Randi Azmi

助理教授

校长青年学者
教育背景

博士(韩国国民大学)

学士(印度尼西亚大学)

研究领域
钙钛矿半导体;异质结薄膜;下一代太阳能电池;太阳能和可再生能源
学术领域
新能源科学与工程,材料学,化学,物理
港中大(深圳)个人网站
https://myweb.cuhk.edu.cn/randiazmi
电子邮件
randiazmi@cuhk.edu.cn
个人简介

Randi Azmi教授于2014年在印度尼西亚大学获得凝聚态物理学学士学位,于2020年在韩国国民大学获得应用纳米化学博士学位。在加入香港中文大学(深圳)之前,Randi Azmi教授在阿卜杜拉国王科技大学(KAUST)太阳能中心担任博士后研究员(2020-2024年)。

Randi Azmi教授的研究团队——可再生能源异质结材料实验室(HEROLAB)专注于研究高效有机和无机混合异质结薄膜太阳能电池、单结和多结太阳能电池,旨在开发下一代高效且稳定的太阳能电池技术。该团队的研究工作跨越多个学科,从新型材料到器件制造,包括优化工艺流程和材料,以及在真实工作环境中对太阳能电池进行评估,以将它们推进至工业应用水平;研究团队还与光伏相关企业合作,以提升可扩展钙钛矿组件的性能和稳定性。

迄今为止,Azmi教授已在Science(4篇)、Nature(2篇)、Joule(3篇)、Nature Communications(2篇)、Advanced Materials(2篇)、Advanced  Energy Materials(7篇)以及ACS Energy Letters(7篇)等知名期刊发表论文超过45篇(h指数=30,引用次数4300+)。2022年,他因在科学、技术与创新方面的杰出贡献,荣获东盟青年科学家奖。近期,他荣获国家级人才项目及2024年深圳市市级人才项目,他的研究亦荣获国家自然科学基金委员会资助。

学术著作

Selected Publications (Co-first # or Corresponding authorship*)

