[1] H GU, S C CHEN, Q ZHENG. Emerging perovskite materials with different nanostructures for photodetectors. Advanced Optical Materials, 9, 2001637(2020).
[2] W CAI, H LI, M LI et al. Opportunities and challenges of inorganic perovskites in high-performance photodetectors. Journal of Physics D: Applied Physics, 54, 293002(2021).
[3] N LAUERSDORF, J HUANG. Perovskites Enabled Highly Sensitive and Fast Photodetectors. Perovskite Photovoltaics and Optoelectronics: From Fundamentals to Advanced Applications. San Francisco: WILEY, 383-409(2022).
[4] C LI, Y MA, Y XIAO et al. Advances in perovskite photodetectors. InfoMat, 2, 1247(2020).
[5] Y XU, Y LI, G PENG et al. Asymmetric metal halide film with suppressed leakage current for high sensitive X-ray detection and imaging. IEEE Electron Device Letters, 43, 1709(2022).
[6] X TIAN, Y ZHANG, R ZHENG et al. Two-dimensional organic- inorganic hybrid Ruddlesden-Popper perovskite materials: preparation, enhanced stability, and applications in photodetection. Sustainable Energy & Fuels, 4, 2087(2020).
[7] Y LEI, Y LI, Z JIN. Photon energy loss and management in perovskite solar cells. Energy Reviews, 1, 100003(2022).
[8] F WANG, Y HAN, D DUAN et al. Recent progress of scalable perovskite solar cells and modules. Energy Reviews, 1, 100010(2022).
[9] H YANG, C CUI. Impact of isomers on the photovoltaic properties of polymerized small-molecule acceptors. Energy Reviews, 1, 100008(2022).
[10] B LI, Z LI, X WU et al. Interface functionalization in inverted perovskite solar cells: from material perspective. Nano Research Energy, e9120011(2022).
[11] H GUAN, Y LEI, Q WU et al. An interface co-modification strategy for improving the efficiency and stability of CsPbI3 perovskite solar cells. ACS Applied Energy Materials, 5, 13419(2022).
[12] Y LEI, G PENG, H WANG et al. 2D Dion-Jacobson CsPbI3 with enhanced interlayer coupling for stable and efficient photovoltaics. Advanced Materials Interfaces, 9, 2201501(2022).
[13] J GHOSH, P K GIRI. Recent advances in perovskite/2D materials based hybrid photodetectors. Journal of Physics: Materials, 4, 032008(2021).
[14] J SAFAEI, G WANG. Progress and prospects of two-dimensional materials for membrane-based osmotic power generation. Nano Research Energy, e9120008(2022).
[15] T HUANG, Z ZHU, C ZHAO et al. Enhancing two-dimensional perovskite photodetector performance through balancing carrier density and directional transport. Journal of Materials Chemistry A, 10, 21044(2022).
[16] K TANAKA, T TAKAHASHI, T KONDO et al. Image charge effect on two-dimensional excitons in an inorganic-organic quantum- well crystal. Physical Review B, 71, 045312(2005).
[17] M ERA, T HATTORI, T TAIRA et al. Self-organized growth of PbI-based layered perovskite quantum well by dual-source vapor deposition. Chemistry of Materials, 9, 8(1997).
[18] H YAO, G PENG, Z LI et al. Fine coverage and uniform phase distribution in 2D (PEA)2Cs3Pb4I13 solar cells with a record efficiency beyond 15%. Nano Energy, 106790(2022).
[19] Y LEI, Z LI, H WANG et al. Manipulate energy transport via fluorinated spacers towards record-efficiency 2D Dion-Jacobson CsPbI3 solar cells. Science Bulletin, 67, 1352(2022).
[20] C SHI, Z LI, K KANG et al. Fluorosubstitution boosting 2D Ruddlesden-Popper CsPbI3 with high stability and efficiency. Solar RRL, 6, 2200694(2022).
[21] H YAO, Z LI, G PENG et al. Novel PHA organic spacer increases interlayer interactions for high efficiency in 2D Ruddlesden- Popper CsPbI3 solar cells. ACS Applied Materials & Interfaces, 14, 35780(2022).
[22] H YAO, Z LI, C SHI et al. A novel multiple-ring aromatic spacer based 2D Ruddlesden-Popper CsPbI3 solar cell with record efficiency beyond 16%. Advanced Functional Materials, 32, 2205029(2022).
[23] W CHI, S K BANERJEE. Engineering strategies for two-dimensional perovskite solar cells. Trends in Chemistry, 4, 1005(2022).
