Showing total 73,228 results

1. A method to determine arsenic concentration in drinking water based on proton gradient and conductance measurements in filter paper media.

Author

Rozario, Joan and Hussam, Abul

Subjects

*FILTER paper, *ARSENIC in water, *PROTONS, *ARSENIC, *GROUNDWATER sampling, *DRINKING water

Abstract

This work describes a novel technique for the measurement of inorganic arsenic in water by generating arsine gas and detecting the conductivity of moving protons, H+ (aqueous or aq), produced by the reaction: Ag+ (aq) + AsH3 (gas, g) → AgAsH2 (solid, s) + H+ (aq). The detection is based on an electrochemical gradient of protons in a confined porous substrate (filter paper) and measures the change in the conductance due to the higher mobility of H+ compared to other ions. The conductance was measured with a pair of silver electrodes attached to opposite sides of the substrate with a bipolar pulse conductance technique. The method is established in theory and in practice. The theoretical equation for conductance change shows that a constant increase in conductance is directly proportional to the As(total) concentration. The method is validated with a standard reference material and applied to the measurement of the groundwater sample. [ABSTRACT FROM AUTHOR]

Published

2023

2. Molecular simulation of different types of polysilsesquioxane doped cellulose insulating paper: A guide for special cellulose insulating paper.

Author

Zeng, Zhenglin, Tan, Weimin, Deng, Yanhe, Cheng, Quan, Fu, Liuyue, and Tang, Chao

Subjects

*CELLULOSE fibers, *CELLULOSE, *GLASS transition temperature, *MODULUS of rigidity, *BULK modulus, *ELASTIC modulus, *DIELECTRIC properties

Abstract

To develop special insulating paper is of great significance to promote the service life of transformers. Using molecular simulation to guide the development of special insulating paper can greatly reduce the trial-and-error rate and waste of resources in traditional experiments. The effect of different types of polysilsesquioxane (POSS) on cellulose insulating paper was investigated by using molecular simulation. This paper investigated the thermal stability and mechanical properties and electrical characteristics of caged POSS, semi-caged POSS, and ladder-like POSS doped cellulose insulating paper. The results show that POSS with all types can enhance the performance of cellulose insulating paper, and ladder-like POSS possess the best modification effect. The glass transition temperature was increased by 58 K, and the bulk modulus, shear modulus, and elastic modulus of cellulose insulating paper doped with ladder-like POSS can improve up to 27.07%, 45.67%, and 41.28%, respectively. Meanwhile, the dielectric properties of ladder-like POSS modified insulating paper are also significantly improved. The findings of this paper propose a method for the preparation of ladder-like POSS modified insulating paper, which provides theoretical guidance for the experimental preparation of special insulating paper. [ABSTRACT FROM AUTHOR]

Published

2024

3. Fabrication of negative magnetostrictive Japanese traditional paper (washi) with cobalt ferrite particles.

Author

Kurita, Hiroki, Rova, Lovisa, Keino, Takumi, and Narita, Fumio

Subjects

*MAGNETOSTRICTION, *FERRITES, *COBALT, *JAPANESE language, *WOOD-pulp, *CELLULOSE fibers, *MAGNETIC particles

Abstract

The cellulose fibers that form washi are longer than those of regular paper made from wood pulp. Hence, the mechanical properties of washi can be higher than those of conventional paper. This study evaluated the magnetic, magnetostrictive, and tensile properties of negative magnetostrictive cobalt ferrite (CoFe2O4) particle dispersed handmade washi (washi−CoFe2O4). The CoFe2O4 additives magnetized the washi, which displayed negative magnetostriction with the fiber direction perpendicular to the magnetic field and in the parallel fiber direction. Concerning the mechanical properties, the washi−CoFe2O4 displayed an elongation of up to 77% after yielding. [ABSTRACT FROM AUTHOR]

Published

2023

4. Fabrication and characterization of graphene-based paper for heat spreader applications.

Author

Muhsan, Ali A. and Lafdi, Khalid

Subjects

THERMAL conductivity measurement, THERMAL conductivity, CHEMICAL processes, CHEMICAL vapor deposition, SCANNING electron microscopy, SLURRY

