Abstract

Halide perovskite semiconductors have emerged as promising candidates for the next-generation low-energy consumption, high-flexibility photonics and optoelectronic devices thanks to their superior optical and excitonic properties as well as fabrication convenience. This special issue, including three review papers and six original research papers, focuses on the studies of both fundamentals and applications of perovskite photonics, covering materials, excitonic properties, nonlinear optics, strong light–matter interactions, and optoelectronic devices.

© 2020 Chinese Laser Press

In 2009, metal halide perovskites that combine both advantages of inorganic and organic semiconductors revived as sensitizers in solar cells (SCs) with a power conversion efficiency of 3.8%, which opened a booming decade for perovskite photonics and optoelectronics [16]. Up to now, the conversion efficiency of perovskite SCs has increased dramatically to over 25% [7]. The outstanding excitonic and optical properties of perovskites, including the large absorption/emission efficiency, high defect tolerance, long-distance carrier diffusion, and the low-cost fabrication process, also make them promising for light source and detector applications. The perovskite light-emitting diodes (LEDs) can be traced back to the 1990s [8]. In 2014, a room-temperature perovskite LED was realized by Tan et al. with an external quantum efficiency of only 0.1% [9], and until now the efficiency has been promoted to over 20% in green and red bands [10,11]. In 2014, the first room-temperature microlaser was realized using organic–inorganic hybrid perovskite nanoplatelets [12], and then perovskite lasers including polariton lasers, vortex lasers, and plasmonic lasers were developed rapidly thanks to the high optical gain [1319]. Lately, the continuous-wave optically pumped perovskite microlasers and distributed feedback lasers have been reported [2023]. Perovskites are also employed as active layers in high-efficiency, polarization-sensitive photodetectors [24,25] and X-ray detectors [26,27], which is benefitted from large absorption coefficients for both visible and X-ray spectral ranges as well as high carrier mobilities. Meanwhile, the perovskite nanocrystals can be used for a single-photon light source [28]. For example, a coherent single-photon source was recently reported with a coherence time as long as 80 ps [29], which is very promising for quantum communication applications based on large-scale solution-processed single-photon sources. In particular, perovskites have been an ideal platform to investigate the strong light–matter interactions toward room-temperature polaritonic devices working within a wide band spectrally covering from the ultra-violet to the visible range [17,20,21,3034]. In 2017, Su et al. reported the first room-temperature polariton lasing in a planar perovskite cavity [17], and later in 2019, they observed the room-temperature exciton polariton condensation in a perovskite lattice [32]. In 2018, Zhang et al. reported the exciton polariton in low-dimensional CH3NH3PbBr3 nanowires with a Rabi splitting energy of 390 meV [33], which was then promoted to 564 meV by Shang et al. through adopting the metal–insulator–semiconductor hybrid structure [34]. The studies on exciton polaritons of perovskites have benefitted from the development of low-threshold perovskite microlasers [20,21]. Given the complex framework of the whole perovskite photonics, this special issue aims to provide a journey throughout the fundamentals and applications in this field, and to present the prospects of this future semiconductor material.

Parameter verification is the first step to exploit a material. Excitons, one type of photoexcitation near the optical band edge, play an important role in the core physical processes of semiconductor photonic devices, such as optical transition, charge transfer, and strong exciton–photon coupling [35,36]. For three-dimensional perovskite materials with organic–inorganic hybrid characteristics, the long-standing controversy regarding exciton parameters, especially exciton binding energy ranging from a few meV to nearly 100 meV, has promoted scientists to carry out relevant researches from an in-depth and comprehensive perspective [37,38]. A new report conducted by Baranowski et al. has measured the exciton parameters of CsPbCl3 through high magnetic field spectroscopy at 2 K, including exciton binding energy (64 ± 1.5 meV) and effective mass (0.202 ± 0.010 of the free electron mass) [39]. The measured results are consistent with the theoretical calculations, showing that the exciton binding energy and effective mass increase with decreasing halide atomic number. In addition, the permittivity decreases with lighter metal and halide atoms. These results prove the promising future for CsPbCl3 as optoelectronic and polaritonic devices, especially in the violet and ultra-violet spectral ranges.

