Е-Публикации
Технически университет - София

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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 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 или Web of Science

Вид: статия в списание, публикация в издание с импакт фактор