| Autors: Aleksandrova, M. P. Title: Specifics and challenges to flexible organic light-emitting devices Keywords: flexible OLED, fabrication methods, ink jet printing, roll-t References Issue
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Цитирания (Citation/s):
1. Towards low cost fabrication of inorganic white light emitting diode based on electrodeposited Cu2O thin film/TiO2 nanorods heterojunction, El-Shaer, A., Ismail, W., Abdelfatah, M., 2019, Materials Research Bulletin 116, pp. 111-116, https://www.scopus.com/record/display.uri?eid=2-s2.0-85064434565&origin=resultslist&sort=plf-f&src=s&citedAuthorId=35076971000&imp=t&sid=30f4a95e919af2d00341c0c00bb2bce5&sot=cite&sdt=cite&cluster=scopubyr%2c%222019%22%2ct&sl=0&relpos=6&citeCnt=7&searchTerm= - 2019 - в издания, индексирани в Scopus и/или Web of Science
2. Photophysical and energy transfer mechanism studies of Poly (9,9-di-n-octylflourenyl-2,7-diyl)/Fluorol 7GA/Poly [2-methoxy-5-(2-ethylhexyloxy)-1,4-phenylenevinylene] ternary organic blend films Fuzi, S.A.A., Hj. Jumali, M.H., Al-Asbahi, B.A., Qaid, S.M.H., 2019, Thin Solid Films 683, pp. 90-96, https://www.scopus.com/record/display.uri?eid=2-s2.0-85065872805&origin=resultslist&sort=plf-f&src=s&citedAuthorId=35076971000&imp=t&sid=30f4a95e919af2d00341c0c00bb2bce5&sot=cite&sdt=cite&cluster=scopubyr%2c%222019%22%2ct&sl=0&relpos=7&citeCnt=1&searchTerm= - 2019 - в издания, индексирани в Scopus и/или Web of Science
3. Exciton-triggered luminance degradation of organic light-emitting diodes Ingram, G.L., Zhao, Y.-B., Lu, Z.-H. 2019 Organic Electronics 69, pp. 160-163 , https://www.scopus.com/record/display.uri?eid=2-s2.0-85063301699&origin=resultslist&sort=plf-f&src=s&citedAuthorId=35076971000&imp=t&sid=30f4a95e919af2d00341c0c00bb2bce5&sot=cite&sdt=cite&cluster=scopubyr%2c%222019%22%2ct&sl=0&relpos=15&citeCnt=4&searchTerm= - 2019 - в издания, индексирани в Scopus и/или Web of Science
4. Fabrication of an efficient Electrode/Organic Interface for Flexible Sensors Topno, N.R., Sundriyal, P., Bhattacharya, S. 2019 Materials Today: Proceedings 16, pp. 1469-1474 , https://www.scopus.com/record/display.uri?eid=2-s2.0-85094620822&origin=resultslist&sort=plf-f&src=s&citedAuthorId=35076971000&imp=t&sid=30f4a95e919af2d00341c0c00bb2bce5&sot=cite&sdt=cite&cluster=scopubyr%2c%222019%22%2ct&sl=0&relpos=23&citeCnt=0&searchTerm= - 2019 - в издания, индексирани в Scopus и/или Web of Science
5. Camber deformation property and fracture strain of flexible film made by polydimethylsiloxane Lai, H., Yuan, C., Lin, H. 2020 Optical Materials 107,110066 - 2020 - в издания, индексирани в Scopus и/или Web of Science
6. Change in interface characteristics of ITO modified with n-decyltrimethoxysilane Open Access Baek, M.-G., Shin, J.-E., Hwang, D.-H., (...), Park, H.-G., Park, S.-G. 2020 Crystals 10(8),645, pp. 1-9 - 2020 - в издания, индексирани в Scopus и/или Web of Science
7. Interfacial fracture investigation of patterned active matrix OLED driven by amorphous-Si TFTs under film-type packaging technology Lee, C.-C., Wang, C.-W. 2020 Applied Surface Science 510,145428 - 2020 - в издания, индексирани в Scopus и/или Web of Science
8. Excimer laser annealing method for achieving low electrical resistivity and high work function in transparent conductive amorphous In2O3:Zn films on a polyethylene terephthalate substrate Nomoto, J., Yamaguchi, I., Nakajima, T., Matsubayashi, Y., Tsuchiya, T. 2020 Thin Solid Films 698,137867 - 2020 - в издания, индексирани в Scopus и/или Web of Science