Modification and optimization are the second promotion. One of the origins of perovskite fever is the rich combination of cations and anions, where the cation candidates include various metal or organic cations while the halide anions can be easily tailored to obtain different bandgaps [40]. Furthermore, the emergence of layered perovskites with mixed dimensionality has combined valuable properties between those of two-dimensional and three-dimensional systems [4143], featuring multiple quantum well nature and dielectric confinement. In addition to material, combining with cavity engineering also paves the way to fundamental photonics and practical devices. Four essays in this feature issue focus on mixed organic cations, mixed halide anions, two-dimensional perovskites, and perovskite-based plasmonic metasurface, respectively. Mixing halide anions has been an ordinary way for bandgap tuning and lattice stabilization in perovskites; however, the phase segregation under external stimuli (e.g., illumination) is detrimental to the device performance [44]. To provide an insight into this issue, Wang et al. review the phase segregation phenomena and possible mechanisms in inorganic mixed-halide perovskites, including thin films and nanocrystals [45]. In addition, the mitigation methods are also overviewed, i.e., compositional tuning, morphology engineering, and trap passivation. Another review by Zhang et al. focuses on the 2D counterpart, especially the cavity engineering and light–matter interaction in those 2D perovskite microcavities [46]. 2D perovskites are layered materials in which an inorganic metal-halide octahedron layer is sandwiched by two long-chain organic layers. Zhang et al. first introduced the unique properties of 2D perovskites that resulted from the inherent quantum well structure, and then summarized the fabrication methods, followed by exciton–photon coupling, photonics lasers, and a variety of other function devices in different cavity configurations. This review gives a general view of 2D perovskites and would promote the future development of this field. Zhang et al. studied the nonlinear effects in MA1xFAxPbI3 [MA=CH3NH3+, FA=CH(NH2)2+], i.e., two-photon absorption and saturable absorption. As the pump power increases from 1.0GW·cm2 to 3.0GW·cm2, a conversion from two-photon absorption to saturable absorption is observed from the Z-scan results, which is confirmed by transient absorption and power-dependent transmission spectra. With increasing x, i.e., the FA component, the nonlinear absorption coefficient decreases, accompanied by an increased saturation transmission intensity. The effect of organic cations results from weaker electron cloud distortion of Pb2+, which is attributed to larger unit cell expansion and more hydrogen bonds for larger x [47]. Moreover, Lu et al. investigate the formation of exciton–photon polaritons and exciton–surface plasmon polaritons in perovskite-based subwavelength lattices with different thicknesses. From a theoretical discussion, the configuration sustaining strong light–matter interactions is considered to concurrently allow exceptional points with enhanced local density of states and a quasi-bound state in the continuum with negligible nonradiative losses of the dark mode [48].

Device applications in light harvesting and light source field have continuously fueled the rapid development of halide perovskite photonics and optoelectronics, in parallel with active research in the fundamental optical physics related to excitons and their dressed states with light. A wide range of devices have been demonstrated in solar cells, LEDs, lasers, amplifiers, displays, photodetectors, etc. [10,11,24,4953]; nonetheless, there are still pending scientific and technological questions concerning large-area device fabrication, device stability, as well as the high-performance device. In this issue, Zhao et al. review the fabrication methods of large-area perovskite SCs (area larger than 1cm2) [54], such as spin-coating, blade-coating, and inject printing. In addition, they summarize the common strategies to improve the quality of large-area perovskite films, including engineering the precursor solvent and additives. Furthermore, the fabrication of the large-area charge transporting layer is also discussed, e.g., utilizing Bifluo-OMeTAD in place of Spiro-OMeTAD as HTL to circumvent the difficulty of large-area spin-coating. Although large-area SCs are harnessed by an efficiency lower than 20%, this review concludes with a clear direction ahead. Meanwhile, PTAA has been a conventional HTL in perovskite SCs. Its good hydrophobicity improves the device stability, but hinders the spin-coating process of perovskite precursors as well. Li et al. demonstrate a two-step solvent post-treatment to PTAA with DMF and toluene to improve the hydrophilicity and morphology of PTAA surface, on which the spin-coated perovskite layer shows better crystallinity [55]. As-fabricated inverted perovskite SCs exhibit a high efficiency of 19.13%, and a good stability of maintaining 88.4% of the initial PCE after 30 days in air. Beyond intrinsic photovoltaic properties, Mica et al. explore the potential of Cs0.06MA0.15FA0.79Pb(I0.85Br0.15)3 SCs for visible light communication [56]. These triple-cation perovskite SCs exhibit great energy harvesting performance with PCE up to 21.4%. After the SCs are embedded into the circuit, the ability to collect data is measured for SCs with thicknesses from 60 to 965 nm, and a record high data rate of 56 Mbps for perovskite photodetectors is observed. A further discussion on bandwidth stresses the role of RC time constant, and the optimization of thickness is necessary considering the data rate and bandwidth concurrently. An extra emphasis by Liu et al. is placed on the upconversion lasing in CsPb2Br5 microplates with single-mode operation, high quality factor (3551), and imperceptible color shift (<0.1nm) [57]. The net optical gain of CsPb2Br5 microplates is quickly established in less than 1 ps and persists more than 30 ps, and the net gain for stimulated emission demonstrates a high characteristic temperature of 403 K, providing another all-inorganic platform for high-performance perovskite lasers beyond widely used CsPbBr3.

