請用此 Handle URI 來引用此文件:
http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101739完整後設資料紀錄
| DC 欄位 | 值 | 語言 |
|---|---|---|
| dc.contributor.advisor | 謝馬利歐 | zh_TW |
| dc.contributor.advisor | Mario Hofmann | en |
| dc.contributor.author | 卡娣卡 | zh_TW |
| dc.contributor.author | Karthika Vijayan | en |
| dc.date.accessioned | 2026-03-04T16:11:15Z | - |
| dc.date.available | 2026-03-05 | - |
| dc.date.copyright | 2026-03-04 | - |
| dc.date.issued | 2026 | - |
| dc.date.submitted | 2026-02-23 | - |
| dc.identifier.citation | References
1. A. Dey, J. Ye, A. De, E. Debroye, S. K. Ha, E. Bladt, A. S. Kshirsagar, Z. Wang, J. Yin and Y. Wang, ACS nano, 2021, 15, 10775-10981. 2. X. Cui, Y. Liu and Y. Chen, National science review, 2024, 11, nwae033. 3. X.-S. Tao, F. Chu, S. Wang, X. Fang, J. Zhang, J. Meng, J. Sha and Y. Chen, Energy Z, 2025, 1, N/A-N/A. 4. Z. Li, T. R. Klein, D. H. Kim, M. Yang, J. J. Berry, M. F. Van Hest and K. Zhu, Nature Reviews Materials, 2018, 3, 1-20. 5. M. Eslamian, Nano-micro letters, 2017, 9, 3. 6. L. Protesescu, S. Yakunin, M. I. Bodnarchuk, F. Krieg, R. Caputo, C. H. Hendon, R. X. Yang, A. Walsh and M. V. Kovalenko, Nano letters, 2015, 15, 3692-3696. 7. L. M. Wheeler, E. M. Sanehira, A. R. Marshall, P. Schulz, M. Suri, N. C. Anderson, J. A. Christians, D. Nordlund, D. Sokaras and T. Kroll, Journal of the American Chemical Society, 2018, 140, 10504-10513. 8. G. Nedelcu, L. Protesescu, S. Yakunin, M. I. Bodnarchuk, M. J. Grotevent and M. V. Kovalenko, Nano letters, 2015, 15, 5635-5640. 9. K. Hills‐Kimball, H. Yang, T. Cai, J. Wang and O. Chen, Advanced science, 2021, 8, 2100214. 10. F. Palazon, S. Dogan, S. Marras, F. Locardi, I. Nelli, P. Rastogi, M. Ferretti, M. Prato, R. Krahne and L. Manna, The Journal of Physical Chemistry C, 2017, 121, 11956-11961. 11. G. Li, F. Wisnivesky Rocca Rivarola, N. J. Davis, S. Bai, T. C. Jellicoe, F. de la Peña, S. Hou, C. Ducati, F. Gao and R. H. Friend, Advanced materials, 2016, 28, 3528-+. 12. M. Hao, Y. Bai, S. Zeiske, L. Ren, J. Liu, Y. Yuan, N. Zarrabi, N. Cheng, M. Ghasemi and P. Chen, Nature Energy, 2020, 5, 79-88. 13. A. Honciuc, O.-I. Negru and M. Honciuc, Nanomaterials, 2024, 14, 809. 14. E. M. Furst, Proceedings of the National Academy of Sciences, 2011, 108, 20853-20854. 15. L. Song, B. B. Xu, Q. Cheng, X. Wang, X. Luo, X. Chen, T. Chen and Y. Huang, Science Advances, 2021, 7, eabk2852. 16. S. K. Gupta and Y. Mao, The Journal of Physical Chemistry C, 2021, 125, 6508-6533. 17. Y. Wang and L. Huang, Small, 2025, 21, 2410028. 18. D. D. Kruger, H. García and A. Primo, Advanced Science, 2024, 11, 2307106. 19. Y. Stulov, V. Dolmatov, A. Dubrovskiy and S. Kuznetsov, Coatings, 2023, 13, 352. 20. H.-R. Wenk and A. Bulakh, Minerals: their constitution and origin, Cambridge University Press, 2016. 21. A. Ruth, M. Holland, A. Rockett, E. Sanehira, M. D. Irwin and K. X. Steirer, Crystals, 2022, 12, 88. 22. A. Suzuki, H. Okada and T. Oku, Energies, 2016, 9, 376. 23. P. Szuromi and B. Grocholski, Journal, 2017, 358, 732-733. 24. J. Shamsi, A. S. Urban, M. Imran, L. De Trizio and L. Manna, Chemical reviews, 2019, 119, 3296-3348. 25. Y. Pan, Y. Zhang, W. Kang, N. Deng, Z. Yan, W. Sun, X. Kang and J. Ni, Materials Advances, 2022, 3, 4053-4068. 