Book chapter
[1] Leilei Gu, Yuanjing Lin, Qianpeng Zhang, Smart Optoelectronics in Health Monitoring and Human-Machine Interactions . In Soft Electronics for Diagnosis, Therapy, and Integrated Systems (eds X. Yu, J. Li, Y. Huang and E. Song). https://doi.org/10.1002/9783527845507.ch8.
科普
【1】张千鹏,周嗣乾,徐光海,“从实验室到碳中和:高校企业联手掀起ESG绿色创新新浪潮”,科技纵览(IEEE Spectrum中文版),2025年6月,总第155期,68-71页 (2025).
Journal papers
2025
[68] M. Liu, et al., "Downscaling of Self-Aligned Double-Gate Oxide Semiconductor TFT for Ultrahigh-PPI Displays", IEEE Open Journal on Immersive Displays, doi: 10.1109/OJID.2025.3637082. Online.
[67] X. Huan, et al., "Multi-Stimuli-Responsive Dielectric Composites: Composition–Structure–Nanoscale Mechanism–Function Framework for Dynamic Dielectric Engineering", Adv. Funct. Mater., e21845, early view.
[66] J. Sun, et al. "Hierarchically architected biomass-derived magnetic aerogels for broadband electromagnetic attenuation and functionalities", Journal of Materials Science & Technology, 259, 279 (2026).
[65] Z. Lou, et al. “Atomic-Scale Customization of Oriented Dipolar Defects in Amorphous Carbon via Nanoparticle-Templated Phase Engineering”, Adv. Funct. Mater., e20584, early view.
[64]C. Shen, et al., "Vacuum Thermal Evaporation for OLEDs: Fundamentals, Optimization and Insights for PeLEDs", Advanced Electronic Materials, 11, e00555, (2025). (co-corresponding author)
[63] Y. Cao, et al, "Ultrapure and efficient electroluminescence in alkali metal doped inorganic perovskite quantum wires arrays", Nature Communication, 16, 6053 (2025) .
[62] Y. Li, et al., "Flexible Perovskite Light-emitting Diodes: Recent Progress, Applications and Challenges", npj Flexible Electronics, 2025, 9, 32.(co-corresponding author)
[61] Q. Zhang, et al, "Pixelation of Perovskite Quantum Wire Thin Films with 0.18μm Features and 63,500 ppi Pixel Density", Science Advances, 2025, 11, adu3840. (co-corresponding author, co-first author)
[60] Y. Hu, Q. Zhang, et al., "Recent Progress on Structures, Stability, and Applications of Flexible Perovskite Photodetectors", Journal of Semiconductors, 46, 011601 (2025).(co-corresponding author, co-first author)
2024
[59] Q. Zhang, et al., "Perovskite Light-Emitting Diodes with Quantum Wires and Nanorods", Advanced Materials, 37, 2405418, (2025). (Co-first author)
[58] Z. Chen, et al, "Roadmap on Perovskite Light-Emitting Diodes", JPhys Photonics, 6, 032501 (2024).
[57] Q. Zhang, et al, "Improving the Operational Lifetime of Metal-halide Perovskite LEDs with Dimension Control and Ligand Engineering", ACS Nano, 18, 12, 8557–8570 (2024). (First-author)
[56] Y. Li, et al, "Efficient Photothermal Catalytic Oxidation Enabled by Three-Dimensional Nanochannel Substrates", Environmental Science & Technology, 58, 11, 5153–5161 (2024).
[55] B. Ren, et al, "Full-color fibre light-emitting diodes based on perovskite quantum wires," Science Advances, 10, eadn1095 (2024).
[54] Y. Zhou, et al, "An ultra-wide field-of-view pinhole compound eye using hemispherical nanowire array for robot vision", Science Robotics, 9, eadi8666 (2024).
[53] S. Poddar, et al, "Geometric Shape Recognition with Ultra-High Density Perovskite Nanowire Array based Artificial Vision System", ACS Applied Materials & Interfaces, 16, 5028–5035 (2024).
2023
[52] Z. Long, et al, "Bio-inspired visual systems based on curved image sensors and synaptic devices", Materials Today Electronics, 6, 100017 (2023).