[24] X ZHAO, T LIU, Y L LOO. Advancing 2D perovskites for efficient and stable solar cells: challenges and opportunities. Advanced Materials, 34, e2105849(2022).
[25] R ZHUANG, X WANG, W MA et al. Highly sensitive X-ray detector made of layered perovskite-like (NH4)3Bi2I9 single crystal with anisotropic response. Nature Photonics, 13, 602(2019).
[26] H LI, J SONG, W PAN et al. Sensitive and stable 2D perovskite single-crystal X-ray detectors enabled by a supramolecular anchor. Advanced Materials, 32, e2003790(2020).
[27] H WANG, D H KIM. Perovskite-based photodetectors: materials and devices. Chemical Society Reviews, 46, 5204(2017).
[28] Z LI, E HONG, X ZHANG et al. Perovskite-type 2D materials for high-performance photodetectors. The Journal of Physical Chemistry Letters, 13, 1215(2022).
[29] Y LIU, H YE, Y ZHANG et al. Surface-tension-controlled crystallization for high-quality 2D perovskite single crystals for ultrahigh photodetection. Matter, 1, 465(2019).
[30] Y WANG, Y LIU, S CAO et al. A review on solution-processed perovskite/organic hybrid photodetectors. Journal of Materials Chemistry C, 9, 5302(2021).
[31] T ZHANG, Q XU, F XU et al. Spontaneous low-temperature crystallization of alpha-FAPbI3 for highly efficient perovskite solar cells. Science Bulletin, 64, 1608(2019).
[32] L CHU, S ZHAI, W AHMAD et al. High-performance large-area perovskite photovoltaic modules. Nano Research Energy, e9120024(2022).
[33] J ZENG, L BI, Y CHENG et al. Self-assembled monolayer enabling improved buried interfaces in blade-coated perovskite solar cells for high efficiency and stability. Nano Research Energy, e9120004(2022).
[34] Y LI, D KUANG, J GUO et al. Wavelength selective and cesium halides additive photodetectors based on two-dimensional perovskite: (C8H9NH3)2PbBr4. Journal of Alloys and Compounds, 163990(2022).
[35] Y YUE, M LI, H LI et al. One-step anti-solvent associated method for high performance two-dimensional perovskite photodetectors fabrication at low temperature. Chemical Engineering Journal, 135997(2022).
[36] S H CHIN, J W CHOI, H C WOO et al. Realizing a highly luminescent perovskite thin film by controlling the grain size and crystallinity through solvent vapour annealing. Nanoscale, 11, 5861(2019).
[37] K C KWON, K HONG, LE Q VAN et al. Inhibition of ion migration for reliable operation of organolead halide perovskite- based metal/semiconductor/metal broadband photodetectors. Advanced Functional Materials, 26, 4213(2016).
[38] H R XIA, J LI, W T SUN et al. Organohalide lead perovskite based photodetectors with much enhanced performance. Chemical Communications, 50, 13695(2014).
[39] G LI, Y WANG, L HUANG et al. Research progress of high- sensitivity perovskite photodetectors: a review of photodetectors: noise, structure, and materials. ACS Applied Electronic Materials, 4, 1485(2022).
[40] F LI, T YANG, R ZHENG. Solution-processed perovskite crystals for electronics: moving forward. Matter, 5, 1700(2022).
[41] N GANESH, A Z ASHAR, S PUROHIT et al. Visualization of carrier transport in lateral metal-perovskite-metal structures and its influence on device operation. Physical Review Applied, 17, 024060(2022).
[42] X LIU, S WANG, P LONG et al. Polarization-driven self-powered photodetection in a single-phase biaxial hybrid perovskite ferroelectric. Angewandte Chemie International Edition, 58, 14504(2019).
[43] L LI, Z SUN, P WANG et al. Tailored engineering of an unusual (C4H9NH3)2(CH3NH3)2Pb3Br10 two-dimensional multilayered perovskite ferroelectric for a high-performance photodetector. Angewandte Chemie International Edition, 56, 12150(2017).
[44] G M POUND, M T SIMNAD, L YANG. Heterogeneous nucleation of crystals from vapor. The Journal of Chemical Physics, 22, 1215(1954).
[45] Y WANG, Y TANG, J JIANG et al. Mixed-dimensional self-assembly organic-inorganic perovskite microcrystals for stable and efficient photodetectors. Journal of Materials Chemistry C, 8, 5399(2020).
[46] K DONG, H ZHOU, M XIAO et al. Semi-transparent, high-performance lead-free Cs3Bi2I9 single crystal self-driven photodetector. Applied Physics Letters, 120, 191102(2022).