26. M. A. Adeshina, A. M. Ogunleye, H. Lee, G. Kim, H. Kim and J. Park, Materials Advances, 2025, 6, 8960-8967. 27. J. Yan, H. Li, M. H. Aldamasy, C. Frasca, A. Abate, K. Zhao and Y. Hu, Chemistry of Materials, 2023, 35, 2683-2712. 28. P. s. Antonio, G. l.-C. Soranyel, M. Olga, A. Said, M. n. E. Guillermo and P. r.-P. Julia, 2014. 29. Z.-J. Li, E. Hofman, A. H. Davis, M. M. Maye and W. Zheng, Chemistry of Materials, 2018, 30, 3854-3860. 30. R. A. Kerner, L. Zhao, Z. Xiao and B. P. Rand, Journal of Materials Chemistry A, 2016, 4, 8308-8315. 31. S. Tang, X. Xiao, J. Hu, B. Gao, H. Chen, Z. Zuo, Q. Qi, Z. Peng, J. Wen and D. Zou, RSC advances, 2021, 11, 5874-5884. 32. S. Shao and M. A. Loi, Advanced Materials Interfaces, 2020, 7, 1901469. 33. Y. Shao, Y. Fang, T. Li, Q. Wang, Q. Dong, Y. Deng, Y. Yuan, H. Wei, M. Wang and A. Gruverman, Energy & Environmental Science, 2016, 9, 1752-1759. 34. K. Embrose, M. H. Prakash, T. Vasudevan and L.-C. Chen, ACS Applied Energy Materials, 2025, 8, 2011-2021. 35. F. M. Rombach, S. A. Haque and T. J. Macdonald, Energy & Environmental Science, 2021, 14, 5161-5190. 36. S. Milanese, M. L. De Giorgi, G. Morello, M. I. Bodnarchuk and M. Anni, ACS Applied Nano Materials, 2025, 8, 3964-3973. 37. S. Svanstrom, T. J. Jacobsson, G. Boschloo, E. M. Johansson, H. Rensmo and U. B. Cappel, ACS applied materials & interfaces, 2020, 12, 7212-7221. 38. T. Kimura, Advances in ceramics-synthesis and characterization, processing and specific applications, 2011, 75-100. 39. P. LIU, Y.-x. TONG and Q.-q. YANG, Journal of Electrochemistry, 2007, 13, 1. 40. D. Portehault, S. Devi, P. Beaunier, C. Gervais, C. Giordano, C. Sanchez and M. Antonietti, Angewandte Chemie-German Edition, 2011, 123, 3320. 41. J. P. Zuniga, M. Abdou, S. K. Gupta and Y. Mao, Journal of visualized experiments: JoVE, 2018, 58482. 42. D. Austin, K. Gliebe, C. Muratore, B. Boyer, T. S. Fisher, L. K. Beagle, A. Benton, P. Look, D. Moore and E. Ringe, Materials Today, 2021, 43, 17-26. 43. J. A. Fox and D. N. Barr, Applied Optics, 1973, 12, 2547-2548. 44. W. Guo, Z. Li, L. Huang, M. Qian, J. M. Tour and R. Ye, Nature Synthesis, 2025, 4, 1488-1503. 45. V. V. Yakovlev, V. Lazarov, A. R. Faustov, J. Reynolds and M. Gajdardziska-Josifovska, 2000. 46. G. Z. Chen, D. J. Fray and T. W. Farthing, nature, 2000, 407, 361-364. 47. M. T. Yeung, R. Mohammadi and R. B. Kaner, Annual Review of Materials Research, 2016, 46, 465-485. 48. H. O. Pierson, Handbook of refractory carbides and nitrides: properties, characteristics, processing and applications, William Andrew, 1996. 49. P. H. Mayrhofer, D. Music and J. Schneider, Journal of Applied Physics, 2006, 100. 50. E. Rudy, Ternary Phase Equilibria in Transition Metal-Boron-Carbon-Silicon Systems. Part 2. Ternary Systems. Volume 18. Constitution of Niobium-Tungsten-Carbon Alloys, 1969. 51. M. Zarinejad, Y. Tong, M. Salehi, C. Mu, N. Wang, Y. Xu, S. Rimaz, L. Tian, K. X. Kuah and X. Chen, Crystals, 2024, 14, 665. 52. H.-Y. Chung, M. B. Weinberger, J. B. Levine, A. Kavner, J.-M. Yang, S. H. Tolbert and R. B. Kaner, Science, 2007, 316, 436-439. 53. C. Gu, Y. Liang, X. Zhou, J. Chen, D. Ma, J. Qin, W. Zhang, Q. Zhang, L. L. Daemen and Y. Zhao, Physical Review B, 2021, 104, 014110. 54. Q. Li, D. Zhou, W. Zheng, Y. Ma and C. Chen, Physical Review Letters, 2013, 110, 136403. 