Abstract

In this work, in-plane thermal conductivity measurement was carried out on graphene-based papers. Graphene-based papers were fabricated using various processing techniques such as chemical vapor deposition (CVD), hot pressing of graphene slurry, and evaporation induced self-assembly. The prepared materials were characterized using scanning electron microscopy, Raman spectroscopy, and X-ray diffraction. In-plane thermal conductivity measurement was performed via a steady state thin film thermal conductivity apparatus. The in-plane thermal conductivity measurements show that the CVD based sample has the highest thermal conductivity. COMSOL Multiphysics was used to simulate the in-plane thermal conductivity of graphene-based papers. [ABSTRACT FROM AUTHOR]

Published

2019

5. X-ray microtomography and laser ablation in the analysis of ink distribution in coated paper.

Author

Myllys, M., Häkkänen, H., Korppi-Tommola, J., Backfolk, K., Sirviö, P., and Timonen, J.

Subjects

LASER ablation, X-ray computed microtomography, INK chemistry, PERMEABILITY of paper coatings, PROFILOMETER, PENETRATION mechanics

Abstract

A novel method was developed for studying the ink-paper interface and the structural variations of a deposited layer of ink. Combining high-resolution x-ray tomography with laser ablation, the depth profile of ink (toner), i.e., its varying thickness, could be determined in a paper substrate. X-ray tomography was used to produce the 3D structure of paper with about 1 μm spatial resolution. Laser ablation combined with optical imaging was used to produce the 3D structure of the printed layer of ink on top of that paper with about 70 nm depth resolution. Ablation depth was calibrated with an optical profilometer. It can be concluded that a toner layer on a light-weight-coated paper substrate was strongly perturbed by protruding fibers of the base paper. Such fibers together with the surface topography of the base paper seem to be the major factors that control the leveling of toner and its penetration into a thinly coated paper substrate. [ABSTRACT FROM AUTHOR]

Published

2015

6. Electrically and magnetically dual-driven Janus particles for handwriting-enabled electronic paper.

Author

Komazaki, Y., Hirama, H., and Torii, T.

Subjects

*JANUS particles, *ELECTRONIC paper, *MICROFLUIDIC analytical techniques, *SUPERPARAMAGNETIC materials, *NANOPARTICLES, *ELECTRIC potential, *MAGNETIC fields, *INTERNET forums

Abstract

In this work, we describe the synthesis of novel electrically and magnetically dual-driven Janus particles for a handwriting-enabled twisting ball display via the microfluidic technique. One hemisphere of the Janus particles contains a charge control agent, which allows the display color to be controlled by applying a voltage and superparamagnetic nanoparticles, allows handwriting by applying a magnetic field to the display. We fabricated a twisting ball display utilizing these Janus particles and tested the electric color control and handwriting using a magnet. As a result, the display was capable of permitting handwriting with a small magnet in addition to conventional color control using an applied voltage (80 V). Handwriting performance was improved by increasing the concentration of superparamagnetic nanoparticles and was determined to be possible even when 80V was applied across the electrodes for 4 wt.% superparamagnetic nanoparticles in one hemisphere. This improvement was impossible when the concentration was reduced to 2 wt.% superparamagnetic nanoparticles. The technology presented in our work can be applied to low-cost, lightweight, highly visible, and energy-saving electronic message boards and large whiteboards because the large-size display can be fabricated easily due to its simple structure. [ABSTRACT FROM AUTHOR]

Published

2015

7. Reactive molecular dynamics research on influences of water on aging characteristics of PMIA insulation paper.

Author

Wang, Lihan, Yin, Fei, Shen, Yin, and Tang, Chao

Subjects

*MOLECULAR dynamics, *INSULATING oils, *CHEMICAL stability, *HYDROXYL group, *ACTIVATION energy, *MOISTURE content of food

