Nanocomposite materials based on graphene, graphene oxide, and silver nanoparticles
| dc.citation.epage | 169 | |
| dc.citation.issue | 1 | |
| dc.citation.journalTitle | Інфокомунікаційні технології та електронна інженерія | |
| dc.citation.spage | 163 | |
| dc.citation.volume | 3 | |
| dc.contributor.affiliation | Національний університет “Львівська політехніка” | |
| dc.contributor.affiliation | Lviv Polytechnic National University | |
| dc.contributor.author | Яремчук, І. | |
| dc.contributor.author | Булавінець, Т. | |
| dc.contributor.author | Стахіра, П. | |
| dc.contributor.author | Фітьо, В. | |
| dc.contributor.author | Yaremchuk, I. | |
| dc.contributor.author | Bulavinets, T. | |
| dc.contributor.author | Stakhira, P. | |
| dc.contributor.author | Fitio, V. | |
| dc.coverage.placename | Львів | |
| dc.coverage.placename | Lviv | |
| dc.date.accessioned | 2025-07-22T10:58:35Z | |
| dc.date.created | 2023-02-28 | |
| dc.date.issued | 2023-02-28 | |
| dc.description.abstract | У роботі досліджено плазмонні характеристики нанокомпозитних матеріалів на основі графену, оксиду графену та наночастинок срібла. Розраховано ефективну діелектричну проникність та коефіцієнт поглинання нанокомпозитів на основі графен – срібло та оксид графену – срібло залежно від концентрації та розміру наночастинок. Зміна коефіцієнта заповнення наночастинок срібла на 5 % призводить до істотних змін як дійсної, так і уявної частин ефективної діелектричної проникності нанокомпозитного матеріалу. Яскраво виражений пік поглинання спостерігається у випадку композиту на основі графену з коефіцієнтом заповнення срібла 0,2. Водночас для композиту на основі оксиду графену пік поглинання можна ідентифікувати, якщо коефіцієнт заповнення срібла дорівнює 0,1. Максимальне поглинання спостерігається для нанокомпозитного матеріалу із включеннями радіусом 5 нм в обох випадках. Досліджувані нанокомпозитні матеріали можна успішно використовуватись для різних застосувань органічної електроніки. | |
| dc.description.abstract | In this work, plasmon characteristics of nanocomposite materials based on graphene, graphene oxide, and silver nanoparticles have been studied. The effective dielectric constant and absorption coefficient of the nanocomposites based on graphene-silver and graphene oxide – silver depending on the concentration and size of nanoparticles have been calculated. A change in the silver nanoparticles filling factor by 5 percent leads to significant changes in both the real and imaginary parts of the effective dielectric constant of the nanocomposite material. A pronounced absorption peak is observed in the case of graphene-based nanocomposite with a silver filling factor of 0.2. At the same time, the absorption peak can be indicated at a silver filling factor of 0.1 for the graphene oxide-based nanocomposite. The maximum absorption is observed for the nanocomposite material with nanoparticles having a radius of 5 nm in both cases. The researched nanocomposite materials can be successfully used for various organic electronics applications. | |
| dc.format.extent | 163-169 | |
| dc.format.pages | 7 | |
| dc.identifier.citation | Nanocomposite materials based on graphene, graphene oxide, and silver nanoparticles / I. Yaremchuk, T. Bulavinets, P. Stakhira, V. Fitio // Infocommunication Technologies and Electronic Engineering. — Lviv : Lviv Politechnic Publishing House, 2023. — Vol 3. — No 1. — P. 163–169. | |
| dc.identifier.citationen | Nanocomposite materials based on graphene, graphene oxide, and silver nanoparticles / I. Yaremchuk, T. Bulavinets, P. Stakhira, V. Fitio // Infocommunication Technologies and Electronic Engineering. — Lviv : Lviv Politechnic Publishing House, 2023. — Vol 3. — No 1. — P. 163–169. | |
| dc.identifier.doi | doi.org/10.23939/ictee2023.01.163 | |
| dc.identifier.uri | https://ena.lpnu.ua/handle/ntb/111432 | |
| dc.language.iso | en | |
| dc.publisher | Видавництво Львівської політехніки | |