[51] L. Shu, et al, "Highly efficient blue light-emitting diodes based on perovskite film with vertically graded bandgap and organic grain boundary passivation shells", Advanced Functional Materials, 33, 2306570 (2023).
[50] Y. B. Cao, et al, "High-Efficiency, Flexible and Large-area Red/Green/Blue All Inorganic Metal Halide Perovskite Quantum Wires-Based Light Emitting Diodes", Nature Communications 14, 4611 (2023).
[49] J. Li, et al, "Self-Generated Buried Submicrocavities for High-Performance Near-Infrared Perovskite Light-Emitting Diode", Nano-Micro Letters, 15, 125 (2023).
[48] D. Zhang, et al, "Metal seeding growth of three-dimensional perovskite nanowire forests for high-performance stretchable photodetectors", Nano Energy, 111 (15), 108386 (2023).
2022
[47] Y. Zhu, et al, "Three-dimensional Nanopillar Arrays-based Efficient and Flexible Perovskite Solar Cells with Enhanced Stability", Nano Letters, 22, 9586-9595 (2022).
[46] Y. Ding, et al, "Uncooled self-powered hemispherical biomimetic pit organ for mid- to long-infrared imaging", Science Advances, 8, eabq8432 (2022).
[45] D. Zhang, Q. Zhang, et al, "Metal Halide Perovskite Nanowires: Synthesis, Integration, Properties, and Applications in Optoelectronics", Advanced Energy Materials, 13(33), 2201735 (2023).
[44] Y. Zhou, et al, "Halide-exchanged perovskite photodetectors for wearable visible-blind ultraviolet monitoring", Nano Energy, 100, 107516 (2022).
[43] S. Poddar, et al, "Image Processing with Multi-level Ultra-fast Three Dimensionally Integrated Perovskite Nanowire Array", Nanoscale Horizons, 7, 759-769 (2022).
[42] S. Poddar, et al, "Robust Lead-free Perovskite Nanowire Array Based Artificial Synapses Exemplifying Gestalt Principle of Closure via a Letter Recognition Scheme", Advanced Intelligent Systems, 4(7), 2200065 (2022).
[41] A. Li, Q. Zhang, et al, “A dual plasmonic core—shell Pt/[TiN@TiO2] catalyst for enhanced photothermal synergistic catalytic activity of VOCs abatement”, Nano Research, 15, 7071–7080 (2022).
[40] Y. Fu, et al, "Strongly Quantum-confined Perovskite Nanowire Arrays for Color Tunable Blue Light-emitting Diodes", ACS Nano, 16, 5, 8388–8398 (2022).
[39] D. Zhang, et al, “Vertical Heterogeneous Integration of Metal Halide Perovskite Quantum-Wires/Nanowires for Flexible Narrowband Photodetectors”, Nano Letters, 22, 7, 3062–3070 (2022).
[38] D. Zhang, Q. Zhang, et al, “Large-scale Planar and Spherical Light-emitting Diodes Based on Arrays of Perovskite Quantum Wires”, Nature Photonics, 16, 284-290 (2022).
2021
[37] Q. Zhang, et al, “Design of a Horizontally Aligned Perovskite Nanowire LED with Improved Light Extraction,” IEEE Journal of Electron Device Society, 9, 1215- 1221 (2021). (First-author, co-corresponding author)
[36] Z. Fan, et al, “Preface to the Special Issue on Flexible Energy Devices”, Journal of Semiconductors, 42(10), 100101 (2021).
[35] Y. Zhu, Q. Zhang, et al, “Recent Progress of Efficient Flexible Solar Cells Based on Nanostructures”, Journal of Semiconductors, 42 (10), 101604 (2021).
[34] Y. Zhu, et al, "Moth Eye-inspired Highly Efficient, Robust, and Neutral-colored Semitransparent Perovskite Solar Cells for Building-integrated Photovoltaics", EcoMat, 3, e12117 (2021).
[33] S. Poddar, et al, “Optically tunable ultra-fast resistive switching in lead-free methyl-ammonium bismuth iodide perovskite film,” Nanoscale, 13, 6184-6191 (2021).
