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Articles de revues sur le sujet "Electrical Properties - Nanocomposites"
Cho, Kie Yong, A. Ra Cho, Yun Jae Lee, Chong Min Koo, Soon Man Hong, Seung Sangh Wang, Ho Gyu Yoon et Kyung Youl Baek. « Enhanced Electrical Properties of PVDF-TrFE Nanocomposite for Actuator Application ». Key Engineering Materials 605 (avril 2014) : 335–39. http://dx.doi.org/10.4028/www.scientific.net/kem.605.335.
Texte intégralAbou El Fadl, Faten Ismail, Maysa A. Mohamed, Magida Mamdouh Mahmoud et Sayeda M. Ibrahim. « Studying the electrical conductivity and mechanical properties of irradiated natural rubber latex/magnetite nanocomposite ». Radiochimica Acta 110, no 2 (22 novembre 2021) : 133–44. http://dx.doi.org/10.1515/ract-2021-1080.
Texte intégralPolsterova, Helena. « Dielectric Properties of Nanocomposites Based on Epoxy Resin ». ECS Transactions 105, no 1 (30 novembre 2021) : 461–66. http://dx.doi.org/10.1149/10501.0461ecst.
Texte intégralSabo, Y. T., D. E. A. Boryo, I. Y. Chindo et A. M. Auwal. « Nanocomposites transformed from polystyrene waste/antimony, barium and nickel oxides nanoparticles with improved thermal and electrical properties ». Nigerian Journal of Chemical Research 26, no 2 (5 février 2022) : 117–27. http://dx.doi.org/10.4314/njcr.v26i2.7.
Texte intégralV. C. Morais, Manuel, Marco Marcellan, Nadine Sohn, Christof Hübner et Frank Henning. « Process Chain Optimization for SWCNT/Epoxy Nanocomposite Parts with Improved Electrical Properties ». Journal of Composites Science 4, no 3 (14 août 2020) : 114. http://dx.doi.org/10.3390/jcs4030114.
Texte intégralOuis, Nora, Assia Belarbi, Salima Mesli et Nassira Benharrats. « Improvement of Electrical Conductivity and Thermal Stability of Polyaniline-Maghnite Nanocomposites ». Chemistry & ; Chemical Technology 17, no 1 (27 mars 2023) : 118–25. http://dx.doi.org/10.23939/chcht17.01.118.
Texte intégralAbdulla, Estabraq T. « Synthesis and electrical properties of conductive polyaniline/ SWCNT nanocomposites ». Iraqi Journal of Physics (IJP) 15, no 34 (8 janvier 2019) : 106–13. http://dx.doi.org/10.30723/ijp.v15i34.126.
Texte intégralAlam, Rabeya Binta, Md Hasive Ahmad, S. M. Nazmus Sakib Pias, Eashika Mahmud et Muhammad Rakibul Islam. « Improved optical, electrical, and thermal properties of bio-inspired gelatin/SWCNT composite ». AIP Advances 12, no 4 (1 avril 2022) : 045317. http://dx.doi.org/10.1063/5.0089118.
Texte intégralKasım, Hasan, et Murat Yazıcı. « Electrical Properties of Graphene / Natural Rubber Nanocomposites Coated Nylon 6.6 Fabric under Cyclic Loading ». Periodica Polytechnica Chemical Engineering 63, no 1 (18 juin 2018) : 160–69. http://dx.doi.org/10.3311/ppch.12122.
Texte intégralWang, Shaojing, Peng Xu, Xiangyi Xu, Da Kang, Jie Chen, Zhe Li et Xingyi Huang. « Tailoring the Electrical Energy Storage Capability of Dielectric Polymer Nanocomposites via Engineering of the Host–Guest Interface by Phosphonic Acids ». Molecules 27, no 21 (25 octobre 2022) : 7225. http://dx.doi.org/10.3390/molecules27217225.
Texte intégralThèses sur le sujet "Electrical Properties - Nanocomposites"
Schiţco, Cristina. « Thermal and electrical properties of PVDF/Cu nanocomposites ». Master's thesis, Universidade de Aveiro, 2011. http://hdl.handle.net/10773/7531.