In summary, this special issue presents some frontier works that give a glimpse of the inspiring advances in the field of perovskite photonics, including fundamental investigations, optimization explorations, and application achievements. Finally, we would like to thank the editorial team from Photonics Research for the opportunity to edit this special issue. We are also sincerely grateful to all the authors for their outstanding contributions and the referees for their valuable comments that helped to improve the articles in this special issue.

Disclosures

The authors declare no conflicts of interest.

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52. J. Xu, C. C. Boyd, Z. J. Yu, A. F. Palmstrom, D. J. Witter, B. W. Larson, R. M. France, J. Werner, S. P. Harvey, E. J. Wolf, W. Weigand, S. Manzoor, M. F. A. M. van Hest, J. J. Berry, J. M. Luther, Z. C. Holman, and M. D. McGehee, “Triple-halide wide-band gap perovskites with suppressed phase segregation for efficient tandems,” Science 367, 1097–1104 (2020). [CrossRef]  

53. Y. Hou, E. Aydin, M. De Bastiani, C. Xiao, F. H. Isikgor, D.-J. Xue, B. Chen, H. Chen, B. Bahrami, A. H. Chowdhury, A. Johnston, S.-W. Baek, Z. Huang, M. Wei, Y. Dong, J. Troughton, R. Jalmood, A. J. Mirabelli, T. G. Allen, E. Van Kerschaver, M. I. Saidaminov, D. Baran, Q. Qiao, K. Zhu, S. De Wolf, and E. H. Sargent, “Efficient tandem solar cells with solution-processed perovskite on textured crystalline silicon,” Science 367, 1135–1140 (2020). [CrossRef]  

54. Y. Zhao, F. Ma, F. Gao, Z. Yin, X. Zhang, and J. You, “Research progress in large-area perovskite solar cells,” Photon. Res. 8, A1–A15 (2020). [CrossRef]  

55. Y. Li, C. Liang, G. Wang, J. Li, S. Chen, S. Yang, G. Xing, and H. Pan, “Two-step solvent post-treatment on PTAA for highly efficient and stable inverted perovskite solar cells,” Photon. Res. 8, A39–A49 (2020). [CrossRef]  

56. N. A. Mica, R. Bian, P. Manousiadis, L. K. Jagadamma, I. Tavakkolnia, H. Haas, G. A. Turnbull, and I. D. W. Samuel, “Triple-cation perovskite solar cells for visible light communications,” Photon. Res. 8, A16–A24 (2020). [CrossRef]  

57. Z. Liu, C. Wang, Z. Hu, J. Du, J. Yang, Z. Zhang, T. Shi, W. Liu, X. Tang, and Y. Leng, “Mode selection and high-quality upconversion lasing from perovskite CsPb2Br5 microplates,” Photon. Res. 8, A31–A38 (2020). [CrossRef]  