55. C. Gu, X. Zhou, D. Ma, Y. Zhao and S. Wang, Inorganic Chemistry, 2022, 61, 18193-18200. 56. X. Liu, M. Cao, J. Wen and Y. Gong, ACS Sustainable Chemistry & Engineering, 2024, 12, 17460-17467. 57. S. Sun, D. Yuan, Y. Xu, A. Wang and Z. Deng, ACS nano, 2016, 10, 3648-3657. 58. F. Haydous, J. M. Gardner and U. B. Cappel, Journal of Materials Chemistry A, 2021, 9, 23419-23443. 59. J. Cho, Data in Brief, 2022, 41, 107997. 60. A. Kojima, K. Teshima, Y. Shirai and T. Miyasaka, Journal of the american chemical society, 2009, 131, 6050-6051. 61. Q. A. Akkerman, G. Rainò, M. V. Kovalenko and L. Manna, Nature materials, 2018, 17, 394-405. 62. Y. Zhang, D. Tu, L. Wang, C. Li, Y. Liu and X. Chen, Materials Chemistry Frontiers, 2024, 8, 192-209. 63. H. Wang and D. H. Kim, Chemical Society Reviews, 2017, 46, 5204-5236. 64. R. Yang, D. Yang and S. F. Liu, Chemical Reviews, 2026. 65. L. Zhang, X. Yang, Q. Jiang, P. Wang, Z. Yin, X. Zhang, H. Tan, Y. Yang, M. Wei and B. R. Sutherland, Nature communications, 2017, 8, 15640. 66. H. Wang, Y. Wu, M. Ma, S. Dong, Q. Li, J. Du, H. Zhang and Q. Xu, ACS Applied Energy Materials, 2019, 2, 2305-2312. 67. P. Pandey and D.-W. Kang, Electronics, 2025, 14, 3171. 68. P. De Padova, C. Ottaviani, B. Olivieri, Y. P. Ivanov, G. Divitini and A. Di Carlo, Scientific Reports, 2024, 14, 23618. 69. Z. Tao, Y. Song, B. Wang, G. Tong and L. Ding, Journal of Semiconductors, 2024, 45, 040201-040201-040201-040204. 70. V. Nicolosi, M. Chhowalla, M. G. Kanatzidis, M. S. Strano and J. N. Coleman, Science, 2013, 340, 1226419. 71. A. Burgos-Caminal, E. Socie, M. E. Bouduban and J.-E. Moser, The journal of physical chemistry letters, 2020, 11, 7692-7701. 72. M. R. Leyden, L. K. Ono, S. R. Raga, Y. Kato, S. Wang and Y. Qi, Journal of Materials Chemistry A, 2014, 2, 18742-18745. 73. H. Huang, Q. Xue, B. Chen, Y. Xiong, J. Schneider, C. Zhi, H. Zhong and A. L. Rogach, Angewandte Chemie, 2017, 129, 9699-9704. 74. M. L. Fajri, N. Kossowski, I. Bouanane, F. Bedu, P. Poungsripong, R. Juliano-Martins, C. Majorel, O. Margeat, J. Le Rouzo and P. Genevet, ACS nano, 2024, 18, 26088-26102. 75. J. Stryckers, L. D'Olieslaeger, J. Silvano, C. Apolinario, A. Laranjeiro, J. Gruber, J. D'Haen, J. Manca, A. Ethirajan and W. Deferme, physica status solidi (a), 2016, 213, 1441-1446. 76. Y. Nagaoka, K. Hills‐Kimball, R. Tan, R. Li, Z. Wang and O. Chen, Advanced materials, 2017, 29, 1606666. 77. Z. Liang, S. Zhao, Z. Xu, B. Qiao, P. Song, D. Gao and X. Xu, ACS applied materials & interfaces, 2016, 8, 28824-28830. 78. S. Ullah, J. Wang, P. Yang, L. Liu, S. Yang, T. Xia, H. Guo and Y. Chen, Adv, 2021, 2, 646-683. 79. S. Akhil, V. V. Dutt and N. Mishra, Nanoscale Advances, 2021, 3, 2547-2553. 80. C. Zuo, A. D. Scully, W. L. Tan, F. Zheng, K. P. Ghiggino, D. Vak, H. Weerasinghe, C. R. McNeill, D. Angmo and A. S. Chesman, Communications Materials, 2020, 1, 33. 81. N. J. Jeon, J. H. Noh, Y. C. Kim, W. S. Yang, S. Ryu and S. I. Seok, Nature materials, 2014, 13, 897-903. 82. L. Lu, S. Zou and B. Fang, Acs Catalysis, 2021, 11, 6020-6058. 83. L. Xu, J. Li, T. Fang, Y. Zhao, S. Yuan, Y. Dong and J. Song, Nanoscale Advances, 2019, 1, 980-988. 84. J. Zhang, J. He, L. Yang and Z. Gan, Molecules, 2020, 25, 1151. 