Texte intégralPoly(vinylidene fluoride) (PVDF) nanocomposites films with spherical and 1 Dimension (1D) copper nanoparticles as fillers were prepared; the morphology, dielectric properties, and thermal conductivity were studied. The role of dimensionality of the fillers was assessed and discussed. Spherical or nanowires copper nanoparticles were incorporated into the polymeric matrix up to 0.30 wt % via solution casting from dimethylformamide DMF, which acts as a good solvent for PVDF. The obtained films were shown to be porous when investigated by Scanning Electron Microscopy (SEM). The porosity of the films was eliminated by a hot pressing step. Fourier transform infrared (FTIR) and Raman spectroscopy investigations indicated the formation of γ-phase in the pure polymer as for polymer matrix for both spherical and nanowires copper nanoparticles loading. The presence of Cu in the polymer matrix was only detected for high nanoparticles contents by UV-Vis spectroscopy and X Ray Diffraction (XRD). The crystallization of the polymer was not significantly affected in the case of Cu spheres nanoparticles loading. For Cu nanowires, an increase of the degree of crystallization (ΔXc) with Cu loading was observed (pressed samples). The dielectric and thermal conductivity measurements showed a significant improvement of the dielectric constant and thermal conductivity compared to pure PVDF. When the loading of Cu nanoparticles equals to 0.30%, the dielectric constant and thermal conductivity of the nanocomposites incorporating spherical particles is ~20 at 103 Hz and 0.39 W/mK, respectively. However and particularly interesting this effect is more noticeable for Cu nanowires nanocomposites for which the dielectric constant and the thermal conductivity reached values of 24.4 at 103 Hz and 0.45 W/mK, respectively. These results, until now not reported in the literature, have a unique relevance for future applications of PVDF as electric stress control, electromagnetic shielding and high storage capability of the electric energy devices.
Neste trabalho foram preparados filmes nanocompósitos de poli (fluoreto de vinilideno) (PVDF) com nanoesferas e nanofios de cobre. Foram estudadas a morfologia, propriedades dieléctricas e condutividade térmica. O papel da dimensionalidade do enchimento (fillers) foi avaliado e discutido. As nanopartículas esféricas ou nanofios de cobre foram incorporados na matriz polimérica até 0,30% em peso, através da conformação de soluções de dimetilformamida (DMF). Os filmes obtidos mostraram-se porosos quando analisados por microscopia electrónica de varrimento (SEM). A porosidade dos filmes foi eliminada por uma etapa de prensagem a quente. Espectroscopias de Infravermelho (FTIR) e Raman indicaram a formação da fase γ na matriz polimérica para ambos os tipos de fillers, nano esferas e nanofios de cobre. A presença de Cu na matriz do polímero só foi detectada por espectroscopia UV-VIS e Difracção de raios X (XRD) para altos teores de nanopartículas. A cristalização do polímero não foi significativamente afectada no caso da carga com nanoesferas de Cu. Contudo, foi observada um aumento do grau de cristalização (ΔXc) com a carga para os nanofios de Cu (amostras prensadas). Medições da resposta eléctrica e térmica revelaram uma melhoria significativa da constante dieléctrica e da condutividade térmica em comparação com PVDF puro. Quando a carga de nanopartículas de Cu equivale a 0,30%, a constante dieléctrica e a condutividade térmica dos nanocompósitos com partículas esféricas é de aproximadamente 20 a 103 Hz e 0,39 W/mK, respectivamente. No entanto, e particularmente interessante, este efeito é mais evidente para os nanocompósitos com nanofios de Cu, para os quais a constante dieléctrica e a condutividade térmica atingem valores de 24,4 a 103 Hz e 0,45 W/mK, respectivamente. Estes resultados, até agora não reportados na literatura, são de relevância para futuras aplicações de PVDF em dispositivos controladores de stress eléctrico, de blindagem electromagnética e de alta capacidade de armazenamento de energia eléctrica.
Lau, K. Y. « Structure and electrical properties of silica-based polyethylene nanocomposites ». Thesis, University of Southampton, 2013. https://eprints.soton.ac.uk/358889/.
Texte intégralZhang, Guoqiang. « The Synthesis and Electrical Properties of Functional Polymer Nanocomposites ». Case Western Reserve University School of Graduate Studies / OhioLINK, 2017. http://rave.ohiolink.edu/etdc/view?acc_num=case149010222646324.