[32] Y. Zhang, et al, "Three-dimensional perovskite nanowire array-based ultrafast resistive RAM with ultralong data retention", Science Advances, 7, eabg3788 (2021).
[31] S. Poddar, et al, "Down-scalable and Ultra-fast Memristors with Ultra-high Density Three-dimensional Arrays of Perovskite Quantum Wires", Nano Letters, 21, 5036-5044 (2021).
2020
[30] Q. Zhang, et al., “Light Out-Coupling Management in Perovskite LEDs- What Can We Learn from the Past?” Advanced Functional Materials, 30, 2002570 (2020).(First author)
[29] Q. Zhang, et al., “Three-dimensional perovskite nanophotonic wire array-based light-emitting diodes with significantly improved efficiency and stability,” ACS Nano, 14 (2), 1577-1585 (2020). (First author)
[28] Y. Fu, Q. Zhang, et al, “Scalable All-evaporation Fabrication of Efficient Light-Emitting Diodes with Hybrid 2D-3D Perovskite Nanostructures,” Advanced Functional Materials, 30, 2002913 (2020). (Co-first author)
[27] Y. Zhu, Q. Zhang, et al, “Vapor Phase Fabrication of Three-Dimensional Arrayed BiI3 Nanosheets for Cost-effective Solar Cells,” InfoMat, 2, 975–983 (2020).
[26] L. Gu, et al, “Biomimetic Electrochemical Eye with Hemispherical Perovskite Nanowire Array Retina,” Nature, 581, 278–282 (2020).
2019
[25] Q. Zhang, et al, "Efficient metal halide perovskite light-emitting diodes with significantly improved light extraction on nanophotonic substrates," Nature Communications, 10 (1), 727 (2019).(First-author)
[24] M. Kam, Q. Zhang, et al, “Room-Temperature Sputtered SnO2 as Robust Electron Transport Layer for Air-Stable and Efficient Perovskite Solar Cells on Rigid and Flexible Substrates,” Scientific Reports, 9, 6963 (2019).
[23] D. Zhang, et al, “Increasing Photoluminescence Quantum Yield by Nanophotonic Design of Quantum-Confined Halide Perovskite Nanowire Arrays,” Nano Letters, 19 (5), 2850–2857 (2019).
[22] L. Tang, et al, “Large-scale, adhesive-free and omnidirectional 3D nanocone anti-reflection films for high performance photovoltaics,” Journal of Semiconductors, 40, 042601 (2019).
2018
[21] P. Khoram, et al, “Surface recombination velocity of methylammonium lead bromide nanowires in anodic aluminium oxide templates,” Molecular Systems Design & Engineering, 3, 723-728 (2018).
[20] L. Gu, et al, “Significantly improved black phase stability of FAPbI3 nanowires via spatially confined vapor phase growth in nanoporous templates,” Nanoscale, 10,15164-15172 (2018).
[19] S. Lim, et al, “Broadband omnidirectional light detection in flexible and hierarchical ZnO/Si heterojunction photodiodes,” Nano Research, 10, 22–36 (2018).
2017
[18] S. Z. Oener, et al, “Perovskite nanowire extrusion,” Nano Letters, 17, 6557–6563 (2017).
[17] A. Waleed, et al, “Lead-free perovskite nanowire array photodetectors with drastically improved stability in nanoengineering templates,” Nano Letters, 17 (1), 523-530 (2017).
2016
[16] A. Waleed, Q. Zhang, et al., "Performance Improvement of Solution-processed CdS/CdTe Solar Cells with a Thin Compact TiO2 Buffer Layer," Science Bulletin, 61 (1), 86-91 (2016). (Co-first author)
[15] J. Lee, Q. Zhang, et al., “Particle–Film Plasmons on Periodic Silver Film over Nanosphere (AgFON): A Hybrid Plasmonic Nanoarchitecture for Surface-Enhanced Raman Spectroscopy,” ACS Applied Materials & Interfaces, 8 (1), 634–642 (2016). (Co-first author)
[14] S. Leung, Q. Zhang, et al, “Progress and Design Concerns of Nanostructured Solar Energy Harvesting Devices,” Small, 12, 2536-2548 (2016).