| dc.publisher | Lviv Politechnic Publishing House | |
| dc.relation.ispartof | Інфокомунікаційні технології та електронна інженерія, 1 (3), 2023 | |
| dc.relation.ispartof | Infocommunication Technologies and Electronic Engineering, 1 (3), 2023 | |
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| dc.relation.referencesen | [1] Álvarez-Rodríguez, P., García-Suárez, V. M. (2022). Effect of Impurity Adsorption on the Electronic and Transport Properties of Graphene Nanogaps. Materials, Vol. 15, No 2, p. 500. | |
| dc.relation.referencesen | [2] Fumagalli, E., Raimondo, L., Silvestri, L., Moret, M., Sassella, A., & Campione, M. (2011). Oxidation dynamics of epitaxial rubrene ultrathin films. Chemistry of Materials, Vol. 23, No. 13, pp. 3246–3253. | |
| dc.relation.referencesen | [3] Wang, S., Liu, C., & Li, Q. (2013). Impact of polymer flocculants on coagulation-microfiltration of surface water. Water research, Vol. 47, No. 13, pp. 4538–4546. | |
| dc.relation.referencesen | [4] Omanović-Mikličanin, E., Badnjević, A., Kazlagić, A., & Hajlovac, M. (2020). Nanocomposites: A brief review. Health and Technology, Vol. 10, pp. 51–59. | |
| dc.relation.referencesen | [5] Reyna, A. S., & de Araújo, C. B. (2017). High-order optical nonlinearities in plasmonic nanocomposites – a review. Advances in Optics and Photonics, Vol. 9, No. 4, pp. 720–774. | |
| dc.relation.referencesen | [6] Papageorgiou, D. G., Kinloch, I. A., & Young, R. J. (2017). Mechanical properties of graphene and graphene-based nanocomposites. Progress in materials science, Vol. 90, pp. 75–127. | |
| dc.relation.referencesen | [7] Manno, D., Torrisi, L., Silipigni, L., Buccolieri, A., Cutroneo, M., Torrisi, A., ... & Serra, A. (2022). From GO to rGO: An analysis of the progressive rippling induced by energetic ion irradiation. Applied Surface Science, Vol. 586, pp. 152789. | |
| dc.relation.referencesen | [8] Singh, V., Joung, D., Zhai, L., Das, S., Khondaker, S. I., & Seal, S. (2011). Graphene-based materials: past, present, and future. Progress in materials science, Vol. 56, No. 8, pp. 1178–1271. | |
| dc.relation.referencesen | [9] Shyamala, R., & Devi, L. G. (2020). Reduced graphene oxide/SnO2 nanocomposites for the photocatalytic degradation of rhodamine B: Preparation, characterization, photosensitization, vectorial charge transfer mechanism, and identification of reaction intermediates. Chemical Physics Letters, vol. 748, pp. 137385. | |
| dc.relation.referencesen | [10] Iqbal, A. A., Sakib, N., Iqbal, A. P., & Nuruzzaman, D. M. (2020). Graphene-based nanocomposites and their fabrication, mechanical properties, and applications. Materialia, Vol. 12, pp. 100815. | |
| dc.relation.referencesen | [11] Gong, S., Ni, H., Jiang, L., & Cheng, Q. (2017). Learning from nature: constructing high-performance graphene-based nanocomposites. Materials Today, Vol. 20, No. 4, pp. 210–219. | |
| dc.relation.referencesen | [12] He, K., Zeng, Z., Chen, A., Zeng, G., Xiao, R., Xu, P., ... & Chen, G. (2018). Advancement of Aggraphene-based nanocomposites: an overview of the synthesis and its applications. Small, Vol. 14, No. 32, pp. 1800871. | |
| dc.relation.referencesen | [13] Giasafaki, D., Mitzithra, C., Belessi, V., Filippakopoulou, T., Koutsioukis, A., Georgakilas, V., ... & Steriotis, T. (2022). Graphene-Based Composites with Silver Nanowires for Electronic Applications. Nanomaterials, Vol. 12. No. 19, pp. 3443. | |
| dc.relation.referencesen | [14] Ramalingam, G., Nagapandiselvi, P., Priya, A. K., & Rajendran, S. (2022). A review of graphene-based semiconductors for photocatalytic degradation of pollutants in wastewater. Chemosphere, pp. 134391. | |
| dc.relation.referencesen | [15] Banerjee, S., Dionysiou, D. D., & Pillai, S. C. (2015). Self-cleaning applications of TiO2 by photo-induced hydrophilicity and photocatalysis. Applied Catalysis B: Environmental, Vol. 176, pp. 396–428. | |