85. S. Xiong, F. Tian, F. Wang, A. Cao, Z. Chen, S. Jiang, D. Li, B. Xu, H. Wu and Y. Zhang, Nature Communications, 2024, 15, 5607. 86. S. Kahmann, E. K. Tekelenburg, H. Duim, M. E. Kamminga and M. A. Loi, Nature communications, 2020, 11, 2344. 87. H. Zheng and J. Dai, Materials Letters, 2017, 188, 232-234. 88. M. I. Dar, G. Jacopin, S. Meloni, A. Mattoni, N. Arora, A. Boziki, S. M. Zakeeruddin, U. Rothlisberger and M. Grätzel, Science advances, 2016, 2, e1601156. 89. S. Wang, J. Ma, W. Li, J. Wang, H. Wang, H. Shen, J. Li, J. Wang, H. Luo and D. Li, The journal of physical chemistry letters, 2019, 10, 2546-2553. 90. E. V. Péan, S. Dimitrov, C. S. De Castro and M. L. Davies, Physical Chemistry Chemical Physics, 2020, 22, 28345-28358. 91. Y.-H. Chen, K.-A. Tsai, T.-W. Liu, Y.-J. Chang, Y.-C. Wei, M.-W. Zheng, S.-H. Liu, M.-Y. Liao, P.-Y. Sie and J.-H. Lin, The Journal of Physical Chemistry Letters, 2022, 14, 122-131. 92. J. M. Cleveland, T. A. Welsch, E. Y. Chen, D. B. Chase, M. F. Doty and H. Y. Ramírez-Gómez, The Journal of Physical Chemistry C, 2025, 129, 5893-5904. 93. M. R. Subramaniam, A. K. Pramod, S. A. Hevia and S. K. Batabyal, The Journal of Physical Chemistry C, 2022, 126, 1462-1470. 94. H. Huang, B. Chen, Z. Wang, T. F. Hung, A. S. Susha, H. Zhong and A. L. Rogach, Chemical science, 2016, 7, 5699-5703. 95. J. George, A. P. Joseph and M. Balachandran, International Journal of Energy Research, 2022, 46, 21856-21883. 96. K. Bienkowski, R. Solarska, L. Trinh, J. Widera-Kalinowska, B. Al-Anesi, M. Liu, G. K. Grandhi, P. Vivo, B. Oral and B. Yılmaz, ACS catalysis, 2024, 14, 6603-6622. 97. V. Kumar, S. K. Patel, V. Vyas, D. Kumar, E. S. S. Iyer and A. Indra, Chemical Science, 2024, 15, 13218-13226. 98. G. F. Samu, R. A. Scheidt, P. V. Kamat and C. Janáky, Chemistry of Materials, 2018, 30, 561-569. 99. B. Roose, K. Dey, M. R. Fitzsimmons, Y.-H. Chiang, P. J. Cameron and S. D. Stranks, ACS Energy Letters, 2024, 9, 442-453. 100. R. Ollearo, J. Wang, M. J. Dyson, C. H. Weijtens, M. Fattori, B. T. Van Gorkom, A. J. Van Breemen, S. C. Meskers, R. A. Janssen and G. H. Gelinck, Nature communications, 2021, 12, 7277. 101. R. Hawrami, L. Matei, E. Ariesanti, V. Buliga, H. Parkhe, A. Burger, J. Stewart, A. Piro, F. De Figueiredo and A. Kargar, Materials, 2024, 17, 5360. 102. K. Vijayan, Y.-X. Chen, P. K. Chand, T.-C. Huang, Y.-P. Hsieh and M. Hofmann, Nanoscale Horizons, 2025. 103. P.-N. Tran, B.-D. Tran, D.-C. Nguyen, T.-L. Nguyen, V.-D. Tran and T.-T. Duong, Crystals, 2022, 12, 587. 104. J. Ding, S. Du, Z. Zuo, Y. Zhao, H. Cui and X. Zhan, The Journal of Physical Chemistry C, 2017, 121, 4917-4923. 105. X. Li, D. Yu, F. Cao, Y. Gu, Y. Wei, Y. Wu, J. Song and H. Zeng, Advanced Functional Materials, 2016, 26, 5903-5912. 106. Y. Dong, Y. Gu, Y. Zou, J. Song, L. Xu, J. Li, J. Xue, X. Li and H. Zeng, Small, 2016, 12, 5622-5632. 107. D. K. Jarwal, N. Jingar, M. Kulhar, R. Kumar and A. Bera, Sensors and Actuators A: Physical, 2024, 374, 115451. 108. N. Jiang, J. Wei, M. Lv, Y. Rong, C. Wang, Y. Liu, G. Wei, X. Han, Y. Wang and Y. Liu, Journal of Materials Chemistry C, 2023, 11, 6046-6056. 109. H. Zhou, Z. Song, C. R. Grice, C. Chen, J. Zhang, Y. Zhu, R. Liu, H. Wang and Y. Yan, Nano Energy, 2018, 53, 880-886. 110. Y. Li, Z.-F. Shi, S. Li, L.