Texte intégralLim, Chee-Sern. « Mechanical and electrical properties of aligned carbon nanofiber/epoxy nanocomposites ». Thesis, Wichita State University, 2010. http://hdl.handle.net/10057/3315.
Texte intégralThesis (M.S.)--Wichita State University, College of Engineering, Dept. of Mechanical Engineering.
Maruzhenko, Oleksii. « Structure, thermal and electrical properties of nanocomposites with hybrid fillers ». Thesis, Lyon, 2019. http://www.theses.fr/2019LYSEI131.
Texte intégralThe thesis determines the principles of the conductive phase structure formation in polymer composites containing conductive fillers, which will be different types of carbon fillers. The processes of segregated structure formation in which the particles of the filler are localized on the surfaces of polymer grains is studied. It is shown that the value of the percolation threshold φc for the segregated system is one order lower than in the composite with a random distribution of the filler 2.95 vol.% and 24.8 vol.%, respectively. The hybrid filler shows percolation threshold, much lower than the value calculated using the mixing rule. Experimental results of thermal conductivity for systems filled with anthracite, graphene and hybrid filler Gr/A do not reveal percolation behaviour and can be well described by the Lichtenecker model. It is shown that λf for segregated systems is 4.4 times higher than for a composite with a random distribution of filler particles. It is shown that in segregated systems the shielding parameters are significantly increased due to the absorption caused by the internal reflection on the conductive walls of the filler framework. Carbon fillers create the most effective basis that ensures a high absorption rate of EMI at low concentrations. It was found that the greatest shielding effect in the interaction of a composite with electromagnetic radiation was observed for the hybrid filler GNP/CNT (graphite nanoplatelets/carbon nanotubes). The synergistic effect is explained not by their higher electrical conductivity, but by the better interaction of the EMI with the developed hybrid framework of the filler, which causes increased absorption of the EMI. Systems with a segregated structure based on elastomer (ground rubber) with a polymer-adhesive and hybrid electroconductive nano-fillers exhibit a significant piezoresistive effect. The cyclic studies of electric response, depending on the applied external load, showed a linear relationship between composite deformation and current changes through the sample and demonstrate stable long-term stability. The study of the piezoresistive effect in a wide temperature range (-40 ÷ +50°C) showed the stability of the main characteristics and the possibility of exploiting the composite in a wide temperature range
Noël, Amélie. « Electrical properties of film-forming polymer/graphene nanocomposites : Elaboration through latex route and characterization ». Thesis, Saint-Etienne, EMSE, 2014. http://www.theses.fr/2014EMSE0767/document.
Texte intégralPrinted electronics, particularly on flexible and textile substrates, raised a strong interest during the past decades. This project presents a procedure that provides a complete and consistent candidate for conductive inks based on a graphene/polymer nanocomposite material. It consists in the synthesis of conductive inks nanocomposites comprising polymer particles (latex) with low glass transition temperature, Tg, and graphene platelets, for the conductive properties. The conductive particles, named Nanosize Multilayered Graphene (NMG), are prepared by wet grinding delamination of micro-graphite suspensions stabilized by various surfactants and/or polymeric stabilizers. This solvent-free procedure allows the formation of NMG suspensions with low thickness (1-10 sheets). Polymer particles are synthetized by surfactant-free emulsion polymerization with acrylates monomers.Physical blending of latex particles and NMG platelets are performed to obtain conductive nanocomposites inks. Adding NMG induce a low percolation threshold and a sharp increase of the electrical and mechanical properties of the nanocomposites. Moreover, the polymer particles diameters have an impact on these properties.To increase the formation of a well-defined cellular microstructure, the nanocomposites are also synthetized by in situ polymerization in presence of NMG platelets, using emulsion, miniemulsion or dispersion polymerization. The excellent electrical properties of these nanocomposites associated to their flexibility make these materials suitable candidates for the production of conductive inks for textile printing applications
MINNAI, CHLOE'. « OPTICAL AND ELECTRICAL PROPERTIES OF METAL POLYMER NANOCOMPOSITES FABRICATED WITH SUPERSONIC CLUSTER BEAM IMPLANTATION ». Doctoral thesis, Università degli Studi di Milano, 2018. http://hdl.handle.net/2434/637068.
