[[1]]

Shao B, Liu X, Liu Z, Zeng G, Liang Q, Liang C, et al. A novel double Z-scheme photocatalyst Ag3PO4/Bi2S3/Bi2O3 with enhanced visible-light photocatalytic performance for antibiotic degradation. Chem Eng J 2019;368:730–45.

[[2]]

Shao B, Liu X, Liu Z, Zeng G, Zhang W, Liang Q, et al. Synthesis and characterization of 2D/0D g-C3N4/CdS-nitrogen doped hollow carbon spheres (NHCs) composites with enhanced visible light photodegradation activity for antibiotic. Chem Eng J 2019;374:479–93.

[[3]]

Fujishima A, Honda K. Electrochemical photolysis of water at a semiconductor electrode. Nature 1972;238(5358):37–8.

[[4]]

Yu S, Yun HJ, Kim YH, Yi J. Carbon-doped TiO2 nanoparticles wrapped with nanographene as a high performance photocatalyst for phenol degradation under visible light irradiation. Appl Catal B 2014;144:893–9.

[[5]]

Jiao X, Li X, Jin X, Sun Y, Xu J, Liang L, et al. Partially oxidized SnS2 atomic layers achieving efficient visible-light-driven CO2 reduction. J Am Chem Soc 2017;139(49):18044–51.

[[6]]

Tian J, Cheng N, Liu Q, Xing W, Sun X. Cobalt phosphide nanowires: efficient nanostructures for fluorescence sensing of biomolecules and photocatalytic evolution of dihydrogen from water under visible light. Angew Chem Int Ed Engl 2015;54(18):5493–7.

[[7]]

Su Z, Wang L, Grigorescu S, Lee K, Schmuki P. Hydrothermal growth of highly oriented single crystalline Ta2O5 nanorod arrays and their conversion to Ta3N5 for efficient solar driven water splitting. Chem Commun 2014;50 (98):15561–4.

[[8]]

Hisatomi T, Katayama C, Moriya Y, Minegishi T, Katayama M, Nishiyama H, et al. Photocatalytic oxygen evolution using BaNbO2N modified with cobalt oxide under photoexcitation up to 740 nm. Energy Environ Sci 2013;6 (12):3595–9.

[[9]]

Wang X, Maeda K, Thomas A, Takanabe K, Xin G, Carlsson JM, et al. A metalfree polymeric photocatalyst for hydrogen production from water under visible light. Nat Mater 2009;8(1):76–80.

[[10]]

Shao B, Liu Z, Zeng G, Wu Z, Liu Y, Cheng M, et al. Nitrogen-doped hollow mesoporous carbon spheres modified g-C3N4/Bi2O3 direct dual semiconductor photocatalytic system with enhanced antibiotics degradation under visible light. ACS Sustain Chem Eng 2018;6(12):16424–36.

[[11]]

Chiou YD, Hsu YJ. Room-temperature synthesis of single-crystalline Se nanorods with remarkable photocatalytic properties. Appl Catal B 2011;105 (1–2):211–9.

[[12]]

Liu G, Niu P, Yin L, Cheng HM. a-Sulfur crystals as a visible-light-active photocatalyst. J Am Chem Soc 2012;134(22):9070–3.

[[13]]

Liu G, Yin LC, Niu P, Jiao W, Cheng HM. Visible-light-responsive brhombohedral boron photocatalysts. Angew Chem Int Ed Engl 2013;52 (24):6242–5.

[[14]]

Xing M, Fang W, Yang X, Tian B, Zhang J. Highly-dispersed boron-doped graphene nanoribbons with enhanced conductibility and photocatalysis. Chem Commun 2014;50(50):6637–40.

[[15]]

Hu Z, Yuan L, Liu Z, Shen Z, Yu JC. An elemental phosphorus photocatalyst with a record high hydrogen evolution efficiency. Angew Chem Int Ed Engl 2016;55 (33):9580–5.

[[16]]

Vishnoi P, Gupta U, Pandey R, Rao CNR. Stable functionalized phosphorenes with photocatalytic HER activity. J Mater Chem A 2019;7(12):6631–7.