-Z. Lei, H.-F. Ji, D. Wu, T.-T. Xu, Y.-T. Tian and X.-J. Li, Journal of Materials Chemistry C, 2017, 5, 8355-8360. 111. A. Suhail, A. Saini, S. Beniwal and M. Bag, The Journal of Physical Chemistry C, 2023, 127, 17298-17306. 112. H. Zhou, J. Zeng, Z. Song, C. R. Grice, C. Chen, Z. Song, D. Zhao, H. Wang and Y. Yan, The journal of physical chemistry letters, 2018, 9, 2043-2048. 113. C. Bao, Z. Chen, Y. Fang, H. Wei, Y. Deng, X. Xiao, L. Li and J. Huang, Advanced materials, 2017, 29, 1703209. 114. K. M. Sim, A. Swarnkar, A. Nag and D. S. Chung, Laser & Photonics Reviews, 2018, 12, 1700209. 115. Z. Sun, Y. Wang, Y. Liu, R. Liu, T. Chen, S. Ye, N. Lai, H. Cui, F. Lin and R. Wang, ACS Applied Nano Materials, 2024, 7, 11785-11793. 116. H. Tao, H. Wang, Y. Bai, H. Zhao, Q. Fu, Z. Ma and H. Long, Journal of Materials Chemistry C, 2020, 8, 6228-6235. 117. L. Ji, H.-Y. Hsu, J. C. Lee, A. J. Bard and E. T. Yu, Nano letters, 2018, 18, 994-1000. 118. H.-J. Kim, H. Oh, T. Kim, D. Kim and M. Park, ACS Applied Nano Materials, 2022, 5, 1308-1316. 119. M. T. Hossain, M. Das, J. Ghosh, S. Ghosh and P. Giri, Nanoscale, 2021, 13, 14945-14959. 120. J. Wang, J. Zhang, Y. Zhou, H. Liu, Q. Xue, X. Li, C.-C. Chueh, H.-L. Yip, Z. Zhu and A. K. Jen, Nature communications, 2020, 11, 177. 121. Y. Zhao, S. Jiao, S. Liu, Y. Jin, S. Yang, X. Wang, T. Liu, H. Jin, D. Wang and S. Gao, Journal of Alloys and Compounds, 2023, 965, 171434. 122. S. K. Gupta and Y. Mao, Progress in Materials Science, 2021, 117, 100734. 123. X. Liu, N. Fechler and M. Antonietti, Chemical Society Reviews, 2013, 42, 8237-8265. 124. R. Roper, M. Harkema, P. Sabharwall, C. Riddle, B. Chisholm, B. Day and P. Marotta, Annals of Nuclear Energy, 2022, 169, 108924. 125. P. V. Huong, Materials Letters, 1992, 14, 80-82. 126. L. Wang, Z. Zhai and L. Li, Micromachines, 2024, 15, 785. 127. E. Bykova, S. V. Ovsyannikov, M. Bykov, Y. Yin, T. Fedotenko, H. Holz, S. Gabel, B. Merle, S. Chariton and V. B. Prakapenka, Journal of Materials Chemistry A, 2022, 10, 20111-20120. 128. H.-T. Chin, D.-C. Wang, D. P. Gulo, Y.-C. Yao, H.-C. Yeh, J. Muthu, D.-R. Chen, T.-C. Kao, M. Kalbac and P.-H. Lin, Nano Letters, 2023, 24, 67-73. | - |
| dc.identifier.uri | http://tdr.lib.ntu.edu.tw/jspui/handle/123456789/101739 | - |
| dc.description.abstract | 奈米結構因其獨特的電子、光學及催化特性,長期以來備受研究人員關注。為了精準調控這些特性,結構的精密控制至關重要,然而這對於現有的合成方法而言仍是一大挑戰。本論文探討了在奈米結構生長完成後,進一步修飾其性質的相關策略。
首先,我們提出了一種 液對液撞擊技術(liquid-in-liquid impingement technique),能有效增加鈣鈦礦奈米立方體的晶體尺寸。儘管鈣鈦礦奈米立方體展現出強大的光電交互作用與可調控的電子特性,但通常面臨缺陷密度高、結晶性不佳及光電性能退化等問題。現有依賴聚合物基質或熱退火(thermal annealing)的後處理策略,雖能減少奈米立方體表面的負面影響,卻往往需付出高熱預算 的代價,並可能損害成分的完整性。我們的方法則是透過受控的撞擊,經由剪切力驅動的頸縮現象(shear-driven necking)將粒子合併為連續的薄片。顯微鑑定分析證實,其核心機制為燒結作用(sintering);光譜與電化學測量亦顯示,生成的薄片具有更少的缺陷、更高的穩定性以及更優異的性能。 其次,我們介紹了一種調控二維材料特性的通用方法。透過將「雷射輔助熔鹽合成」與「電化學調控」相結合,有望達成對難熔材料(refractory materials)之相組成、形貌及氧化態的精準控制。我們將此雷射熔鹽平台應用於非凡德瓦力結合的二維固體——氮化鎢之轉化,生成可作為催化劑及功能材料並應用於電子與電化學元件的鎢化合物。這種結合策略為建構具備精密結構與化學屬性的複雜無機化合物,提供了一條強而有力的路徑。 | zh_TW |
| dc.description.abstract | Nanostructures have captured the attention of researchers due to their unique electronic, optical, and catalytic properties. To tailor these properties, precise structural control is required, that has proven challenging for established synthesis approaches. This thesis explores strategies to modify the properties of nanostructures after growth.