9. Surface defect formation in polyimide film via ion migration from glass substrate Son, J.H., Lee, W.-E., Byun, D.-J., Heo, K. 2020 Polymer Degradation and Stability 173,109079 - 2020 - в издания, индексирани в Scopus и/или Web of Science
10. Controlling the emission spectrum of binary emitting polymer hybrids by a systematic doping strategy via förster resonance energy transfer for white emission, Al-Asbahi, B.A., Alsalhi, M.S., Fatehmulla, A., (...), Mujamammi, W.M., Ghaithan, H.M., 2021, Micromachines 12(11), 1371 - 2021 - в издания, индексирани в Scopus и/или Web of Science
11. Differences in ito surfaces according to the formation of aromatic rings and aliphatic self-assembled monolayers for organic light-emitting diode applications, Baek, M.-G., Park, S.-G., 2021, Nanomaterials 11(10), 2520 - 2021 - в издания, индексирани в Scopus и/или Web of Science
12. Printed Organic Light-Emitting Diodes on Fabric with Roll-to-Roll Sputtered ITO Anode and Poly(vinyl alcohol) Planarization Layer, Sohn, S., Kim, S., Shim, J.W., Jung, S.K., Jung, S., 2021, ACS Applied Materials and Interfaces 13(24), pp. 28521-28528 - 2021 - в издания, индексирани в Scopus и/или Web of Science
13. An efficient and facile method to develop defect-free OLED displays, Solanki, A., Awasthi, A., Unni, K.N.N., Deepak, 2021, Semiconductor Science and Technology 36(6), 065005 - 2021 - в издания, индексирани в Scopus и/или Web of Science
14. Recent progress in the high-temperature-resistant PI substrate with low CTE for CIGS thin-film solar cells, Shi, S., Yao, L., Ma, P., (...), Yang, C., Li, W., 2021, Materials Today Energy 20, 100640 - 2021 - в издания, индексирани в Scopus и/или Web of Science
15. Synthesis and photoluminescence properties of heteroleptic 9-arylated carbazole iridium(Iii) complexes, Oh, S.H., Yum, E.K., Kim, Y., (...), Heo, J., Kim, Y.-J., 2021, Applied Chemistry for Engineering 32(2), pp. 180-189 - 2021 - в издания, индексирани в Scopus и/или Web of Science
16. Origin of simultaneous enhancement of work function and carrier concentration in In2O3films by excimer-laser irradiation, Nomoto, J., Matsui, H., Yamaguchi, I., Nakajima, T., Tsuchiya, T., 2021, Applied Physics Letters 118(10), 101602 - 2021 - в издания, индексирани в Scopus и/или Web of Science
17. A Brief History of OLEDs—Emitter Development and Industry Milestones Open Access, Hong, G., Gan, X., Leonhardt, C., (...), Busch, J.M., Bräse, S., 2021, Advanced Materials 33(9),2005630 - 2021 - в издания, индексирани в Scopus и/или Web of Science
18. Gioti, M., Tselekidou, D., Foris, V., Kyriazopoulos, V., Papadopoulos, K., Kassavetis, S., & Logothetidis, S. (2022). Influence of dopant concentration and annealing on binary and ternary polymer blends for active materials in OLEDs. Nanomaterials, 12(22) doi:10.3390/nano12224099 - 2022 - в издания, индексирани в Scopus и/или Web of Science
19. Lin, Y., Zhou, X., Hou, X., Xie, Z., & Liu, L. (2022). Spatial identification of "zeroth defect" formation in organic light-emitting diodes by multispectral mappings. ACS Applied Materials and Interfaces, 14(27), 31474-31481. doi:10.1021/acsami.2c09033 - 2022 - в издания, индексирани в Scopus и/или Web of Science