References

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  1. A. Kojima, K. Teshima, Y. Shirai, and T. Miyasaka, “Organometal halide perovskites as visible-light sensitizers for photovoltaic cells,” J. Am. Chem. Soc. 131, 6050–6051 (2009).
    [Crossref]
  2. M. A. Green, A. Ho-Baillie, and H. J. Snaith, “The emergence of perovskite solar cells,” Nat. Photonics 8, 506–514 (2014).
    [Crossref]
  3. P. Gao, M. Grätzel, and M. K. Nazeeruddin, “Organohalide lead perovskites for photovoltaic applications,” Energy Environ. Sci. 7, 2448–2463 (2014).
    [Crossref]
  4. G. E. Eperon, M. T. Hörantner, and H. J. Snaith, “Metal halide perovskite tandem and multiple-junction photovoltaics,” Nat. Rev. Chem. 1, 0095 (2017).
    [Crossref]
  5. J.-P. Correa-Baena, M. Saliba, T. Buonassisi, M. Grätzel, A. Abate, W. Tress, and A. Hagfeldt, “Promises and challenges of perovskite solar cells,” Science 358, 739–744 (2017).
    [Crossref]
  6. H. J. Snaith, “Present status and future prospects of perovskite photovoltaics,” Nat. Mater. 17, 372–376 (2018).
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C. Huang, C. Zhang, S. Xiao, Y. Wang, Y. Fan, Y. Liu, N. Zhang, G. Qu, H. Ji, J. Han, L. Ge, Y. Kivshar, and Q. Song, “Ultrafast control of vortex microlasers,” Science 367, 1018–1021 (2020).
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Q. Shang, M. Li, L. Zhao, D. Chen, S. Zhang, S. Chen, P. Gao, C. Shen, J. Xing, G. Xing, B. Shen, X. Liu, and Q. Zhang, “Role of the exciton-polariton in a continuous-wave optically pumped CsPbBr3 perovskite laser,” Nano Lett. 20, 6636–6643 (2020).
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C. Qin, A. S. D. Sandanayaka, C. Zhao, T. Matsushima, D. Zhang, T. Fujihara, and C. Adachi, “Stable room-temperature continuous-wave lasing in quasi-2D perovskite films,” Nature 585, 53–57 (2020).
[Crossref]

R. Su, S. Ghosh, J. Wang, S. Liu, C. Diederichs, T. C. H. Liew, and Q. Xiong, “Observation of exciton polariton condensation in a perovskite lattice at room temperature,” Nat. Phys. 16, 301–306 (2020).
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M. Baranowski, P. Plochocka, R. Su, L. Legrand, T. Barisien, F. Bernardot, Q. Xiong, C. Testelin, and M. Chamarro, “Exciton binding energy and effective mass of CsPbCl3: a magneto-optical study,” Photon. Res. 8, A50–A55 (2020).
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Y. Wang, X. Quintana, J. Kim, X. Guan, L. Hu, C.-H. Lin, B. T. Jones, W. Chen, X. Wen, H. Gao, and T. Wu, “Phase segregation in inorganic mixed-halide perovskites: from phenomena to mechanisms,” Photon. Res. 8, A56–A71 (2020).

S. Zhang, Y. Zhong, F. Yang, Q. Cao, W. Du, J. Shi, and X. Liu, “Cavity engineering of two-dimensional perovskites and inherent light-matter interaction,” Photon. Res. 8, A72–A90 (2020).

X. Zhang, S. Xiao, R. Li, T. He, G. Xing, and R. Chen, “Influence of mixed organic cations on the nonlinear optical properties of lead tri-iodide perovskites,” Photon. Res. 8, A25–A30 (2020).
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L. Lu, Q. Le-Van, L. Ferrier, E. Drouard, C. Seassal, and H. S. Nguyen, “Engineering light–matter strong coupling regime in perovskite-based plasmonic metasurface: quasi-bound state in the continuum and exceptional points,” Photon. Res. 8, A91–A100 (2020).

