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A word cloud is a visual representation of the most frequently used words in a text or a set of texts. The words appear in different sizes, with the size of each word being proportional to its frequency of occurrence in the text. The more frequently a word is used, the larger it appears in the word cloud. This technique allows for a quick visualization of the most important themes and concepts in a text.
In the context of this page, the word cloud was generated from the publications of the author {}. The words in this cloud come from the titles, abstracts, and keywords of the author's articles and research papers. By analyzing this word cloud, you can get an overview of the most recurring and significant topics and research areas in the author's work.
The word cloud is a useful tool for identifying trends and main themes in a corpus of texts, thus facilitating the understanding and analysis of content in a visual and intuitive way.
Kim, Y., Assali, S., Joo, H.-J., Koelling, S., Chen, M., Luo, L., Shi, X., Burt, D., Ikonic, Z., Nam, D., & Moutanabbir, O. (2023). Short-wave infrared cavity resonances in a single GeSn nanowire. Nature Communications, 14(1), 4393 (7 pages). Available
Kim, Y.-M., Assali, S., Jung, Y., Burt, D., Zhang, L., Joo, H.-J., Koelling, S., Chen, M., Luo, L., Atalla, M. R. M., Ikonic, Z., Tan, C. S., Moutanabbir, O., & Nam, D. (2022). Evolution of Gesn Lasers Towards Photonic Integration into Practical Applications. Meeting abstracts, MA2022-02(32), 1167-1167. External link
Burt, D., Joo, H.-J., Kim, Y., Jung, Y., Chen, M., Luo, M., Kang, D.-H., Assali, S., Zhang, L., Son, B., Fan, W., Moutanabbir, O., Ikonic, Z., Tan, C. S., Huang, Y.-C., & Nam, D. (2022). Direct bandgap GeSn nanowires enabled with ultrahigh tension from harnessing intrinsic compressive strain. Applied Physics Letters, 120(20), 7 pages. External link
Kim, Y., Assali, S., Burt, D., Jung, Y., Joo, H.-J., Chen, M., Ikonic, Z., Moutanabbir, O., & Nam, D. (2022). Enhanced GeSn Microdisk Lasers Directly Released on Si. Advanced Optical Materials, 10(2), 2101213 (7 pages). External link
Joo, H.-J., Kim, Y., Burt, D., Jung, Y., Zhang, L., Chen, M., Luo, M., Parluhutan, S. J., Kang, D.-H., Lee, C., Assali, S., Son, B., Ikonic, Z., Moutanabbir, O., Cho, Y.-H., Tan, C. S., Huang, Y.-C., & Nam, D. (2022). Gesnoi Laser Technology for Photonic-Integrated Circuits. ECS Meeting Abstracts, MA2022-02(32), 1168-1168. External link
Joo, H.-J., Kim, Y., Burt, D., Jung, Y., Zhang, L., Chen, M., Parluhutan, S. J., Kang, D.-H., Lee, C., Assali, S., Ikonic, Z., Moutanabbir, O., Cho, Y.-H., Tan, C. S., & Nam, D. (2021). 1D photonic crystal direct bandgap GeSn-on-insulator laser. Applied Physics Letters, 119(20), 201101 (6 pages). External link
Joo, H.-J., Kim, Y., Burt, D., Yung, Y., Zhang, L., Chen, M., Parluhutan, S. J., Kang, D.-H., Lee, C., Assali, S., Ikonic, Z., Moutanabbir, O., Cho, Y.-H., Tan, C. S., & Nam, D. (2022, January). 1D photonic crystal GeSn-on-insulator nanobeam laser [Paper]. Silicon Photonics XVII, San Francisco, CA, USA (9 pages). External link
Kim, Y., Assali, S., Burt, D., Jung, Y., Joo, H.-J., Chen, M., Ikonic, Z., Moutanabbir, O., & Nam, D. (2022, January). Improved GeSn microdisk lasers directly sitting on Si [Paper]. Silicon Photonics XVII, San Francisco, CA, USA (7 pages). External link
Burt, D., Jooa, H.-J., Kim, Y., Jung, Y., Chen, M., Luo, M., Kang, D.-H., Assali, S., Zhang, L., Son, B., Fan, W., Moutanabbir, O., Ikonic, Z., Tan, C. S., Huang, Y.-C., & Nam, D. (2022, January). Tensile-strained direct bandgap GeSnOI micro/nanostructures by harnessing residual strain [Paper]. Silicon Photonics XVII. External link