  1. R. Azmi*; E. Ugur; biah; J. Liu; G. T. Harisson; A. Seitkhan; F. Aljamaan; A. S. Sub M. I. Nugraha; M. K. Eswaran; M. Babic; Y. Chen; F. Xu; T. G. Allen; A. U. Rehman, C.-L. Wang; T. D. Anthopoulos; U. Schwingenschlögl; M. D. Bastiani; E. Aydin; S. D. Wolf*. Damp heat–stable perovskite solar cells with tailored-dimensionality 2D/3D heterojunctions. Science. 376, 73-77 (2022). (IF: 63.7, JCR Q1, Favourite innovation research in 2022 from physicsworld.com, ESI highly cited paper and hot paper, https://www.science.org/doi/full/10.1126/science.abm5784)
  2. R. Azmi*; D. S. Utomo; B. Vishal; S. Zhumagali; P. Dally; A. M. Risqi; A. Prasetio; C. Faofao; Imil F. Imran; A. A. Said; E. Ugur; A. S. Subbiah; E. Aydin; C. Xiao; S. I. Seok; S. D. Wolf. Double-side 2D/3D heterojunctions for inverted perovskite solar cells. Nature 628, 93–98 (2024). (IF: 69.5, JCR Q1, ESI highly cited paper and hot paper, https://doi.org/10.1038/s41586-024-07189-3)
  3. R. Azmi*; D. S. Utomo, Y. Liu, S. Zhumagali, S. D. Wolf. Dimensionality engineering of perovskites for stable heterojunction-based photovoltaics. Nature Reviews Materials (2025). (Invited, IF: 86.2, JCR Q1, https://doi.org/10.1038/s41578-025-00847-6)
  4. X. Chang#, R. Azmi#, T. Yang, N. Wu, S. Y. Jeong, H. Xi, D. S. Utomo, B. Vishal, F. H Isikgor, H. Faber, Z. Ling, M.He, M. Marengo, P. Dally, A. Prasetio, Y.-Y. Yang, C. Xiao, H. Y. Woo, K. Zhao, M. Heeney, S. D. Wolf, L. Tsetseris, T. D. Anthopoulos. Solvent-dripping modulated 3D/2D heterostructures for high-performance perovskite solar cells. Nature Communication.  16, 1042 (2025) (IF: 14.7, JCR Q1, https://doi.org/10.1038/s41467-025-56409-5)
  5. A. Hassan, M. I. Syauqi, Y. Liu, Z. Ke, W. Lin, Z. Wang, Y. Jin, R. Azmi*. Unveiling the potential of flexible perovskite photovoltaics: From lab to fab. Materials Science and Engineering: R: Reports 166, 101023 (2025). (IF: 33.1, JCR Q1, https://doi.org/10.1016/j.mser.2025.101023)
  6. R. Azmi*; S. Zhumagali; H. Bristow; An. R. Pininti; S. Zhang; A. Yazmaciyan; D. S. Utomo; A. S. Subbiah; S. D. Wolf. Moisture-Resilient Perovskite Solar Cells for Enhanced Stability. Advanced Materials 36, 12, 2211317 (2024). (IF: 32.1, JCR Q1, https://doi.org/10.1002/adma.202211317)
  7. D. S. Utomo, L. M. Svirskaite, A. Prasetio, V. Malinauskiene, V. Getautis, E. Aydin, T. Malinauskas, R. Azmi*, S. D. Wolf., N-type self-assembled monolayers as electronselective contacts for n-i-p perovskite solar cells. ACS Energy Lett., 9, 4, 1682–1692 (2024). (IF: 23.9, JCR Q1, https://pubs.acs.org/doi/full/10.1021/acsenergylett.4c00306)
  8. T. Amrillah; A. Prasetio; A. R. Supandi; D. H. Sidiq; F. S. Putra; M. A. Nugroho; Z. Salsabilla; R. Azmi*. Environment-friendly copper-based chalcogenide thin film solar cells: status and perspectives. Materials Horizons, 10, 313-339 (2023). (IF: 15.7, JCR Q1, DOI: 10.1039/D2MH00983H)
  9. G. Y.Yoo#; R. Azmi#, C. Kim; W. Kim; B. K. Min; S.-Y. Jang; Y. R. Do. Stable and Colorful Perovskite Solar Cells Using a Nonperiodic SiO2/TiO2 Multi-Nanolayer Filter. ACS Nano, 13, 10129 10139 (2019). (IF: 18.0, JCR Q1, https://doi.org/10.1021/acsnano.9b03098)
  10. R. Azmi; N. Nurrosyid; S.-H. Lee; M. A. Mubarak; W. Lee; S. Hwang; W. Yin; T. K. Ahn; T.-W. Kim; D. Y. Ryu; Y. R. Do; S.-Y. Jang. Shallow and deep trap state passivation for low-temperature processed perovskite solar cells. ACS Energy Lett. 5, 1396-1403 (2020). (IF: 23.99, JCR Q1, https://doi.org/10.1021/acsenergylett.0c00596)
  11. R. Azmi; W. T. Hadmojo; S. Sinaga; C.-L. Lee; S. C. Yoon; I. H. Jung; S.-Y. Jang. High‐efficiency low‐temperature ZnO based perovskite solar cells based on highly polar, nonwetting self‐assembled molecular layers. Adv. Energy Mater., 8, 5, 1701683 (2018). (IF: 29.7, JCR Q1, Selected as Back Cover, https://onlinelibrary.wiley.com/doi/full/10.1002/aenm.201701683)
  12. E. Aydin; E. Ughur; B. K. Yildirim; T. G. Allen; P. Dally; A. Razzaq; F. Cao; L. Xu; B. Vishal; A. Yazmaciyan; A. A. Said; S. Zhumagali; R. Azmi; M. Babaics; A. Fell; C. Xiao; S. D. Wolf. Monolithic perovskite/silicon tandem solar cell with energetically homogenized interconnection. Nature 623, 7988, 732-738 (2023). (IF: 69.5, JCR Q1, ESI highly cited paper and hot paper, https://www.nature.com/articles/s41586-023-06667-4)