Texte intégralDeGeorge, Vincent G. « Chemical Partitioning and Resultant Effects on Structure and Electrical Properties in Co-Containing Magnetic Amorphous Nanocomposites for Electric Motors ». Research Showcase @ CMU, 2017. http://repository.cmu.edu/dissertations/885.
Texte intégralJung, de Andrade Mônica. « Study of electrical properties of 2- and 3-dimensional carbon nanotubes networks ». Toulouse 3, 2010. http://thesesups.ups-tlse.fr/1288/.
Texte intégralTwo and three dimensional carbon nanotube networks (2D- and 3D-CNTNs) were prepared over silica glass substrate and in silica matrix, respectively. The aptitudes of various CNTs (single-, double- and multi-walled CNTs: SWCNTs, DWCNTs and MWCNTs, respectively) to form percolating CNTNs were compared by measurement of their electrical conductivity (EC) in dynamic suspensions in chloroform. The SWCNTs suspensions show the highest maximum normalized EC (3. 08 S. Cm2/g) while the DWCNTs ones have the lowest percolation thresholds (0. 002-0. 06 vol. %). This led to choose SWCNTs for 2D-CNTNs and DWCNTs for 3D ones. To produce 2D-CNTNs, SWCNTs aqueous suspensions (prepared with surfactant and probe sonication, PS) were deposited over the substrates through: dip-coating (DC), filtration (FM), spray-coating (SC) and electrophoretic deposition (ED). Most of the 2D-CNTNs formed a percolating CNTN whose EC follow the power law (exponent ~1. 29). Their surface conductance and UV transparency allow their use in displays, touch screens, shielding in cathode tubes and electrostatic dissipation. The smoothest CNTNs obtained by DC and ED are also interesting for solar cells. The 3D-CNTNs were prepared by sol-gel route using mildly functionalized DWCNTs (with/without dry step) dispersed with PS. The nanocomposites were fully densified by spark-plasma sintering. The "Dry" route allowed the lowest percolation threshold (0. 35 vol. % DWCNT), while the more conductive material from "Wet" route shows EC of 1. 56 S/cm (6. 43 vol. % DWCNTs). Besides the dispersion of CNTs could be improved, the achieved EC of these nanocomposites is high enough for their use in anti-electrostatic or heating applications
Takele, Haile [Verfasser]. « Optical and electrical properties of metal-polymer nanocomposites prepared by vapor-phase co-evaporation / Haile Takele ». Kiel : Universitätsbibliothek Kiel, 2009. http://d-nb.info/1019810459/34.
Texte intégralLivres sur le sujet "Electrical Properties - Nanocomposites"
Wang, Qing, et Lei Zhu. Functional polymer nanocomposites for energy storage and conversion. Sous la direction de Wang Qing, Zhu Lei et American Chemical Society. Division of Polymeric Materials : Science and Engineering. Washington, D.C : American Chemical Society, 2010.
Trouver le texte intégralWang, Qing. Functional polymer nanocomposites for energy storage and conversion. Washington, D.C : American Chemical Society, 2010.
Trouver le texte intégralZnO bao mo zhi bei ji qi guang, dian xing neng yan jiu. Shanghai Shi : Shanghai da xue chu ban she, 2010.
Trouver le texte intégralHuang, Xingyi, et Chunyi Zhi. Polymer Nanocomposites : Electrical and Thermal Properties. Springer, 2018.
Trouver le texte intégralHuang, Xingyi, et Chunyi Zhi. Polymer Nanocomposites : Electrical and Thermal Properties. Springer, 2016.
Trouver le texte intégralHuang, Xingyi, et Chunyi Zhi. Polymer Nanocomposites : Electrical and Thermal Properties. Springer London, Limited, 2016.
Trouver le texte intégralNovel Nanocomposites : Optical, Electrical, Mechanical and Surface Related Properties. MDPI, 2021. http://dx.doi.org/10.3390/books978-3-0365-2248-7.
Texte intégralAyyar, Manikandan, Anish Khan, Abdullah Mohammed Ahmed Asiri et Imran Khan. Magnetic Nanoparticles and Polymer Nanocomposites : Structural, Electrical and Optical Properties and Applications [Volume 2]. Elsevier Science & Technology, 2023.