[[17]]

Zheng Y, Chen Y, Gao B, Chen J, Du Z, Lin B. Polymeric carbon nitride hybridized by CuInS2 quantum dots for photocatalytic hydrogen evolution. Mater Lett 2019;254:81–4.

[[18]]

Li L, Yu Y, Ye GJ, Ge Q, Ou X, Wu H, et al. Black phosphorus field-effect transistors. Nat Nanotechnol 2014;9(5):372–7.

[[19]]

Huang YC, Chen X, Wang C, Peng L, Qian Q, Wang SF. Layer-dependent electronic properties of phosphorene-like materials and phosphorene-based van der Waals heterostructures. Nanoscale 2017;9(25):8616–22.

[[20]]

Wang C, Peng L, Qian Q, Du J, Wang S, Huang Y. Tuning the carrier confinement in GeS/phosphorene van der Waals heterostructures. Small 2018;14 (10):201703536.

[[21]]

Rahman MZ, Kwong CW, Davey K, Qiao SZ. 2D phosphorene as a water splitting photocatalyst: fundamentals to applications. Energy Environ Sci 2016;9(3):709–28. Erratum in: Energy Environ Sci 2016;9(4):1513–4.

[[22]]

Feng R, Lei W, Liu G, Liu M. Visible- and NIR-light responsive blackphosphorus-based nanostructures in solar fuel production and environmental remediation. Adv Mater 2018;30(49):e1804770.

[[23]]

Muduli SK, Varrla E, Xu Y, Kulkarni SA, Katre A, Chakraborty S, et al. Evolution of hydrogen by few-layered black phosphorus under visible illumination. J Mater Chem A 2017;5(47):24874–9.

[[24]]

Li B, Lai C, Zeng G, Huang D, Qin L, Zhang M, et al. Black phosphorus, a rising star 2D nanomaterial in the post-graphene era: synthesis, properties, modifications, and photocatalysis applications. Small 2019;15(8):e1804565.

[[25]]

Sa B, Li YL, Qi J, Ahuja R, Sun Z. Strain engineering for phosphorene: the potential application as a photocatalyst. J Phys Chem C 2014;118 (46):26560–8.

[[26]]

Rahman MZ, Batmunkh M, Bat-Erdene M, Shapter JG, Mullins CB. p-Type BP nanosheet photocatalyst with AQE of 3.9% in the absence of a noble metal cocatalyst: investigation and elucidation of photophysical properties. J Mater Chem A 2018;6(38):18403–8.

[[27]]

Zhu X, Zhang T, Sun Z, Chen H, Guan J, Chen X, et al. Black phosphorus revisited: a missing metal-free elemental photocatalyst for visible light hydrogen evolution. Adv Mater 2017;29(17):201605776.

[[28]]

Tian B, Tian B, Smith B, Scott MC, Lei Q, Hua R, et al. Facile bottom-up synthesis of partially oxidized black phosphorus nanosheets as metal-free photocatalyst for hydrogen evolution. Proc Natl Acad Sci USA 2018;115(17):4345–50.

[[29]]

Zhao G, Wang T, Shao Y, Wu Y, Huang B, Hao X. A novel mild phase-transition to prepare black phosphorus nanosheets with excellent energy applications. Small 2017;13(7):201602243.

[[30]]

Liang Q, Liu X, Zeng G, Liu Z, Tang L, Shao B, et al. Surfactant-assisted synthesis of photocatalysts: mechanism, synthesis, recent advances and environmental application. Chem Eng J 2019;372:429–51.

[[31]]

Ran J, Wang X, Zhu B, Qiao SZ. Strongly interactive 0D/2D hetero-structure of a ZnxCd1xS nano-particle decorated phosphorene nano-sheet for enhanced visible-light photocatalytic H2 production. Chem Commun 2017;53 (71):9882–5.

[[32]]

Zhao H, Liu H, Sun R, Chen Y, Li X. A Zn0.5Cd0.5S photocatalyst modified by 2D black phosphorus for efficient hydrogen evolution from water. ChemCatChem 2018;10(19):4395–405.

[[33]]

Wu J, Huang S, Jin Z, Chen J, Hu L, Long Y, et al. Black phosphorus: an efficient co-catalyst for charge separation and enhanced photocatalytic hydrogen evolution. J Mater Sci 2018;53(24):16557–66.