First, we introduce a liquid in liquid impingement technique that enhances the crystal dimension of perovskite nanocubes. While perovskite nanocubes have demonstrated strong light-matter interaction and tunable electronic properties, they typically suffer from high defect densities, poor crystallinity, and degraded optoelectronic performance. Post-treatment strategies that rely on polymer matrices or thermal annealing have decreased the contribution of nanocube surfaces, but at the cost of high thermal budget and compromised compositional integrity. Our method relies on controlled impingement through shear-driven necking, merging the particles into continuous flakes. Microscopic characterization confirms the occurrence of sintering as the underlying mechanism, and spectroscopic and electrochemical measurements confirm that the resulting flakes possess fewer defects, enhanced stability, and superior performance. Second, we describe a versatile approach to modify the properties of two-dimensional materials. The combination of laser-assisted molten salt synthesis with electrochemical regulation promises precise control over phase composition, morphology, and oxidation state of refractory materials. We apply the laser-molten salt platform to the conversion of tungsten nitride, a non-van-der-Waals 2D solid, to tungsten compounds that can function as catalysts and functional materials for electronic and electrochemical devices. This combined strategy offers a powerful route for engineering complex inorganic compounds with precise structural and chemical attributes. | en |
| dc.description.provenance | Submitted by admin ntu (admin@lib.ntu.edu.tw) on 2026-03-04T16:11:15Z No. of bitstreams: 0 | en |
| dc.description.provenance | Made available in DSpace on 2026-03-04T16:11:15Z (GMT). No. of bitstreams: 0 | en |
| dc.description.tableofcontents | Doctoral dissertation acceptance certificate………………………………………………..i
Acknowledgements………………………………………………………………………..ii 中文摘要…………………………………………………………………………………iii Abstract (English)………………………………………………………………………....v Publication…………………………………………………………………………….....vii Table of Contents………………………………………………………………………..viii List of Figures……………………………………………………………………….…..xiv Chapter 1. Introduction 1.1 Introduction ……………………………………………………………………...…....1 1.2 Background and Motivation …………………………………………………………..2 1.3 Metal Halide Perovskite Nanocrystals…………….…………………………………...2 1.4 Interfacial Assembly and Sintering…………………………………………………… 4 1.5 Novel Electrochemical Molten Salt Reactions ………………………………………. 4 1.6 Research gaps and Objectives …………………………………………….................. 5 Chapter 2. Literature Review 2.1 Chapter Overview …………………….…………………...…………………………. 7 2.2 Perovskite Nanocrystals for Optoelectronics 2.2.1 Perovskites………………….…………………...………………………….. 7 2.2.2 Metal Halide Perovskites ……………………………………………………9 2.2.3 Inorganic Perovskites – CsPbBr3 …………………………………………..10 2.2.4 Synthesis and Stabilization of Perovskite Nanocrystals ...……………….....10 2.2.5 Interface Engineering for High-Performance Optoelectronic Devices..…...12 2.2.6 Limitations in the Current State-of-the-Art… …………………….............. 