20. Abroshan, H., Winget, P., Kwak, H. S., An, Y., Brown, C. T., & Halls, M. D. (2022). Machine learning for the design of novel OLED materials doi:10.1021/bk-2022-1416.ch002 - 2022 - в издания, индексирани в Scopus и/или Web of Science
21. WS2 incorporated PANI-rGO nanocomposites tailored for inflated thermal, optical and electrical properties used as ETL for OLEDs, G Mandal, RB Choudhary, BA Al-Asbahi, AAA Ahmed - Optical Materials, Volume 146, December 2023, 114379 - 2023 - в издания, индексирани в Scopus и/или Web of Science
22. Debashish Nayak, Ram Bilash Choudhary, A survey of the structure, fabrication, and characterization of advanced organic light emitting diodes, May 2023, Microelectronics Reliability 144(1–2):114959 - 2023 - в издания, индексирани в Scopus и/или Web of Science
23. Large area small-molecule thin films deposited by the doctor blade technique implemented with computer numerical control machine Ramos-Hernández, R., Calvo, F.D., Pérez-Gutiérrez, E., Percino, M.J. 2023 Thin Solid Films 771,139787 - 2023 - в издания, индексирани в Scopus и/или Web of Science
24. Multifacets of organometallic quinoline complexes, January 2023, DOI: 0.1016/B978-0-323-85788-8.00006-9, In book: Functional Materials from Carbon, Inorganic, and Organic Sources, Chitra S. Khade, Thejo Kalyani, S J Dhoble, Functional Materials from Carbon, Inorganic, and Organic Sources Methods and Advances Woodhead Publishing Series in Electronic and Optical Materials 2023, Pages 453-475. - 2023 - в издания, индексирани в Scopus и/или Web of Science
25. Kamarudin S.F., Abdul Aziz N.H., Lee H.W., Jaafar M., Sulaiman S., Inkjet Printing Optimization: Toward Realization of High-Resolution Printed Electronics (2024) Advanced Materials Technologies, 9 (14), art. no. 2301875 - 2024 - в издания, индексирани в Scopus и/или Web of Science
26. Ndikumana J., An K., Spectrally independent and wide-angle light extraction of organic light emitting diodes with randomly disassembled nanostructure (2024) Nanoscale, 16 (32), pp. 15319 - 15329. - 2024 - в издания, индексирани в Scopus и/или Web of Science
27. Tesis Diseno y fabricacion de oleds basados en nuevos Derivados de oxadiazoles simetricos luminiscentes Presenta M.c. Miguel Angel Aztatzi Mendoza, Abril 2024, Universidad Autonoma de Nuevo Leon - 2024 - от чужди автори в чужди издания, неиндексирани в Scopus или Web of Science
28. Han T., Chen P., Zhang Y., Tang S.-J., Teng M.-Y., Shi C.-Y., Ye L.-W., Huang G.-L., Chen Z., Han H.-B., Lu G., Zheng Y.-X., High-performance solution-processed orange phosphorescent OLEDs, 2025, Science China Materials, issue 0, DOI 10.1007/s40843-024-3321-5, issn 20958226, eissn 21994501 - 2025 - в издания, индексирани в Scopus
29. Agarwal A., Sharma V., Misra G., Mehta S.N., Flexible Diodes: Principles, Concepts, and Applications Toward 5G Green Communication, 2025, 5G Green Communication Networks For Smart Cities, issue 0, pp. 95-107 - 2025 - в издания, индексирани в Scopus
30. Aarti A., Veettil B.P., Rodger A., Venkatesan K., Recent Progress and Challenges in Molecular Design for Hyperfluorescent Based Organic Light Emitting Diodes (OLEDs), 2025, Advanced Optical Materials, issue 0, DOI 10.1002/adom.202501648, eissn 21951071 - 2025 - в издания, индексирани в Scopus
Вид: статия в списание, публикация в издание с импакт фактор, индексирана в Scopus