[[34]]

Elbanna O, Zhu M, Fujitsuka M, Majima T. Black phosphorus sensitized TiO2 mesocrystal photocatalyst for hydrogen evolution with visible and nearinfrared light irradiation. ACS Catal 2019;9(4):3618–26.

[[35]]

Ran J, Zhu B, Qiao SZ. Phosphorene co-catalyst advancing highly efficient visible-light photocatalytic hydrogen production. Angew Chem Int Ed Engl 2017;56(35):10373–7.

[[36]]

Zhu M, Zhai C, Fujitsuka M, Majima T. Noble metal-free near-infrared-driven photocatalyst for hydrogen production based on 2D hybrid of black phosphorus/WS2. Appl Catal B 2018;221:645–51.

[[37]]

Yuan YJ, Wang P, Li Z, Wu Y, Bai W, Su Y, et al. The role of bandgap and interface in enhancing photocatalytic H2 generation activity of 2D–2D black phosphorus/MoS2 photocatalyst. Appl Catal B 2019;242:1–8.

[[38]]

Tian B, Tian B, Smith B, Scott MC, Hua R, Lei Q, et al. Supported black phosphorus nanosheets as hydrogen-evolving photocatalyst achieving 5.4% energy conversion efficiency at 353 K. Nat Commun 2018;9(1):1397.

[[39]]

Liang Q, Shi F, Xiao X, Wu X, Huang K, Feng S. In situ growth of CoP nanoparticles anchored on black phosphorus nanosheets for enhanced photocatalytic hydrogen production. ChemCatChem 2018;10(10):2179–83.

[[40]]

Zhu M, Kim S, Mao L, Fujitsuka M, Zhang J, Wang X, et al. Metal-free photocatalyst for H2 evolution in visible to near-infrared region: black phosphorus/graphitic carbon nitride. J Am Chem Soc 2017;139(37):13234–42.

[[41]]

Ran J, Guo W, Wang H, Zhu B, Yu J, Qiao SZ. Metal-free 2D/2D phosphorene/gC3N4 van der Waals heterojunction for highly enhanced visible-light photocatalytic H2 production. Adv Mater 2018;30(25):1800128.

[[42]]

Kong LQ, Ji YJ, Dang ZZ, Yan JQ, Li P, Li YY, et al. g-C3N4 loading black phosphorus quantum dot for efficient and stable photocatalytic H2 generation under visible light. Adv Funct Mater 2018;28(22):1800668.

[[43]]

Lei W, Mi Y, Feng R, Liu P, Hu S, Yu J, et al. Hybrid 0D–2D black phosphorus quantum dots-graphitic carbon nitride nanosheets for efficient hydrogen evolution. Nano Energy 2018;50:552–61.

[[44]]

Song T, Zeng G, Zhang P, Wang T, Ali A, Huang S, et al. 3D reticulated carbon nitride materials high uniformly capture 0D black phosphorus as /0D composites for stable and efficient photocatalytic hydrogen evolution. J Mater Chem A 2019;7(2):503–12.

[[45]]

Zhu M, Osakada Y, Kim S, Fujitsuka M, Majima T. Black phosphorus: a promising two dimensional visible and near-infrared-activated photocatalyst for hydrogen evolution. Appl Catal B 2017;217:285–92.

[[46]]

Hu J, Chen D, Mo Z, Li N, Xu Q, Li H, et al. Z-scheme 2D/2D heterojunction of black phosphorus/monolayer Bi2WO6 nanosheets with enhanced photocatalytic activities. Angew Chem Int Ed Engl 2019;58(7):2073–7.

[[47]]

Zhu M, Sun Z, Fujitsuka M, Majima T. Z-scheme photocatalytic water splitting on a 2D heterostructure of black phosphorus/bismuth vanadate using visible light. Angew Chem Int Ed Engl 2018;57(8):2160–4.

[[48]]

Zhu M, Cai X, Fujitsuka M, Zhang J, Majima T. Au/La2Ti2O7 nanostructures sensitized with black phosphorus for plasmon-enhanced photocatalytic hydrogen production in visible and near-infrared light. Angew Chem Int Ed 2017;56(8):2064–8.