13 2.3 Laser -Assisted Electrochemical Molten Salt Synthesis 2.3.1 Introduction to Molten Salt Synthesis (MSS)………………………........... 14 2.3.2 Laser-Assisted Transformations in Material Engineering………………… 15 2.3.3 Electrochemical Deposition Methods……………………………............... 15 2.3.4 Tungsten Nitrides and Borides: Structure and Properties ………………… 16 2.3.5 Current Limitations and Challenges……………………………................. 17 2.4 Summary of Literature Review……………………................................................... 18 Chapter 3. Experimental Methods 3.1 Chapter Overview…………………...……………….………………........................ 20 3.2 Materials and Methods 3.2.1 Preparation of Cs-Oleate…………………........………………...………… 21 3.2.2 Synthesis of CsPbBr3 Nanocubes……………….......................................... 21 3.2.3 Synthesis of Sintered Perovskite Flakes…………………............................ 22 3.2.4 Preparation of Electric Measurements……………………………….......... 24 3.2.5 Electrochemical Measurements of Perovskite Flakes…………………...... 24 3.3 Electrochemical Molten Salt Synthesis Using Laser 3.3.1 Synthesis of Tungsten Nitride………………….......................................... 25 3.3.2 Preparation of Flux Materials……………………....................................... 26 3.3.3 Preparation of the Laser-Assisted Electrochemical MSS setup …………... 27 3.3.4 Laser Irradiation Parameters………………………..................................... 27 3.4 Material Characterization Techniques 3.4.1 Scanning Electron Microscopy and Energy-Dispersive Spectroscopy……..28 3.4.2 Transmission electron Microscopy………….……….................................. 30 3.4.3 Fourier Transform Infrared Spectroscopy…………………………............ 31 3.4.4 Photoluminescence………………………...…………………………........ 32 3.4.5 Temperature-Dependent Photoluminescence…………………................... 33 3.4.6 Time-Resolved Photoluminescence…………………................................. 34 3.4.7 Raman Spectroscopy……………………….........…………………………34 3.4.8 Cyclic Voltammetry……………………….........………………………….35 3.4.9 Electrochemical Impedance Spectroscopy…………………....................... 36 Chapter 4. Solution-Based Sintering of Perovskite Nanoparticles for High-Performance Optoelectronics 4.1 Chapter Overview……………………….........…………………............................... 37 4.2 Introduction……………………….........……………………….................................38 4.3 Materials and Methods 4.3.1 Materials Used………………………........………………………….......... 41 4.3.2 Nanocube synthesis……………………….........……….………………….41 4.3.3 Mechanocoalesced Flake Synthesis………………………………...............42 4.4 Results and Discussion……………………….........…………………………........... 43 4.5 Conclusion and Future Work….........………………………...................................... 57 4.6 Future Work………………….........………………………........................................ 58 Chapter 5. Conversion of Tungsten Borides from Tungsten Nitrides Using Laser-Assisted Electrochemical Molten Salt Reactions 5.1 Chapter Overview…………………...........………………………............................. 59 5.2 Introduction and Motivation…………………...........…………………………….… 59 5.3 Materials and Methods 5.3.1 Experimental Setup…………………........................................................... 61 5.4 Results………………………...……………………….............................................. 64 5.5 Tungsten Nitride System……….…………...........………………………………..... 