[1] ZHANG K N, SHE Y H, CAI X B et al. Epitaxial substitution of metal iodides for low-temperature growth of two-dimensional metal chalcogenides. Nature Nanotechnology, 18, 448-455(2023).

[2] ZHONG J X, ZHOU D W, BAI Q et al. Growth of millimeter-sized 2D metal iodide crystals induced by ion-specific preference at water-air interfaces. Nature Communications, 15, 3185(2024).

[3] XIAO H, LIANG T, XU M S. Growth of ultraflat PbI2 nanoflakes by solvent evaporation suppression for high-performance UV photodetectors. Small, 15, 1901767(2019).

[4] SUN Y, YIN Y, POLS M et al. Engineering the phases and heterostructures of ultrathin hybrid perovskite nanosheets. Advanced Materials, 32, 2002392(2020).

[5] HSUEH H C, CHEN R K, VASS H et al. Compression mechanisms in quasimolecular XI3 （X=As， Sb， Bi） solids. Physical Review B, 58, 14812-14822(1998).

[6] KĘPIŃSKA M, NOWAK M, DUKA P et al. Optical properties of SbI3 single crystalline platelets. Optical Materials, 33, 1753-1759(2011).

[7] KĘPIŃSKA M, STARCZEWSKA A, BEDNARCZYK I et al. Fabrication and characterisation of SbI3-opal structures. Materials Letters, 130, 17-20(2014).

[8] MADY K A, EID A H, SOLIMAN W Z. Electrical conductivity of antimony triiodide single crystals. Journal of Materials Science Letters, 6, 251-253(1987).

[9] BHARATHI MOHAN D, PHILIP A, SUNANDANA C S. Iodization of antimony thin films： XRD， SEM and optical studies of nanostructured SbI3. Vacuum, 82, 561-565(2008).

[10] ONODERA T, BABA K, HITOMI K. Evaluation of antimony tri-iodide crystals for radiation detectors. Science and Technology of Nuclear Installations, 2018, 1532742(2018).

[11] SUN X X, LI C, HOU Q Y et al. Phase transition and electronic properties of SbI3： first-principles calculations. Modern Physics Letters B, 31, 1750200(2017).

[12] XING S Y, CHEN S X, FANG S X et al. Pressure-regulated photovoltaic response in antimony triiodide with asymmetric metal contact. Advanced Optical Materials, 12, 2401433(2024).

[13] LIU W W, ZHANG T, ZHAO B H et al. Facilitating the carrier transport kinetics at the CsPbBr3/carbon interface through SbX3 （X = Cl， Br， I） passivation. ACS Applied Materials & Interfaces, 14, 57362-57370(2022).

[14] CHAHKAMALI F O, FAGHIHI M R, MAGHSOODLOU M T. Introduction of antimony triiodide （SbI3） as a new and efficient catalyst for synthesis of polyfunctionalized piperidines. Research on Chemical Intermediates, 42, 8109-8117(2016).

[15] RAMACHANDRAN A A, KRISHNAN B, DEVASIA S et al. Photosensitive antimony triiodide thin films by rapid iodization of chemically deposited antimony sulfide. Materials Research Bulletin, 142, 111382(2021).

[16] TANG J, GE F X, CHEN J L et al. A droplet method for synthesis of multiclass ultrathin metal halides. Small, 19, 2301573(2023).

[17] XUE B F, FU Z W, LI H et al. Cheap and environmentally benign electrochemical energy storage and conversion devices based on AlI3 electrolytes. Journal of the American Chemical Society, 128, 8720-8721(2006).