D. Kim, H. J. Jung, I. J. Park, B. W. Larson, S. P. Dunfield, C. Xiao, J. Kim, J. Tong, P. Boonmongkolras, S. G. Ji, F. Zhang, S. R. Pae, M. Kim, S. B. Kang, V. Dravid, J. J. Berry, J. Y. Kim, K. Zhu, D. H. Kim, and B. Shin, “Efficient, stable silicon tandem cells enabled by anion-engineered wide-bandgap perovskites,” Science 368, 155–160 (2020).
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J. Xu, C. C. Boyd, Z. J. Yu, A. F. Palmstrom, D. J. Witter, B. W. Larson, R. M. France, J. Werner, S. P. Harvey, E. J. Wolf, W. Weigand, S. Manzoor, M. F. A. M. van Hest, J. J. Berry, J. M. Luther, Z. C. Holman, and M. D. McGehee, “Triple-halide wide-band gap perovskites with suppressed phase segregation for efficient tandems,” Science 367, 1097–1104 (2020).
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Y. Hou, E. Aydin, M. De Bastiani, C. Xiao, F. H. Isikgor, D.-J. Xue, B. Chen, H. Chen, B. Bahrami, A. H. Chowdhury, A. Johnston, S.-W. Baek, Z. Huang, M. Wei, Y. Dong, J. Troughton, R. Jalmood, A. J. Mirabelli, T. G. Allen, E. Van Kerschaver, M. I. Saidaminov, D. Baran, Q. Qiao, K. Zhu, S. De Wolf, and E. H. Sargent, “Efficient tandem solar cells with solution-processed perovskite on textured crystalline silicon,” Science 367, 1135–1140 (2020).
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Y. Zhao, F. Ma, F. Gao, Z. Yin, X. Zhang, and J. You, “Research progress in large-area perovskite solar cells,” Photon. Res. 8, A1–A15 (2020).
[Crossref]

Y. Li, C. Liang, G. Wang, J. Li, S. Chen, S. Yang, G. Xing, and H. Pan, “Two-step solvent post-treatment on PTAA for highly efficient and stable inverted perovskite solar cells,” Photon. Res. 8, A39–A49 (2020).
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N. A. Mica, R. Bian, P. Manousiadis, L. K. Jagadamma, I. Tavakkolnia, H. Haas, G. A. Turnbull, and I. D. W. Samuel, “Triple-cation perovskite solar cells for visible light communications,” Photon. Res. 8, A16–A24 (2020).
[Crossref]

Z. Liu, C. Wang, Z. Hu, J. Du, J. Yang, Z. Zhang, T. Shi, W. Liu, X. Tang, and Y. Leng, “Mode selection and high-quality upconversion lasing from perovskite CsPb2Br5 microplates,” Photon. Res. 8, A31–A38 (2020).
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2019 (6)

Y. Fu, H. Zhu, J. Chen, M. P. Hautzinger, X. Y. Zhu, and S. Jin, “Metal halide perovskite nanostructures for optoelectronic applications and the study of physical properties,” Nat. Rev. Mater. 4, 169–188 (2019).
[Crossref]

Y. Liang, Q. Shang, Q. Wei, L. Zhao, Z. Liu, J. Shi, Y. Zhong, J. Chen, Y. Gao, M. Li, X. Liu, G. Xing, and Q. Zhang, “Lasing from mechanically exfoliated 2D homologous Ruddlesden-Popper perovskite engineered by inorganic layer thickness,” Adv. Mater. 31, 1903030 (2019).
[Crossref]

Y. Liu, J. Cui, K. Du, H. Tian, Z. He, Q. Zhou, Z. Yang, Y. Deng, D. Chen, X. Zuo, Y. Ren, L. Wang, H. Zhu, B. Zhao, D. Di, J. Wang, R. H. Friend, and Y. Jin, “Efficient blue light-emitting diodes based on quantum-confined bromide perovskite nanostructures,” Nat. Photonics 13, 760–764 (2019).
[Crossref]

Y. Jiang, X. Wang, and A. Pan, “Properties of excitons and photogenerated charge carriers in metal halide perovskites,” Adv. Mater. 31, 1806671 (2019).
[Crossref]