| dc.relation.referencesen | [16] Adam, R. E., Chalangar, E., Pirhashemi, M., Pozina, G., Liu, X., Palisaitis, J., ... & Nur, O. (2019). Graphene-based plasmonic nanocomposites for highly enhanced solar-driven photocatalytic activities. RSC advances, Vol. 9, No. 52, pp. 30585–30598. | |
| dc.relation.referencesen | [17] Pryshchepa, O., Pomastowski, P., & Buszewski, B. (2020). Silver nanoparticles: Synthesis, investigation techniques, and properties. Advances in Colloid and Interface Science, Vol. 284, pp. 102246. | |
| dc.relation.referencesen | [18] Sun, H., Ge, G., Zhu, J., Yan, H., Lu, Y., Wu, Y., ... & Luo, Y. (2015). High electrical conductivity of graphene-based transparent conductive films with silver nanocomposites. RSC Advances, Vol. 5, No. 130, pp. 108044–108049. | |
| dc.relation.referencesen | [19] de Faria, A. F., Martinez, D. S. T., Meira, S. M. M., de Moraes, A. C. M., Brandelli, A., Souza Filho, A. G., & Alves, O. L. (2014). Anti-adhesion and antibacterial activity of silver nanoparticles supported on graphene oxide sheets. Colloids and Surfaces B: Biointerfaces, Vol. 113, pp. 115–124. | |
| dc.relation.referencesen | [20] Al-Masoodi, A. H. H., Talik, N. A., Goh, B. T., Sarjidan, M. A. M., Al-Masoodi, A. H., & Abd Majid, W. H. (2021). Effect of silver nanoparticles deposited on indium tin oxide by plasma-assisted hot-filament evaporation on phosphorescent organic light-emitting diode performance. Applied Surface Science, Vol. 570, pp. 151280. | |
| dc.relation.referencesen | [21] Triambulo, R. E., Cheong, H. G., & Park, J. W. (2014). All-solution-processed foldable transparent electrodes of Ag nanowire mesh and metal matrix films for flexible electronics. Organic Electronics, Vol. 15. No. 11, pp. 2685–2695. | |
| dc.relation.referencesen | [22] Wang, Y., Li, H., Zhu, W., He, F., Huang, Y., Chong, R., ... & Fang, X. (2019). Plasmon-mediated nonradiative energy transfer from a conjugated polymer to a plane of graphene-nanodot-supported silver nanoparticles: an insight into the characteristic distance. Nanoscale, Vol. 11, No. 14, pp. 6737–6746. | |
| dc.relation.referencesen | [23] Markel, V. A. (2016). Introduction to the Maxwell Garnett approximation: a tutorial. JOSA A, Vol. 33, No. 7, pp. 1244–1256. | |
| dc.relation.referencesen | [24] Song, B., Gu, H., Zhu, S., Jiang, H., Chen, X., Zhang, C., & Liu, S. (2018). Broadband optical properties of graphene and HOPG investigated by spectroscopic Mueller matrix ellipsometry. Applied Surface Science, Vol. 439, pp. 1079–1087. | |
| dc.relation.referencesen | [25] Schöche, S., Hong, N., Khorasaninejad, M., Ambrosio, A., Orabona, E., Maddalena, P., & Capasso, F. (2017). Optical properties of graphene oxide and reduced graphene oxide determined by spectroscopic ellipsometry. Applied Surface Science, Vol. 421, pp. 778–782. | |
| dc.relation.referencesen | [26] Fitio, V., Yaremchuk, I., Vernyhor, O., & Bobitski, Y. (2020). Analytical expressions for spectral dependences of silver, gold, copper, and aluminum dielectric permittivity. Optica Applicata, Vol. 50, No. 2, pp. 171–184. | |
| dc.rights.holder | © Національний університет “Львівська політехніка”, 2023 | |
| dc.subject | нанокомпозитні матеріали | |
| dc.subject | графен | |
| dc.subject | оксид графену | |
| dc.subject | наночастинки срібла | |
| dc.subject | ефективна діелектрична проникність | |
| dc.subject | поглинання | |
| dc.subject | nanocomposite materials | |
| dc.subject | graphene | |
| dc.subject | oxide graphene | |
| dc.subject | silver nanoparticles | |
| dc.subject | effective dielectric permittivity | |
| dc.subject | absorption | |
| dc.subject.udc | 53.072 | |
| dc.subject.udc | 53 | |
| dc.subject.udc | 004 | |
| dc.title | Nanocomposite materials based on graphene, graphene oxide, and silver nanoparticles | |
| dc.title.alternative | Нанокомпозитні матеріали на основі графену, оксиду графену та наночастинок срібла | |
| dc.type | Article |
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