Trouver le texte intégralAyyar, Manikandan, Anish Khan, Abdullah Mohammed Ahmed Asiri et Imran Khan. Magnetic Nanoparticles and Polymer Nanocomposites : Structural, Electrical and Optical Properties and Applications, Volume 2. Elsevier Science & Technology, 2023.
Trouver le texte intégralAraújo, Ana Cláudia Vaz de. Síntese de nanopartículas de óxido de ferro e nanocompósitos com polianilina. Brazil Publishing, 2021. http://dx.doi.org/10.31012/978-65-5861-120-2.
Texte intégralChapitres de livres sur le sujet "Electrical Properties - Nanocomposites"
Fothergill, J. C. « Electrical Properties ». Dans Dielectric Polymer Nanocomposites, 197–228. Boston, MA : Springer US, 2009. http://dx.doi.org/10.1007/978-1-4419-1590-0_7.
Texte intégralFothergill, J. C. « Electrical Properties ». Dans Dielectric Polymer Nanocomposites, 197–228. Boston, MA : Springer US, 2009. http://dx.doi.org/10.1007/978-1-4419-1591-7_7.
Texte intégralSaini, Parveen. « Electrical Properties and Electromagnetic Interference Shielding Response of Electrically Conducting Thermosetting Nanocomposites ». Dans Thermoset Nanocomposites, 211–37. Weinheim, Germany : Wiley-VCH Verlag GmbH & Co. KGaA, 2013. http://dx.doi.org/10.1002/9783527659647.ch10.
Texte intégralCosta, L. C. « Microwave Electrical Properties of Nanocomposites ». Dans Nanoscience Advances in CBRN Agents Detection, Information and Energy Security, 227–38. Dordrecht : Springer Netherlands, 2014. http://dx.doi.org/10.1007/978-94-017-9697-2_23.
Texte intégralNizamuddin, Sabzoi, Sabzoi Maryam, Humair Ahmed Baloch, M. T. H. Siddiqui, Pooja Takkalkar, N. M. Mubarak, Abdul Sattar Jatoi et al. « Electrical Properties of Sustainable Nano-Composites Containing Nano-Fillers : Dielectric Properties and Electrical Conductivity ». Dans Sustainable Polymer Composites and Nanocomposites, 899–914. Cham : Springer International Publishing, 2019. http://dx.doi.org/10.1007/978-3-030-05399-4_30.
Texte intégralKhanam, P. Noorunnisa, Deepalekshmi Ponnamma et M. A. AL-Madeed. « Electrical Properties of Graphene Polymer Nanocomposites ». Dans Graphene-Based Polymer Nanocomposites in Electronics, 25–47. Cham : Springer International Publishing, 2015. http://dx.doi.org/10.1007/978-3-319-13875-6_2.
Texte intégralIndolia, Ajay Pal, Malvika Chaudhary, M. S. Gaur et Sobinder Singh. « Electrical Properties of PU/CdS Nanocomposites ». Dans Recent Advances in Metrology, 343–51. Singapore : Springer Nature Singapore, 2022. http://dx.doi.org/10.1007/978-981-19-2468-2_37.
Texte intégralGunasekaran, Vijayasri, Mythili Narayanan, Gurusamy Rajagopal et Jegathalaprathaban Rajesh. « Electrical and Dielectric Properties : Nanomaterials ». Dans Handbook of Magnetic Hybrid Nanoalloys and their Nanocomposites, 783–800. Cham : Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-90948-2_25.
Texte intégralGunasekaran, Vijayasri, Mythili Narayanan, Gurusamy Rajagopal et Jegathalaprathaban Rajesh. « Electrical and Dielectric Properties : Nanomaterials ». Dans Handbook of Magnetic Hybrid Nanoalloys and their Nanocomposites, 1–18. Cham : Springer International Publishing, 2022. http://dx.doi.org/10.1007/978-3-030-34007-0_25-1.
Texte intégralTsekmes, Alex, Peter Morshuis et Gary C. Stevens. « Chapter 8 Electrical Properties of Polymer Nanocomposites ». Dans Tailoring of Nanocomposite Dielectrics, 218–42. Penthouse Level, Suntec Tower 3, 8 Temasek Boulevard, Singapore 038988 : Pan Stanford Publishing Pte. Ltd., 2016. http://dx.doi.org/10.1201/9781315201535-9.