Abstract

The diffusion of moisture in the meta-aramid fiber (PMIA) oil-paper insulation system and the thermal decomposition of PMIA insulation paper in different moisture contents were studied via molecular dynamics simulations. The results showed that the PMIA insulation paper had a stronger ability to absorb water molecules than the insulating oil; therefore, water molecules in the insulating oil diffuse to the insulation paper, which further affects the thermal decomposition of the PMIA insulation paper. The activation energy of the water-bearing composite model was 129.96 kJ/mol, which was 5.5% lower than that of the pure PMIA (137.61 kJ/mol). It indicated that moisture could promote PMIA decomposition. The micromechanism of the enhanced thermal decomposition of PMIA with moisture contents could be described as follows: The O–H bond of the water can easily break to generate H atoms and hydroxyl radicals (•OH). The strong activity of H atoms allows it to easily combine with the ammonia base at the end of PMIA to generate NH3. Additionally, the free •OH radical can easily combine with the amido and carbonyl bonds at two ends of PMIA, undergo an oxidation reaction, and generate an oxhydryl. Therefore, it can reduce the chemical stability of the PMIA chain and further drive thermal decomposition. Statistical data on fragments generated by the thermal decomposition of the water-bearing PMIA composite system show that the main products include H2, C/H/O-containing molecules, hydrocarbon molecules, N-bearing molecules, and free radicals. [ABSTRACT FROM AUTHOR]

Published

2020

8. X-ray texture analysis of paper coating pigments and the correlation with chemical composition analysis.

Author

Roine, J., Tenho, M., Murtomaa, M., Lehto, V.-P., and Kansanaho, R.

Subjects

*SURFACES (Technology), *PRINTING properties of paper, *PRINTING equipment, *X-ray spectroscopy, *SURFACE coatings

Abstract

The present research experiments the applicability of x-ray texture analysis in investigating the properties of paper coatings. The preferred orientations of kaolin, talc, ground calcium carbonate, and precipitated calcium carbonate particles used in four different paper coatings were determined qualitatively based on the measured crystal orientation data. The extent of the orientation, namely, the degree of the texture of each pigment, was characterized quantitatively using a single parameter. As a result, the effect of paper calendering is clearly seen as an increase on the degree of texture of the coating pigments. The effect of calendering on the preferred orientation of kaolin was also evident in an independent energy dispersive spectrometer analysis on micrometer scale and an electron spectroscopy for chemical analysis on nanometer scale. Thus, the present work proves x-ray texture analysis to be a potential research tool for characterizing the properties of paper coating layers. [ABSTRACT FROM AUTHOR]

Published

2007

9. Improvements of mechanical properties of multilayer open-hole graphene papers.

Author

Xia, Yuxuan, Li, Yeyuan, Zhu, Chunhua, Wei, Ning, and Zhao, Junhua

Subjects

*SHEAR strength, *CARBON-carbon bonds, *TENSILE strength, *STRESS concentration, *COVALENT bonds, *LAMINATED glass

Abstract

Holes and defects can greatly reduce the mechanical properties of multilayer graphene sheets under different loading conditions due to the stress concentration near the hole edge in each in-plane sheet and the lack of interlayer carbon–carbon bonds between the layers. Here, we report a novel design of multilayer open-hole graphene papers (MLGPs) formed through interlayer covalent bonding at the hole edges of multilayer open-hole graphene sheets (MLGSs) under high temperature using molecular dynamics (MD) simulations. Our MD results show that the hybrid sp2–sp3 interlayer bonds of MLGPs can significantly improve their both tensile strength and interlayer shear strength. The tensile strength and interlayer shear strength of MLGPs increase by around 20% and 3 times by comparison with those of MLGSs with the same number of layers, respectively, which mainly depends on the uniformity of their interlayer bond distribution. This study can provide an effective way to improve the mechanical performances of multilayer graphene sheets with flaws and also offer corresponding guidance for the design of MLGS-based nanocomposites. [ABSTRACT FROM AUTHOR]

Published

2019

10. Thin film versus paper-like reduced graphene oxide: Comparative study of structural, electrical, and thermoelectrical properties.

Author

Okhay, Olena, Gonçalves, Gil, Tkach, Alexander, Dias, Catarina, Ventura, Joao, da Silva, Manuel Fernando Ribeiro, Valente Gonçalves, Luís Miguel, and Titus, Elby

Subjects

GRAPHENE oxide, THIN films, CHEMICAL reduction, HYDRAZINE, SEMICONDUCTORS

Abstract

We report fabrication of reduced graphene oxide (rGO) films using chemical reduction by hydrazine hydrate and rGO paper-like samples using low temperature treatment reduction. Structural analysis confirms the formation of the rGO structure for both samples. Current-voltage (I-V) measurements of the rGO film reveal semiconductor behavior with the maximum current value of ~3×10-4A. The current for the rGO paper sample is found to be, at least, one order of magnitude higher. Moreover, bipolar resistance switching, corresponding to memristive behavior of type II, is observed in the I-V data of the rGO paper. Although precise values of the rGO film conductivity and the Seebeck coefficient could not be measured, rGO paper shows an electrical conductivity of 6.7×102S/m and Seebeck coefficient of -6μV/°C. Thus, we demonstrate a simplified way for the fabrication of rGO paper that possesses better and easier measurable macroscopic electrical properties than that of rGO thin film. [ABSTRACT FROM AUTHOR]

