Publications
Here you will find research Research papers enabled by Fluxim’s development tools
Research Paper: Switching From Acceptor to FRET Donor: How the Organic Solar Cell Architecture Can Change the Role of a Chromophore
Jin, H., Mallo, N., Zhang, G., Lindsay, O., Chu, R., Gao, M., McAnally, S., Etchells, I.M., Burn, P.L., Gentle, I.R. and Shaw, P.E. (2025), Switching From Acceptor to FRET Donor: How the Organic Solar Cell Architecture Can Change the Role of a Chromophore. Adv. Funct. Mater.,
Research Paper: Equivalent-circuit modeling of electron-hole recombination in semiconductors and mixed ionic-electronic conductors
Moia, D. (2025), Equivalent-circuit modeling of electron-hole recombination in semiconductors and mixed ionic-electronic conductors. Physical Review Applied, 23: 014055.
Research Paper: Enlarging moment and regulating orientation of buried interfacial dipole for efficient inverted perovskite solar cells
Peng, Y., Chen, Y., Zhou, J., Luo, C., Tang, W., Duan, Y., Wu, Y. and Peng, Q. (2025), Enlarging moment and regulating orientation of buried interfacial dipole for efficient inverted perovskite solar cells. Nature Communications.
Research Paper: Coordination-Based Doping of MEH-PPV with La(TFSI)3 Enables Air-Free Conductivity 2 and Stable Performance in Perovskite Solar Cells
McPherson, Seth W. and Chou, Yeh-Chuan and Shin, Insoo and Maclean, Stephen A. and Li, Tai-De and Lin, Chieh-Ting and Kong, Jaemin and Rohr, Jason A. and Taylor, André D., Coordination-Based Doping of Meh-Ppv with La(Tfsi)3 Enables Air-Free Conductivity and Stable Performance in Perovskite Solar Cells.
Research Paper: Small Molecular Organic Hole Transport Layer for Efficient Inverted Perovskite Solar Cells
Ahmmed, S., Karim, M. A., He, Y., Cao, S., Kayesh, M. E., Matsuishi, K., & Islam, A. (2025). Small Molecular Organic Hole Transport Layer for Efficient Inverted Perovskite Solar Cells. Solar RRL, 7, e202500017.
Research paper: Bulk Passivation of Lead Halide Perovskites: The Key to High-Performance Indoor Photovoltaics at Very Low-Light Intensities
Karpiola, E., Grandhi, G.K., Doyranli, C., Han, Y., Alexander, A., Jagadamma, L.K., Tewari, A., Manna, D. and Vivo, P. (2025), Bulk Passivation of Lead Halide Perovskites: The Key to High‐Performance Indoor Photovoltaics at Very Low‐Light Intensities. Solar RRL, 11
Research Paper: Dopant-free hydrophobic fluorene-based HTMs with methoxy-triphenylamine and carbazole groups for improved perovskite solar cell performance
Bhat, V.G., Keremane, K.S., Subramanya, K.S., Archana, S., Hegde, A., Asuo, I.M., Poudel, B. and Dalimba, U.K. (2025), Dopant-free hydrophobic fluorene-based hole transport materials: impact of methoxy-substituted triphenylamine and carbazole peripheral groups on the performance of perovskite solar cells. Sustainable Energy Fuels, 9: 2769.
Research Paper: Visualising ionic screening in perovskite solar cells: a bumpy ride along the J–V curve
orre Cachafeiro, M.A., Narbey, S., Ruhstaller, B., Nüesch, F. and Tress, W. (2025), Visualising ionic screening in perovskite solar cells: a bumpy ride along the J–V curve. EES Solar.
Research Paper: Dicyandiamide‑Driven Tailoring of the n‑Value Distribution and Interface Dynamics for High‑Performance ACI 2D Perovskite Solar Cell
Chen, G., Gan, Y., Wang, S., Liu, X., Yang, J., Peng, S., Zhao, Y., Li, P., Komilov, A., Song, Y., Zhang, Y. (2025), Dicyandiamide‑Driven Tailoring of the n‑Value Distribution and Interface Dynamics for High‑Performance ACI 2D Perovskite Solar Cells. Nano-Micro Lett., 17:305.
Research Paper: Defect mitigation via fullerene-based functional additives for enhanced efficiency and stability in tin perovskite solar cells
Shukla, A., Khadka, D.B., Li, C., Rikukawa, M., Takeoka, Y., Sahara, R., Yanagida, M. and Shirai, Y. (2025), Defect mitigation via fullerene-based functional additives for enhanced efficiency and stability in tin perovskite solar cells. J. Mater. Chem. A, 13: 23487.