[13] L. Gu, et al, “3D Arrays of 1024-pixel image sensors based on lead halide perovskite nanowires,” Advanced Materials, 28(44), 9713-9721 (2016).
[12] X. Zheng, et al, “Designing nanobowl arrays of mesoporous TiO2 as an alternative electron transporting layer for carbon cathode-based perovskite solar cells,” Nanoscale, 8, 6393-6402 (2016).
2015
[11] M. M. Tavakoli, et al, “Highly efficient flexible perovskite solar cells with antireflection and self-cleaning nanostructures,” ACS Nano, 9, 10287–10295 (2015).
[10] Y. Qiu, et al, “Nanobowl optical concentrator for efficient light trapping and high-performance organic photovoltaics,” Science Bulletin, 60, 109-115 (2015).
2014
[09] S. Leung, Q. Zhang, et al, “Light management with nanostructures for optoelectronic devices,” The Journal of Physical Chemistry Letters, 5, 1479-1495 (2014).
[08] X. Liu, et al, “All-printable band-edge modulated ZnO nanowire photodetectors with ultra-high detectivity,” Nature Communications, 5, 4007 (2014).
[07] Y. Qiu, et al, “Efficient photoelectrochemical water splitting with ultrathin films of hematite on three-dimensional nanophotonic structures,” Nano Letters, 14, 2123-2129 (2014).
[06] S. Leung, et al, “Roll-to-roll fabrication of large scale and regular arrays of three-dimensional nanospikes for high efficiency and flexible photovoltaics,” Scientific Reports, 4, 4243 (2014).
[05] K. Tsui, et al, “Low-cost, flexible, and self-cleaning 3D nanocone anti-reflection films for high-efficiency photovoltaics,” Advanced Materials, 26, 2805-2811 (2014).
[04] J. Li, et al, “A three-dimensional hexagonal fluorine-doped tin oxide nanocone array: a superior light harvesting electrode for high performance photoelectrochemical water splitting,” Energy & Environmental Science, 7, 3651-3658 (2014).
[03] S. Leung, et al, “Large scale, flexible and three-dimensional quasi-ordered aluminum nanospikes for thin film photovoltaics with omnidirectional light trapping and optimized electrical design,” Energy & Environmental Science, 7, 3611-3616 (2014).
2013
[02] B. Hua, et al, “Efficient photon management with nanostructures for photovoltaics,” Nanoscale, 5, 6627-6640 (2013).
2011
[01] L. Wu, et al, “Polarization characteristics of the metallic structure with elliptically helical metamaterials,” Optics Express, 19, 17539-17945 (2011).
Conference Papers
2024
[04] Q. Zhang*; D. Zhang; B. Cao; H. Lv; X. Mo*; Z. Fan*, "Perovskite Quantum Wires and Their Applications in the Field of Display and Lighting", in CLEO 2024, Technical Digest Series (Optica Publishing Group, 2024), paper SF1R.3.
2021
[03] Q. Zhang, Y. Lin, X. Sun, B. Cao, H. Tang and Z. Fan, "A Design of Horizontal Perovskite Nanowire LED for Better Light Extraction," 2021 5th IEEE Electron Devices Technology & Manufacturing Conference (EDTM), 2021, pp. 1-3. (Best Paper Award Finalist)
[02] S. Poddar, et al, "Opto-Electric resistive switching and synaptic emulation in lead-free perovskite film," 2021 5th IEEE Electron Devices Technology & Manufacturing Conference (EDTM), 2021, pp. 1-3.
[01] L. Gu, et al, "Bionic Eye with Perovskite Nanowire Array Retina," 2021 5th IEEE Electron Devices Technology & Manufacturing Conference (EDTM), 2021, pp. 1-3.
Video Journal:
[1] Q. Zhang*, D. Zhang, Y. Fu, X. Sun, B. Ren, and Z. Fan, "Perovskite Light-Emitting Diodes with Nano- and Quantum- Materials", Vid. Proc. Adv. Mater., Volume 3, Article ID2211622, Year 2022; DOI: 10.5185/vpoam.2022.11622.