  13. Z. Xu; H. Bristow; M. Babics; B. Vishal; E. Aydin; R. Azmi; E. Ugur; B. K. Yildirim; J. Liu; R. A. Kerner; S. D. Wolf; B. P. Rand. Silicon subcells afford reverse bias protection in monolithic perovskite/silicon tandem solar cells. Joule, 7, 9, 1992-2002 (2023). (IF: 46, JCR Q1, https://doi.org/10.1016/j.joule.2023.07.017)
  14. E. Aydin; J. Liu; E. Ugur; R. Azmi; G. T. Harrison; Y. Hou; B. Chen; S. Zhumagali; M. D. Bastiani; M. Wang; W. Raja; T. G. Allen; A. U. Rehman; A. S. Subbiah; M. Babics; A. Babayigit; F. H. Isikgor; K. Wang; E. V. Kerschaver; L. Tsetseris; E. H. Sargent; F. Laquai; S. D. Wolf. Ligand-bridged charge extraction and enhanced quantum efficiency enable efficient n–i–p perovskite/silicon tandem solar cells. Energy & Environ. Sci., 14, 4377-4390 (2021). (IF: 39.7, JCR Q1, DOI: 10.1039/D1EE01206A)
  15. J. Liu; M. D. Bastiani; E. Aydin; Y. Gao; G. T. Harrison; A. Seitkhan; M. Babics; A. S. Subbiah; W. Yan; F. Xu; L. Xu; E. Ugur; A. U. Rehman; A. Razzaq; R. Azmi; F. H. Isikgor; T. G. Allen; F. Laquai; S. D. Wolf. Efficient and stable perovskite-silicon tandem solar cells through contact displacement by MgFx. Science, 377, 302-306 (2022). (IF: 63.7, JCR Q1, ESI highly cited paper, https://www.science.org/doi/full/10.1126/science.abn8910)
  16. A. A. Said; E. Aydin; E. Ugur; Z. Xu; C. Deger; B. Vishal; A. Vlk; P. Dally; B. K. Yildirim; R. Azmi; J. Liu; E. A. Jackson; H. M. Johnson; M. Gui; H. Richter; A. R. Pininti; H. Bristow; M. Babics; A. Razzaq;T. G. Allen; M. Ledinský; I. Yavuz; B. P. Rand; S. D. Wolf. Sublimed C60 for efficient and repeatable perovskite-based solar cells. Nature Communication.  15, 708 (2024) (IF: 14.7, JCR Q1, ESI highly cited paper, https://www.nature.com/articles/s41467-024-44974-0)
  17. A. R. Pininti, A. S. Subbiah, C. Deger, I. Yavuz, A. Prasetio, P. Dally, V. Hnapovskyi, A. A. Said, L. V. T. Merino, S. Mannar, S. Zhumagali, B. Vishal, M. Marengo, A. Razzaq, M. Babics, T. G. Allen, E. Aydin, R. Azmi, S. D. Wolf. Resolving Scaling Issues in Self‐Assembled Monolayer‐Based Perovskite Solar Modules via Additive Engineering. Adv. Energy Mater., 15, 7, 2403530 (2025). (IF: 29.7, JCR Q1, https://advanced.onlinelibrary.wiley.com/doi/full/10.1002/aenm.202403530 )
  18. Z. Wang, Q. Liang, M. Li, G. Sun, S. Li, T. Zhu, Y. Han, H. Xia, Z. Ren, B. Yu, J. Zhang, R. Ma, H. T. Chandran, L. Cheng, L. Zhang, D. Li, S. Chen, X. Lu, C. Yan, R. Azmi, K. Liu, J. Tang, G. Li. Buried Interface Regulation with a Supramolecular Assembled Template Enables High‐Performance Perovskite Solar Cells for Minimizing the VOC Deficit. Advanced Materials 37, 24, 2418011 (2025). (IF: 32.1, JCR Q1, https://doi.org/10.1002/adma.202418011)
  19. A. S. Subbiah, S. Mannar, V. Hnapovskyi, A. R. Pininti, B. Vishal, L. V. T. Merino, O. Matiash, O. Karalis, H. Hempel, A. Prasetio, B. Y., P. Dally, D. R. Villalva, M. Babics, L. Xu, A. Razzaq, R. Azmi, F. Xu, H. L. Bristow, E. Ugur, A. U. Rehman, H. Pasanen, E. Aydin, T. Allen, D. Baran, T. Unold, F. Laquai, S. D. Wolf. Efficient blade-coated perovskite/silicon tandems via interface engineering. Joule. 9, 101767 (2025) (IF: 46, JCR Q1, ESI highly cited paper, https://www.cell.com/joule/abstract/S2542-4351(24)00432-X )

  20. O. E.-Raji, C. Messmer, R. R. Pradhan, O. Fischer, V. Hnapovskyi, S. Kosar, M. Marengo, M. List, J. Faisst, J. P. Jurado, O. Matiash, H. P. Pasanen, A. Prasetio, B. Vishal, S. Zhumagali, A. R. Pininti, Y. Gupta, C. Baretzky, E. Ugur, C. E. Petoukhoff, M. Bivour, E. Aydin, R. Azmi, J. Schön, F. Schindler, M. C. Schubert, U. Schwingenschlögl, F. Laquai, A. A Said, J. Borchert, P. SC Schulze, S. D. Wolf, S. W. Glunz, Electron accumulation across the perovskite layer enhances tandem solar cells with textured silicon. Science, eadx1745 (2025) (IF: 63.7, JCR Q1, https://www.science.org/doi/full/10.1126/science.adx1745 )