Published

2016

11. Temperature-dependence of electrical and dielectric properties of papers for electrophotography.

Author

Maldzius, R., Sirviö, P., Sidaravicius, J., Lozovski, T., Backfolk, K., and Rosenholm, J. B.

Subjects

ELECTROPHOTOGRAPHY, PRINTING, PHOTORECEPTORS, ELECTRIC fields, ELECTRIC conductivity, TEMPERATURE

Abstract

The temperature-dependence of the electrical and dielectric properties of paper substrates was studied using experimental papers with different NaCl contents, different thicknesses, and different grammages. Physical processes related to the charging potential, charge decay rate, conductivity, dielectric constant, and dielectric loss of papers are dependent on thermal energy, and this dependence on temperature can be described by exponential expressions. The ion content of paper not only determines the level of these properties at a given temperature, as expected but also influences their temperature-dependence. Frequency analysis of the dielectric loss confirms that new structures are formed in paper by the addition of NaCl. The results may be applicable to the design of materials and equipment, e.g., for the electrophotographic printing processes. [ABSTRACT FROM AUTHOR]

Published

2010

12. Thermophysical characterization of artificially aged papers by means of the photothermal...

Author

Bertolotti, M. and Ligia, S.

Subjects

*PAPER, *THERMOPHYSICAL properties

Abstract

Presents information on a study which determined the thermophysical properties of artificially aged paper samples by means of photothermal deflection technique. Theory; Experimental results and discussion; Conclusions.

Published

1999

13. Mechanism study of the conductivity characteristics of cellulose electrical insulation influenced by moisture.

Author

Zhao, Haoxiang, Mu, Haibao, Zhang, Daning, Baumeier, Björn, Yao, Huanmin, Guo, Guangzhi, and Zhang, Guanjun

Subjects

ELECTRIC insulators & insulation, FRONTIER orbitals, MOLECULAR dynamics, CELLULOSE, ELECTRIC distortion, MOISTURE, CELLULOSE synthase, SILICONE rubber

Abstract

Cellulose insulating paper is widely used in the power industry for its good electrical insulating properties. Moisture sharply increases its conductivity, which directly leads to the weakening of insulation performance and greatly increases the risk of subsequent electric field distortion and insulation breakdown. This paper focuses on the microscopic mechanism of moisture changing the characteristics of charge transport in cellulose insulation and attempts to reveal the related conductivity mechanism. To achieve this purpose, microscopic and macroscopic perspectives are integrated and several simulation and experimental methods are utilized comprehensively. The molecular dynamics simulation results showed that most water molecules in damped cellulose were individually and uniformly adsorbed on the hydroxyl groups by hydrogen bond, and the quantum chemistry computation results showed that the lowest unoccupied molecular orbital more appeared on the water molecule and the corresponding density of state increased. Then, experimentally, it was confirmed that the trap energy level decreased by the thermally stimulated current method. On this basis, the promotion effect of moisture on charge transport is predicted and verified by polarization and depolarization current methods. As the moisture content increased, more charge carriers escaped from the trap by hopping and participated in long-range continuous charge motion. Therefore, after dampness, the current of cellulose insulating paper increased exponentially with the increase in electric field strength, which was consistent with the hopping conductivity mechanism. [ABSTRACT FROM AUTHOR]

Published

2022

14. Radiation effects in single-walled carbon nanotube papers.

Author

Cress, Cory D., Schauerman, Christopher M., Landi, Brian J., Messenger, Scott R., Raffaelle, Ryne P., and Walters, Robert J.

