaching process of recycled paper. The optimum temperature and pH for the glucoamylase assay were standardized as 50°C and 5.5. After 1 h of incubation, glucoamylase retained 90% of its activity at 30–50°C. It also kept 70% of its activity in the pH range of 4.0–6.5 after an hour of incubation. The enzyme led to an increase of 30% in the relative whiteness of 10 dry grams of sulfite paper and magazine paper when applied along with commercial cellulase and 10 mM MnCl2. In addition, after the treatments, the glucoamylase recovered activity was 30%–32%, which indicates a prolonged availability of the enzyme and can considerably curtail the redundant downstream process of the recycled paper bio‐bleaching. Thus, the glucoamylase from A. japonicus has a significant role in bio‐bleaching recycled paper, reducing the necessity of hard chemicals, and improving the industrial process in an interesting economic and ecological mode. [ABSTRACT FROM AUTHOR]

Published

2024

20. A novel artificial neural network approach for residual life estimation of paper insulation in oil‐immersed power transformers.

Author

Nezami, Md. Manzar, Equbal, Md. Danish, Ansari, Md. Fahim, Alotaibi, Majed A., Malik, Hasmat, García Márquez, Fausto Pedro, and Hossaini, Mohammad Asef

Subjects

ARTIFICIAL neural networks, POWER transformers, TRANSFORMER insulation, ARTIFICIAL intelligence, MATHEMATICAL optimization

Abstract

Avoiding financial losses requires preventing catastrophic oil‐filled power transformer breakdowns. Continuous online transformer monitoring is needed. The authors use paper insulation to evaluate transformer health for continuous online transformer monitoring. The study suggests a new artificial intelligence method for estimating paper insulation residual life in oil‐immersed power transformers. The four artificial intelligence models use backpropagation‐based neural networks to predict paper insulation lifespan. Four primary transformer insulating paper failure indices—degree of polymerisation, 2‐furfuraldehyde, carbon monoxide, and carbon dioxide—form the basis of these models. Each model, including the backpropagation‐based neural networks, estimates paper insulation life using one failure index, along with moisture and temperature data. Optimisation techniques enhance hidden layer neurons and epoch count for improved performance. Results are validated against literature‐based life models, establishing a precise input–output correlation. This method accurately predicts the remaining useable life of power transformer paper insulation, enabling utilities to take proactive measures for safe and efficient transformer operation. [ABSTRACT FROM AUTHOR]

Published

2024