H. Utzat, W. Sun, A. E. K. Kaplan, F. Krieg, M. Ginterseder, B. Spokoyny, N. D. Klein, K. E. Shulenberger, C. F. Perkinson, M. V. Kovalenko, and M. G. Bawendi, “Coherent single-photon emission from colloidal lead halide perovskite quantum dots,” Science 363, 1068–1072 (2019).
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C. Chen, L. Gao, W. Gao, C. Ge, X. Du, Z. Li, Y. Yang, G. Niu, and J. Tang, “Circularly polarized light detection using chiral hybrid perovskite,” Nat. Commun. 10, 1927 (2019).
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2018 (8)

T. J. S. Evans, A. Schlaus, Y. Fu, X. Zhong, T. L. Atallah, M. S. Spencer, L. E. Brus, S. Jin, and X. Y. Zhu, “Continuous-wave lasing in cesium lead bromide perovskite nanowires,” Adv. Opt. Mater. 6, 1700982 (2018).
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S. Zhang, Q. Shang, W. Du, J. Shi, Z. Wu, Y. Mi, J. Chen, F. Liu, Y. Li, M. Liu, Q. Zhang, and X. Liu, “Strong exciton-photon coupling in hybrid inorganic-organic perovskite micro/nanowires,” Adv. Opt. Mater. 6, 1701032 (2018).
[Crossref]

Q. Shang, S. Zhang, Z. Liu, J. Chen, P. Yang, C. Li, W. Li, Y. Zhang, Q. Xiong, X. Liu, and Q. Zhang, “Surface plasmon enhanced strong exciton-photon coupling in hybrid inorganic-organic perovskite nanowires,” Nano Lett. 18, 3335–3343 (2018).
[Crossref]

H. J. Snaith, “Present status and future prospects of perovskite photovoltaics,” Nat. Mater. 17, 372–376 (2018).
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K. Lin, J. Xing, L. N. Quan, F. P. G. de Arquer, X. Gong, J. Lu, L. Xie, W. Zhao, D. Zhang, C. Yan, W. Li, X. Liu, Y. Lu, J. Kirman, E. H. Sargent, Q. Xiong, and Z. Wei, “Perovskite light-emitting diodes with external quantum efficiency exceeding 20 per cent,” Nature 562, 245–248 (2018).
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Y. Cao, N. Wang, H. Tian, J. Guo, Y. Wei, H. Chen, Y. Miao, W. Zou, K. Pan, Y. He, H. Cao, Y. Ke, M. Xu, Y. Wang, M. Yang, K. Du, Z. Fu, D. Kong, D. Dai, Y. Jin, G. Li, H. Li, Q. Peng, J. Wang, and W. Huang, “Perovskite light-emitting diodes based on spontaneously formed submicrometre-scale structures,” Nature 562, 249–253 (2018).
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Z. Wu, J. Chen, Y. Mi, X. Sui, S. Zhang, W. Du, R. Wang, J. Shi, X. Wu, X. Qiu, Z. Qin, Q. Zhang, and X. Liu, “All-inorganic CsPbBr3 nanowire based plasmonic lasers,” Adv. Opt. Mater. 6, 1800674 (2018).
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M. C. Brennan, S. Draguta, P. V. Kamat, and M. Kuno, “Light-induced anion phase segregation in mixed halide perovskites,” ACS Energy Lett. 3, 204–213 (2018).
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2017 (6)

Q. Zhang, R. Su, W. Du, X. Liu, L. Zhao, S. T. Ha, and Q. Xiong, “Advances in small perovskite-based lasers,” Small Methods 1, 1700163 (2017).
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J. C. Blancon, H. Tsai, W. Nie, C. C. Stoumpos, L. Pedesseau, C. Katan, M. Kepenekian, C. M. M. Soe, K. Appavoo, M. Y. Sfeir, S. Tretiak, P. M. Ajayan, M. G. Kanatzidis, J. Even, J. J. Crochet, and A. D. Mohite, “Extremely efficient internal exciton dissociation through edge states in layered 2D perovskites,” Science 355, 1288–1292 (2017).
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R. Su, C. Diederichs, J. Wang, T. C. H. Liew, J. Zhao, S. Liu, W. Xu, Z. Chen, and Q. Xiong, “Room-temperature polariton lasing in all-inorganic perovskite nanoplatelets,” Nano Lett. 17, 3982–3988 (2017).
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2016 (7)

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2015 (3)

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2009 (1)

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