Texte intégralActes de conférences sur le sujet "Electrical Properties - Nanocomposites"
Ngabonziza, Yves, Jackie Li et Carol F. Barry. « Electrical Conductivity and Elastic Properties of MWCNT-PP Nanocomposites ». Dans ASME 2008 International Mechanical Engineering Congress and Exposition. ASMEDC, 2008. http://dx.doi.org/10.1115/imece2008-68431.
Texte intégralMinnich, Austin, et Gang Chen. « Modeling the Thermoelectric Properties of Nanocomposites ». Dans ASME 2008 3rd Energy Nanotechnology International Conference collocated with the Heat Transfer, Fluids Engineering, and Energy Sustainability Conferences. ASMEDC, 2008. http://dx.doi.org/10.1115/enic2008-53003.
Texte intégralReddy, R. J., R. Asmatulu et W. S. Khan. « Electrical Properties of Recycled Plastic Nanocomposites Produced by Injection Molding ». Dans ASME 2010 International Mechanical Engineering Congress and Exposition. ASMEDC, 2010. http://dx.doi.org/10.1115/imece2010-40259.
Texte intégralNgabonziza, Yves, et Jackie Li. « Electrical Conductivity and Elastic Properties of Carbon Nanotube Reinforced Polycarbonate Nanocomposites ». Dans ASME 2011 International Mechanical Engineering Congress and Exposition. ASMEDC, 2011. http://dx.doi.org/10.1115/imece2011-62685.
Texte intégralEnomoto, Hiroyuki, Masayuki Kawaguchi, Nipaka Sukpirom et Michael M. Lerner. « Electrical properties of polymer/ MX 2 nanocomposites ». Dans International Symposium on Optical Science and Technology, sous la direction de Naomi J. Halas. SPIE, 2002. http://dx.doi.org/10.1117/12.450467.
Texte intégralOskouyi, Amirhossein B., Uttandraman Sundararaj et Pierre Mertiny. « A Numerical Model to Study the Effect of Temperature on Electrical Conductivity of Polymer-CNT Nanocomposites ». Dans ASME 2013 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2013. http://dx.doi.org/10.1115/imece2013-62602.
Texte intégralHerren, Blake, Mrinal C. Saha, M. Cengiz Altan et Yingtao Liu. « Effects of Rapid Microwave-Curing on Mechanical and Piezoresistive Sensing Properties of Elastomeric Nanocomposites ». Dans ASME 2020 International Mechanical Engineering Congress and Exposition. American Society of Mechanical Engineers, 2020. http://dx.doi.org/10.1115/imece2020-23175.
Texte intégralThaler, Dominic, Nahal Aliheidari et Amir Ameli. « Electrical Properties of Additively Manufactured Acrylonitrile Butadiene Styrene/Carbon Nanotube Nanocomposite ». Dans ASME 2018 Conference on Smart Materials, Adaptive Structures and Intelligent Systems. American Society of Mechanical Engineers, 2018. http://dx.doi.org/10.1115/smasis2018-8002.
Texte intégralLi, Hua, et Gang Li. « Computational Analysis of Strain Effects on Electrical Transport Properties of Crystalline Nanocomposite Thin Films ». Dans ASME 2011 International Mechanical Engineering Congress and Exposition. ASMEDC, 2011. http://dx.doi.org/10.1115/imece2011-64641.
Texte intégralHan, Zhi-dong, Changjun Diao, Ying Li et Hong Zhao. « Thermal properties of LDPE/silica nanocomposites ». Dans 2006 IEEE Conference on Electrical Insulation and Dielectric Phenomena. IEEE, 2006. http://dx.doi.org/10.1109/ceidp.2006.311931.
Texte intégralRapports d'organisations sur le sujet "Electrical Properties - Nanocomposites"
Barnes, Eftihia, Jennifer Jefcoat, Erik Alberts, Hannah Peel, L. Mimum, J, Buchanan, Xin Guan et al. Synthesis and characterization of biological nanomaterial/poly(vinylidene fluoride) composites. Engineer Research and Development Center (U.S.), septembre 2021. http://dx.doi.org/10.21079/11681/42132.
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