Research Paper: Optimizing 2D passivation for enhancing performance of fully air-processed carbon electrode-based perovskite solar cells
Khawaja, K.A., Vijayaraghavan, S.N., Penukula, S., Xiang, W., Rolston, N., Li, L. and Yan, F. (2025), Optimizing 2D passivation for enhancing performance of fully air-processed carbon electrode-based perovskite solar cells. EES Sol., 1, 620.
Research Paper: Thermodynamic principles for optimizing multi-junction photovoltaics — Exemplified for perovskite-based indoor photovoltaics
Kay, A.M., Riley, D.B., Burwell, G., & Meredith, P. (2025), Thermodynamic principles for optimizing multi-junction photovoltaics—Exemplified for perovskite-based indoor photovoltaics. APL Energy, 3, 036102.
Research Paper: Double-side Interfacial Engineering of Hole Transport Layer Enables Efficient and Operationally Stable Colloidal Quantum Dot Solar Cells
Researchers achieved a record 14.28% efficiency and 520-hour operational stability in PbS CQD solar cells using Fluxim’s Litos Lite. A double-side engineered HTL dramatically improved performance and lifetime in air.
Loss Analysis of Halide-Perovskite Solar Cells Deposited on Textured Substrates
Wang, Y., Hüpkes, J., Ravishankar, S., Klingebiel, B. and Kirchartz, T. (2025), Loss Analysis of Halide-Perovskite Solar Cells Deposited on Textured Substrates. Sol. RRL, 9: 2400829.
Toward Understanding the Built-in Field in Perovskite Solar Cellsthrough Layer-by-Layer Surface Photovoltage Measurements
Gutierrez-Partida, E., Rusu, M., Zu, F., Raoufi, M., Diekmann, J., Tokmoldin, N., Warby, J., Menzel, D., Lang, F., Shah, S., Shoaee, S., Korte, L., Unold, T., Koch, N., Kirchartz, T., & Neher, D., Stolterfoht, M. (2025). Toward understanding the built-in field in perovskite solar cells through layer-by-layer surface photovoltage measurements. ACS Applied Materials & Interfaces, 17(7), Article 7.
Solvent-dripping modulated 3D/2D heterostructures for high-performance perovskite solar cells
Chang, X., Azmi, R., Yang, T. et al. Solvent-dripping modulated 3D/2D heterostructures for high-performance perovskite solar cells. Nat Commun 16, 1042 (2025).
Efficiency optimization of lead-free CH3NH3SnI3-based perovskite solar cells through material and structural modifications
Alsulami, Q.A., Redoy, R.A. & Wageh, S. Efficiency optimization of lead-free CH3NH3SnI3-based perovskite solar cells through material and structural modifications. Sci Rep 15, 13170 (2025).
Exploring Charge Transport and Hysteresis Effects in Perovskite Solar Cells Through Dynamic Measurements and Analytical Modeling
Nogueira, G. L.; Lopez-Richard, V.; Meneghetti Jr., L. A.; Hartmann, F.; Graeff, C. F. O., A New Approach to Characterize Charge Transport and Hysteresis in Perovskite Solar Cells, arXiv 2025
Hole-selective-molecule doping improves the layer thickness tolerance of PEDOT:PSS for efficient organic solar cells
Bin Zhao, Xiaozhen Huang, Sein Chung, Min Zhang, Yufei Zhong, Anhai Liang, Zhenmin Zhao, Chaofeng Zhu, Jingjing Zhao, Seunghyun Kim, Jimin Kim, Ming Wang, Shilin Chen, Kilwon Cho, Yang Wang, Zhipeng Kan, eScience,Volume 5, Issue 1,2025, 100305, ISSN 2667-1417
23.2% efficient low band gap perovskite solar cells with cyanogen management
Perera, W. H. K.; Zhou, Y.; Webb, T.; Trindade, G. F.; Xu, Y.; Zhu, J.; Masteghin, M. G.; Harvey, S. P.; Macdonald, T. J.; Jenatsch, S.; Dai, L.; Sathasivam, S.; Hinder, S. J.; Stranks, S. D.; Jayawardena, K. D. G. I.; Zhao, D.; Zhao, Y.; Zhang, W.; Haque, S. A.; Silva, S. R. P.
Energy Environ. Sci. 2025, 18, 439–453