[1] MONTALTI M, CREDI A, PRODI L, et al. Hbook of photochemistry[M]. 3rd ed. Boca Raton: CRC Press, 2006.
[2] SCHULZE T F, SCHMIDT T W. Photochemical upconversion: present status and prospects for its application to solar energy conversion[J]. Energy & Environmental Science, 8, 103-125(2015).
[3] HAN Y Y, LUO X, LAI R C, et al. Visible-light-driven sensitization of naphthalene triplets using quantum-confined CsPbBr3 nanocrystals[J]. The Journal of Physical Chemistry Letters, 10, 1457-1463(2019).
[4] HUANG Z Y, LI X, YIP B D, et al. Nanocrystal size and quantum yield in the upconversion of green to violet light with CdSe and anthracene derivatives[J]. Chemistry of Materials, 27, 7503-7507(2015).
[5] LI X, HUANG Z Y, ZAVALA R, et al. Distance-dependent triplet energy transfer between CdSe nanocrystals and surface bound anthracene[J]. The Journal of Physical Chemistry Letters, 7, 1955-1959(2016).
[6] XU Z H, JIN T, HUANG Y M, et al. Direct triplet sensitization of oligothiophene by quantum dots[J]. Chemical Science, 10, 6120-6124(2019).
[7] NIENHAUS L, WU M F, GEVA N, et al. Speed limit for triplet-exciton transfer in solid-state PbS nanocrystal-sensitized photon upconversion[J]. ACS Nano, 11, 7848-7857(2017).
[8] PAPA C M, GARAKYARAGHI S, GRANGER D B, et al. TIPS-pentacene triplet exciton generation on PbS quantum dots results from indirect sensitization[J]. Chemical Science, 11, 5690-5696(2020).
[10] IZAKURA S, GU W T, NISHIKUBO R, et al. Photon upconversion through a cascade process of two-photon absorption in CsPbBr3 and triplet-triplet annihilation in porphyrin/diphenylanthracene[J]. The Journal of Physical Chemistry C, 122, 14425-14433(2018).
[11] NIENHAUS L, CORREA-BAENA J P, WIEGHOLD S, et al. Triplet-sensitization by lead halide perovskite thin films for near-infrared-to-visible upconversion[J]. ACS Energy Letters, 4, 888-895(2019).
[12] RAIŠYS S, JURŠENAS S, SIMON Y C, et al. Enhancement of triplet-sensitized upconversion in rigid polymers via singlet exciton sink approach[J]. Chemical Science, 9, 6796-6802(2018).
[13] WIEGHOLD S, BIEBER A S, VANORMAN Z A, et al. Influence of triplet diffusion on lead halide perovskite-sensitized solid-state upconversion[J]. The Journal of Physical Chemistry Letters, 10, 3806-3811(2019).
[14] WU M F, CONGREVE D N, WILSON M W B, et al. Solid-state infrared-to-visible upconversion sensitized by colloidal nanocrystals[J]. Nature Photonics, 10, 31-34(2016).
[15] GHOSH I, SHAIKH R S, KÖNIG B. Sensitization-initiated electron transfer for photoredox catalysis[J]. Angewandte Chemie International Edition, 56, 8544-8549(2017).
[16] RAVETZ B D, PUN A B, CHURCHILL E M, et al. Photoredox catalysis using infrared light via triplet fusion upconversion[J]. Nature, 565, 343-346(2019).
[17] HU H W, MEIER F, ZHAO D M, et al. Efficient room-temperature phosphorescence from organic-inorganic hybrid perovskites by molecular engineering[J]. Advanced Materials, 30, 1707621(2018).
[18] LUO X, LAI R C, LI Y L, et al. Triplet energy transfer from CsPbBr3 nanocrystals enabled by quantum confinement[J]. Journal of the American Chemical Society, 141, 4186-4190(2019).
[19] YOUNTS R, DUAN H S, GAUTAM B, et al. Efficient generation of long-lived triplet excitons in 2D hybrid perovskite[J]. Advanced Materials, 29, 1604278(2017).
[20] BOHN B J, TONG Y, GRAMLICH M, et al. Boosting tunable blue luminescence of halide perovskite nanoplatelets through postsynthetic surface trap repair[J]. Nano Letters, 18, 5231-5238(2018).
[22] SHAMSI J, KUBICKI D, ANAYA M, et al. Stable hexylphosphonate-capped blue-emitting quantum-confined CsPbBr3 nanoplatelets[J]. ACS Energy Letters, 5, 1900-1907(2020).