71 5.5.1 W5N6 Reactions on Copper Foil………………………................................72 5.5.2 Transfer of W5N6 for Raman Measurements……………………………..... 73 5.5.3 Raman and SEM Analysis of Transferred W5N6 …………………..……… 74 5.5.4 Electrode Structure for Laser-Assisted Electrochemical MSR………….….74 5.5.5 Preliminary Results………………………................................................... 75 5.6 Conclusion………………...........………………………............................................ 78 5.7 Future Outlook………………………........…………………..................................... 79 Chapter 6. Conclusion and Future Outlook 6.1 Conclusion………………………...........…………….………………....................... 81 6.2 Overall Future Outlook………………………...........…………………….……….... 83 References ………………………...........………………………................................................. 86 | - |
| dc.language.iso | en | - |
| dc.subject | 奈米結構 | - |
| dc.subject | 鈣鈦礦 | - |
| dc.subject | 液對液撞擊 | - |
| dc.subject | 剪切梯度 | - |
| dc.subject | 界面壓力驅動燒結 | - |
| dc.subject | 機械力誘導合併 | - |
| dc.subject | 光電性能 | - |
| dc.subject | 熔鹽合成法 (MSS) | - |
| dc.subject | 熔鹽反應 (MSR) | - |
| dc.subject | 電化學合成 | - |
| dc.subject | 雷射輔助電化學熔鹽反應 | - |
| dc.subject | 硼化鎢 | - |
| dc.subject | 結構修飾 / 結構調控 | - |
| dc.subject | 元件整合 | - |
| dc.subject | Nanostructures | - |
| dc.subject | Perovskite | - |
| dc.subject | Liquid-in-liquid impingement | - |
| dc.subject | Shear gradient | - |
| dc.subject | Interfacial pressure-driven sintering | - |
| dc.subject | Mechanocoalescence | - |
| dc.subject | Optoelectronic performance | - |
| dc.subject | Molten salt synthesis | - |
| dc.subject | Molten salt reaction (MSR) | - |
| dc.subject | Electrochemical synthesis | - |
| dc.subject | Laser-assisted electrochemical MSR | - |
| dc.subject | Tungsten borides | - |
| dc.subject | Structural modification | - |
| dc.subject | Device integration | - |
| dc.title | 奈米結構之介面工程邁向高效能光電元件 | zh_TW |
| dc.title | Interface Engineering of Nanoscale Structures Toward Enhanced Opto-Electronic Devices | en |
| dc.type | Thesis | - |
| dc.date.schoolyear | 114-1 | - |
| dc.description.degree | 博士 | - |
| dc.contributor.coadvisor | 謝雅萍 | zh_TW |
| dc.contributor.coadvisor | Ya-Ping Hsieh | en |
| dc.contributor.oralexamcommittee | 陳永芳;蔡孟霖;趙宇強;王迪彥 | zh_TW |
| dc.contributor.oralexamcommittee | Yang-Fang Chen;Meng-Lin Tsai;Yu-Chiang Chao;Di-Yan Wang | en |
| dc.subject.keyword | 奈米結構,鈣鈦礦液對液撞擊剪切梯度界面壓力驅動燒結機械力誘導合併光電性能熔鹽合成法 (MSS)熔鹽反應 (MSR)電化學合成雷射輔助電化學熔鹽反應硼化鎢結構修飾 / 結構調控元件整合 | zh_TW |
| dc.subject.keyword | Nanostructures,PerovskiteLiquid-in-liquid impingementShear gradientInterfacial pressure-driven sinteringMechanocoalescenceOptoelectronic performanceMolten salt synthesisMolten salt reaction (MSR)Electrochemical synthesisLaser-assisted electrochemical MSRTungsten boridesStructural modificationDevice integration | en |
| dc.relation.page | 96 | - |
| dc.identifier.doi | 10.6342/NTU202600786 | - |
| dc.rights.note | 同意授權(限校園內公開) | - |
| dc.date.accepted | 2026-02-24 | - |
| dc.contributor.author-college | 理學院 | - |
| dc.contributor.author-dept | 物理學系 | - |
| dc.date.embargo-lift | 2031-02-23 | - |
| 顯示於系所單位: | 物理學系 | |
文件中的檔案:
| 檔案 | 大小 | 格式 | |
|---|---|---|---|
| ntu-114-1.pdf 未授權公開取用 | 4.08 MB | Adobe PDF | 檢視/開啟 |
系統中的文件,除了特別指名其著作權條款之外,均受到著作權保護,並且保留所有的權利。