Subjects

CARBON nanotubes, NANOTUBES, IONIZING radiation, RADIATION, NANOSTRUCTURES

Abstract

The effects of ionizing radiation on the temperature-dependent conductivity of single-walled carbon nanotube (SWCNT) papers have been investigated in situ in a high vacuum environment. Irradiation of the SWCNT papers with 4.2 MeV alpha particles results in a steady decrease in the SWCNT paper conductivity, resulting in a 25% reduction in room temperature conductivity after a fluence of 3×1012 alpha particles/cm2. The radiation-induced temperature-dependent conductivity modification indicates that radiation damage causes an increase in the effective activation barrier for tunneling-like conductivity and a concomitant increase in wavefunction localization of charge carriers within individual SWCNTs. The spatial defect generation within the SWCNT paper was modeled and confirms that a uniform displacement damage dose was imparted to the paper. This allows the damage coefficient (i.e., differential change in conductivity with fluence) for alpha particles, carbon ions, and protons to be compared with the corresponding nonionizing energy loss (NIEL) of the incident particle. The resulting nonlinear relationship with NIEL between these parameters is distinct from the more typical linear response observed in many bulk semiconductors and superconductors and indicates that localized radiation damage in the SWCNT papers has a greater impact than distributed damage. Although SWCNT papers behave largely as a bulk material with properties that are a convolution of the underlying SWCNT distribution, the radiation response appears to be largely dominated by degradation in the preferred one-dimensional conduction within these two-dimensionally confined nanostructures. [ABSTRACT FROM AUTHOR]

Published

2010

15. Electronic structure spectroscopy of organic semiconductors by energy resolved-electrochemical impedance spectroscopy (ER-EIS).

Author

Schauer, Franz

Subjects

ORGANIC semiconductors, ELECTRONIC structure, IMPEDANCE spectroscopy, SEMICONDUCTOR materials, MATERIALS science, FULLERENES, ELECTRONIC paper, TIME-resolved spectroscopy

Abstract

Organic electronic applications are envisioned to address broad markets, which includes flexible displays, electronic papers, sensors, disposable and wearable electronics, and medical and biophysical applications, leading to a tremendous amount of interest from both academia and industry in the study of devices. These fields of science and technology constitute interdisciplinary fields that cover physics, chemistry, biology, and materials science, leading, as a wanted output, to the elucidation of physical and chemical properties, as well as structures, fabrication, and performance evaluation of devices and the creation of new knowledge underlying the operation of organic devices using new synthesized organic materials—organic semiconductors. We testify the situation when the available organic electronic applications sometimes lack a theoretical background. The cause may be the complicated properties of disordered, weak bounded, molecular materials with properties different from their inorganic counterparts. One of the basic information-rich resources is the electronic structure of organic semiconductors, elucidated by the methods, hardly possible to be transferred from the branch of inorganic semiconductors. Electrochemical spectroscopic methods, in general, and electrochemical impedance spectroscopy, in particular, tend and seem to fill this gap. In this Perspective article, the energy resolved-electrochemical impedance spectroscopic method for electronic structure studies of surface and bulk of organic semiconductors is presented, and its theoretical and implementation background is highlighted. To show the method's properties and strength, both as to the wide energy and excessive dynamic range, the basic measurements on polymeric materials and D–A blends are introduced, and to highlight its broad applicability, the results on polysilanes degradability, gap engineering of non-fullerene D–A blends, and electron structure spectroscopy of an inorganic nanocrystalline film are highlighted. In the outlook and perspective, the electrolyte/polymer interface will be studied in general and specifically devoted to the morphological, transport, and recombination properties of organic semiconductors and biophysical materials. [ABSTRACT FROM AUTHOR]

Published

2020

16. Paper-based ultracapacitors with carbon nanotubes-graphene composites.

Author

Jian Li, Xiaoqian Cheng, Jianwei Sun, Brand, Cameron, Shashurin, Alexey, Reeves, Mark, and Keidar, Michael

Subjects

*SUPERCAPACITORS, *CARBON nanotubes, *GRAPHENE, *SCANNING electron microscopes, *TRANSMISSION electron microscopes, *RAMAN spectroscopy, *THIN films