[[49]]

Cai X, Mao L, Yang S, Han K, Zhang J. Ultrafast charge separation for full solar spectrum-activated photocatalytic H2 generation in a black phosphorus–Au– CdS heterostructure. ACS Energy Lett 2018;3(4):932–9.

[[50]]

Mao L, Cai X, Yang S, Han K, Zhang J. Black phosphorus–CdS–La2Ti2O7 ternary composite: effective noble metal-free photocatalyst for full solar spectrum activated H2 production. Appl Catal B 2019;242:441–8.

[[51]]

Reddy DA, Kim EH, Gopannagari M, Kim Y, Kumar DP, Kim TK. Few layered black phosphorus/MoS2 nanohybrid: a promising co-catalyst for solar driven hydrogen evolution. Appl Catal B 2019;241:491–8.

[[52]]

Boppella R, Yang W, Tan J, Kwon HC, Park J, Moon J. Black phosphorus supported Ni2P co-catalyst on graphitic carbon nitride enabling simultaneous boosting charge separation and surface reaction. Appl Catal B 2019;242:422–30.

[[53]]

Wen M, Wang J, Tong R, Liu D, Huang H, Yu Y, et al. A low-cost metal-free photocatalyst based on black phosphorus. Adv Sci 2019;6(1):1801321.

[[54]]

Yan J, Ji Y, Kong L, Li Y, Navlani-García M, Liu S, et al. Black phosphorus-based compound with few layers for photocatalytic water oxidation. ChemCatChem 2018;10(16):3424–8.

[[55]]

Wang H, Yang X, Shao W, Chen S, Xie J, Zhang X, et al. Ultrathin black phosphorus nanosheets for efficient singlet oxygen generation. J Am Chem Soc 2015;137(35):11376–82.

[[56]]

Wang H, Jiang S, Shao W, Zhang X, Chen S, Sun X, et al. Optically switchable photocatalysis in ultrathin black phosphorus nanosheets. J Am Chem Soc 2018;140(9):3474–80.

[[57]]

Pan S, He J, Wang C, Zuo Y. Exfoliation of two-dimensional phosphorene sheets with enhanced photocatalytic activity under simulated sunlight. Mater Lett 2018;212:311–4.

[[58]]

Yuan YJ, Yang S, Wang P, Yang Y, Li Z, Chen D, et al. Bandgap-tunable black phosphorus quantum dots: visible-light-active photocatalysts. Chem Commun 2018;54(8):960–3.

[[59]]

Li X, Li F, Lu X, Zuo S, Zhuang Z, Yao C. Black phosphorus quantum dots/ attapulgite nanocomposite with enhanced photocatalytic performance. Funct Mater Lett 2017;10(6):1750078.

[[60]]

Yan J, Verma P, Kuwahara Y, Mori K, Yamashita H. Recent progress on black phosphorus-based materials for photocatalytic water splitting. Small Methods 2018;2(12):1800212.

[[61]]

Lei W, Zhang T, Liu P, Rodriguez JA, Liu G, Liu M. Bandgap- and local fielddependent photoactivity of Ag/black phosphorus nanohybrids. ACS Catal 2016;6(12):8009–20.

[[62]]

Liu Y, Zhou M, Zhang W, Chen K, Mei A, Zhang Y, et al. Enhanced photocatalytic properties of TiO2 nanosheets@2D layered black phosphorus composite with high stability under hydro-oxygen environment. Nanoscale 2019;11 (12):5674–83.

[[63]]

Lee HU, Lee SC, Won J, Son BC, Choi S, Kim Y, et al. Stable semiconductor black phosphorus (BP)@titanium dioxide (TiO2) hybrid photocatalysts. Sci Rep 2015;5(1):8691.

[[64]]

He C, Qian H, Li X, Yan X, Zuo S, Qian J, et al. Visible-light-driven CeO2/black phosphorus heterostructure with enhanced photocatalytic performance. J Mater Sci Mater Electron 2019;30(1):593–9.

[[65]]

Feng R, Lei W, Sui X, Liu X, Qi X, Tang K, et al. Anchoring black phosphorus quantum dots on molybdenum disulfide nanosheets: a 0D/2D nanohybrid with enhanced visible- and NIR-light photoactivity. Appl Catal B 2018;238:444–53.

