Composite Materials Research https://ojs.piscomed.com/index.php/CMR <table> <tbody> <tr style="vertical-align: top;"> <td style="text-align: justify;"> <p><em>Composite Materials Research</em> mainly publishes scientific research papers that are innovative, high-level, and significant in the international basic research and applied research of composite materials. Published scope: Preparation, performance, and application of composite materials such as fibers, particles, or whiskers to reinforce polymer-based, metal-based, and ceramic-based structures, functions, biology, environmental protection, construction, etc., to promote academic exchanges in the field of composite materials at home and abroad. And the promotion and application of advanced composite materials.</p> </td> <td> <div id="cover_section"><a title="Composite Materials Research " href="/index.php/cmr" target="_self"> <img id="cover-img" src="/public/site/images/admin/H复合材料的ç&nbsp;”究x.jpg" alt="Composite Materials Research " align="right"> </a></div> <div id="issn_section"><br><span class="issn_num">ISSN(P): 2251-2667</span><br><br><img src="/public/site/Open_Access.png" alt="" height="20px"></div> </td> </tr> </tbody> </table> PiscoMed Publishing Pte Ltd en-US Composite Materials Research 2251-2667 <p>Copyright on any open access article in a journal published by PiscoMed Publishing is retained by the author(s).</p> <p>Authors grant PiscoMed Publishing a license to publish, copy, distribute, and convey the article.</p> <p>&nbsp;</p> <p>The current adopted license, the <a href="https://creativecommons.org/licenses/by/4.0/">Creative Commons Attribution 4.0 International License (CC BY 4.0)</a>, formalizes these and other terms and conditions of publishing articles. The license (CC BY 4.0) means:</p> <p>&nbsp;</p> <p>Share: Everyone can copy and redistribute the open-access content in the journal.</p> <p>&nbsp;</p> <p>Adapt: Materials in the articles can be remixed, reused, and reanalyzed for any purpose.</p> <p>&nbsp;</p> <p>Attribution: You must cite the source with the correct license if some changes to the materials are made, but that does not mean that the licensor endorses you or your use.</p> <p>&nbsp;</p> <p>Authors should ensure that the content of the article is not involved in a copyright dispute before submitting it. For previously published articles, authors should obtain permission from the copyright holder if the material is under a more restrictive license. &nbsp;</p> Microstructure and performances of ITO film prepared by ion beam sputtering https://ojs.piscomed.com/index.php/CMR/article/view/525 Ion beam sputtering deposition was firstly introduced to prepare indium tin oxide (ITO) film in this study. The ITO film was annealed at different temperature in a flow of nitrogen or air, respectively. The effect of annealing process on the microstructure, optical and electrical performances of the ITO film was studied. The results showed that the crystallinity and optical properties of the ITO film were improved with the increase of annealing temperature. The transmittance of the ITO film in visible regions increased up to 96% after it was annealed at 500℃ in nitrogen or in air. It was found that the resistivity of ITO film depended on both the annealing temperature and the annealing atmosphere, which showed a close relationship to the atomic percentage’s sum of oxygen vacancy and Sn<sup>4+</sup>, which was quantified by XPS result. Ping C Copyright (c) 2018 Ping C https://creativecommons.org/licenses/by-nc/4.0 10.1828/cmr.v6i3.525 An Analyses of Schottky Structure with Lead Monoxide Layer https://ojs.piscomed.com/index.php/CMR/article/view/528 Al/ lead monoxide (PbO) /<em>p</em>-Si structures were consructed to research the electrical properties of PbO interlayer and the conductance-voltage (<em>G-V</em>) and capacitance-voltage (<em>C-V</em>) characteristics of these<strong> </strong>structures at room temperature have been studied at 600kHz, 800kHz and 1MHz. The study of barrier height , series resistance (<em>R<sub>s</sub></em>) and interface states density (<em>D<sub>it</sub></em>) using <em>G-V</em> and<em> C-V</em> graphs in these structures has been reported. <em>G </em>and<em> C</em> measurements were obtained to be dependent on frequency and bias voltage. Sema BO Ugur G Copyright (c) 2018 Sema BO, Ugur G https://creativecommons.org/licenses/by-nc/4.0 10.1828/cmr.v6i3.528 Enhancement of photoelectrocatalysis efficiency of carbon nanotubes doped with TiO2 nanostructures applied on pesticide degradation https://ojs.piscomed.com/index.php/CMR/article/view/694 <br /><table class="data" width="100%"><tbody><tr valign="top"><td class="value">In this study, a composite electrode based on multi-walled carbon nanotubes (MWCNT)<br />and titanium dioxide (TiO2) prepared by the sol-gel method was synthesized and<br />evaluated for the photoelectrochemical oxidation of carbaryl. The MWCNT/TiO2<br />composite was deposited into a titanium plate (Ti) and characterised by scanning<br />electron microscopy (SEM), X-ray diffraction (XRD), and electrochemically. The<br />photoelectrochemical oxidation of carbaryl was studied to evaluate potential<br />applications of the Ti/MWCNT/TiO2 composite electrode in environmental science.<br />The carbaryl removal efficiency yielded 71.0% at an applied potential of +1.5 V for 1 h<br />using the Ti/MWCNT/TiO2 composite electrode in presence of light. In comparison, the<br />removal efficiency reached 57.6% using the same parameters, however in absence of<br />light. The results demonstrated the interesting photoelectrochemical properties of the<br />developed material when applied on the pesticide degradation.</td></tr></tbody></table> Ivana C Copyright (c) 2019 Ivana C https://creativecommons.org/licenses/by-nc/4.0 10.1828/cmr.v6i3.694 Effect of Nano-particles on Energy Release Rate in Mode I Fracture Using Corrected Beam Theory https://ojs.piscomed.com/index.php/CMR/article/view/700 <p>The main objective of this paper is evaluation of nano-particles effect on energy release rate in nano-composites mode I fracture. Nano-composite samples with woven glass fibers and alumina nanoparticle have been fabricated using VARTM process as co-cured and underwent Double Cantilever Beam tests according to ASTM D5528 standard. To calculate the energy release rate in Mode I fracture, corrected beam theory data reduction scheme has been utilized for different percentage of nano particles.</p> P Ghabezi Copyright (c) 2019 P Ghabezi https://creativecommons.org/licenses/by-nc/4.0 10.1828/cmr.v6i3.700