Abstract

In this paper, a paper-based ultracapacitors were fabricated by the rod-rolling method with the ink of carbon nanomaterials, which were synthesized by arc discharge under various magnetic conditions. Composites of carbon nanostructures, including high-purity single-walled carbon nanotubes (SWCNTs) and graphene flakes were synthesized simultaneously in a magnetically enhanced arc. These two nanostructures have promising electrical properties and synergistic effects in the application of ultracapacitors. Scanning electron microscope, transmission electron microscope, and Raman spectroscopy were employed to characterize the properties of carbon nanostructures and their thin films. The sheet resistance of the SWCNT and composite thin films was also evaluated by four-point probe from room temperature to the cryogenic temperature as low as 90 K. In addition, measurements of cyclic voltammetery and galvanostatic charging/discharging showed the ultracapacitor based on composites possessed a superior specific capacitance of up to 100 F/g, which is around three times higher than the ultracapacitor entirely fabricated with SWCNT. [ABSTRACT FROM AUTHOR]

Published

2014

17. Biocellulose-based flexible magnetic paper.

Author

Barud, H. S., Tercjak, A., Gutierrez, J., Viali, W. R., Nunes, E. S., Ribeiro, S. J. L., Jafellici, M., Nalin, M., and Marques, R. F. C.

Subjects

*CELLULOSE, *ELECTROMAGNETIC waves, *X-rays, *IRON oxides, *SPECTRUM analysis, *ADSORPTION, *MAGNETIC materials

Abstract

Biocellulose or bacterial cellulose (BC) is a biocompatible (nano) material produced with a threedimensional network structure composed of microfibrils having nanometric diameters obtained by the Gluconacetobacter xylinus bacteria. BC membranes present relatively high porosity, allowing the incorporation or synthesis in situ of inorganic nanoparticles for multifunctional applications and have been used as flexible membranes for incorporation of magnetic nanocomposite. In this work, highly stable superparamagnetic iron oxide nanoparticles (SPION), functionalized with polyethylene glycol (PEG), with an average diameter of 5 nm and a saturation magnetization of 41 emu/g at 300K were prepared. PEG-Fe2O3 hybrid was dispersed by mixing a pristine BC membrane in a stable aqueous dispersion of PEG-SPION. The PEG chains at PEG-SPION's surface provide a good permeability and strong affinity between the BC chains and SPION through hydrogen-bonding interactions. PEG-SPION also allow the incorporation of higher content of nanoparticles without compromising the mechanical properties of the nanocomposite. Structural and magnetic properties of the composite have been characterized by XRD, SEM, energy-dispersive X-ray spectroscopy (EDX), magnetization, Raman spectroscopy, and magnetic force microscopy. [ABSTRACT FROM AUTHOR]

Published

2015

18. Advanced mechanical properties of graphene paper.

Author

Bei Wang, Xiaoping Shen, Guoxiu Wang, and Ranjbartoreh, Ali R.

Subjects

*GRAPHENE, *CARBON steel, *MICROMECHANICS, *STRAINS & stresses (Mechanics), *STRENGTH of materials, *CARBON

Abstract

Graphene paper (GP) has been prepared by flow-directed assembly of graphene nanosheets. The mechanical properties of as-prepared GPs were investigated by tensile, indentation, and bending tests. Heat treated GPs demonstrate superior hardness, ten times that of synthetic graphite, and two times that of carbon steel; besides, their yielding strength is significantly higher than that of carbon steel. GPs show extremely high modulus of elasticity during bending test; in the range of a few terapascal. The high strength and stiffness of GP is ascribed to the interlocking-tile microstructure of individual graphene nanosheets in the paper. These outstanding mechanical properties of GPs could lead to a wide range of engineering applications. [ABSTRACT FROM AUTHOR]

Published

2011

19. Electrical conductivity of carbon-nanotube/cellulose composite paper.

Author

Tanaka, Tomo, Sano, Eiichi, Imai, Masanori, and Akiyama, Kousuke

Subjects

*CARBON nanotubes, *NANOTUBES, *ELECTRIC conductivity research, *CELLULOSE, *COMPOSITE materials, *QUANTUM tunneling, *MATHEMATICAL models

Abstract

We fabricated multiwalled carbon-nanotube/cellulose composite papers and measured their temperature dependences of electrical conductivity. The dependences were described with the Sheng’s fluctuation-induced tunneling (FIT) model. A possible mechanism of the electrical conduction in the composite paper was discussed in the context of the FIT model. [ABSTRACT FROM AUTHOR]

Published

2010

20. Dynamic Measurements of Physical Properties of Pulp and Paper by Audiofrequency Sound.

Author

Horio, M. and Onogi, S.

Published

1951