[[66]]

Wang L, Xu Q, Xu J, Weng J. Synthesis of hybrid nanocomposites of ZIF-8 with two-dimensional black phosphorus for photocatalysis. RSC Adv 2016;6 (73):69033–9.

[[67]]

Shen Z, Sun S, Wang W, Liu J, Liu Z, Yu JC. A black–red phosphorus heterostructure for efficient visible-light-driven photocatalysis. J Mater Chem A 2015;3(7):3285–8.

[[68]]

He D, Zhang Z, Qu J, Yuan X, Guan J. Facile one-step synthesis of black phosphorus via microwave irradiation with excellent photocatalytic activity. Part Part Syst Charact 2018;35(11):1800306.

[[69]]

Qiu P, Xu C, Zhou N, Chen H, Jiang F. Metal-free black phosphorus nanosheetsdecorated graphitic carbon nitride nanosheets with C–P bonds for excellent photocatalytic nitrogen fixation. Appl Catal B 2018;221:27–35.

[[70]]

Zheng Y, Yu Z, Ou H, Asiri AM, Chen Y, Wang X. Black phosphorus and polymeric carbon nitride heterostructure for photoinduced molecular oxygen activation. Adv Funct Mater 2018;28(10):1705407.

[[71]]

Zhu X, Zhang T, Jiang D, Duan H, Sun Z, Zhang M, et al. Stabilizing black phosphorus nanosheets via edge-selective bonding of sacrificial C60 molecules. Nat Commun 2018;9(1):4177.

[[72]]

Zhang Z, He D, Liu H, Ren M, Zhang Y, Qu J, et al. Synthesis of graphene/black phosphorus hybrid with highly stable P–C bond towards the enhancement of photocatalytic activity. Environ Pollut 2019;245:950–6.

[[73]]

Wang X, Xiang Y, Zhou B, Zhang Y, Wu J, Hu R, et al. Enhanced photocatalytic performance of Ag/TiO2 nanohybrid sensitized by black phosphorus nanosheets in visible and near-infrared light. J Colloid Interface Sci 2019;534:1–11.

[[74]]

Wang X, Zhou B, Zhang Y, Liu L, Song J, Hu R, et al. In-situ reduction and deposition of Ag nanoparticles on black phosphorus nanosheets co-loaded with graphene oxide as a broad spectrum photocatalyst for enhanced photocatalytic performance. J Alloys Compd 2018;769:316–24.

[[75]]

Hu J, Ji Y, Mo Z, Li N, Xu Q, Li Y, et al. Engineering black phosphorus to porous g-C3N4–metal–organic framework membrane: a platform for highly boosting photocatalytic performance. J Mater Chem A 2019;7(9):4408–14.

[[76]]

Han C, Li J, Ma Z, Xie H, Waterhouse GIN, Ye L, et al. Black phosphorus quantum dot/g-C3N4 composites for enhanced CO2 photoreduction to CO. Sci Chin Mater 2018;61(9):1159–66.

[[77]]

Hu J, Guo Z, McWilliams PE, Darges JE, Druffel DL, Moran AM, et al. Band gap engineering in a 2D material for solar-to-chemical energy conversion. Nano Lett 2016;16(1):74–9.

[[78]]

Bai L, Wang X, Tang S, Kang Y, Wang J, Yu Y, et al. Black phosphorus/platinum heterostructure: a highly efficient photocatalyst for solar-driven chemical reactions. Adv Mater 2018;30(40):1803641.

[[79]]

Zhou Q, Chen Q, Tong Y, Wang J. Light-induced ambient degradation of fewlayer black phosphorus: mechanism and protection. Angew Chem Int Ed Engl 2016;55(38):11437–41.

[[80]]

Tang X, Liang W, Zhao J, Li Z, Qiu M, Fan T, et al. Fluorinated phosphorene: electrochemical synthesis, atomistic fluorination, and enhanced stability. Small 2017;13(47):201702739.

[[81]]

Liu Y, Liu Z, Huang D, Cheng M, Zeng G, Lai C, et al. Metal or metal-containing nanoparticle@MOF nanocomposites as a promising type of photocatalyst. Coord Chem Rev 2019;388:63–78.