[1] P C RATH, D SAIKIA, M MISHRA et al. Exceptional catalytic performance of ultrafine Cu₂O nanoparticles confined in cubic mesoporous carbon for 4-nitrophenol reduction. Applied Surface Science, 427, 1217-1226(2018).

[2] H NIU, S LIU, Y CAI et al. MOF derived porous carbon supported Cu/Cu₂O composite as high performance non-noble catalyst. Microporous and Mesoporous Materials, 219, 48-53(2016).

[3] M ROCHA, P COSTA, C PEREIRA et al. L-serine-functionalized montmorillonite decorated with Au nanoparticles: a new highly efficient catalyst for the reduction of 4-nitrophenol. Journal of Catalysis, 361, 143-155(2018).

[4] M MAHAM, M NASROLLAHZADEH, S M SAJADI et al. Biosynthesis of Ag/reduced graphene oxide/Fe₃O₄ using Lotus garcinii leaf extract and its application as a recyclable nanocatalyst for the reduction of 4-nitrophenol and organic dyes. Journal of Colloid & Interface Science, 497, 33-42(2017).

[5] P P ZOU, M S WANG, L ZHAO et al. One-step synthesis of Pt@three-dimensional graphene composite hydrogel: an efficient recyclable catalyst for reduction of 4-nitrophenol. Applied Organometallic Chemistry, 30, 722-725(2016).

[6] F COCCIA, L TNUCCI, D BOSCO et al. One-pot synthesis of lignin-stabilised platinum and palladium nanoparticles and their catalytic behaviour in oxidation and reduction reaction. Green Chemistry, 14, 1073-1078(2012).

[7] N GACEM, P DIAO. Effect of solvent polarity on the assembly behavior of PVP coated rhodium nanoparticles. Colloids and Surfaces A, 417, 32-38(2013).

[8] X F YANG, A WANG, B QIAO et al. Single-atom catalysts: a new frontier in heterogeneous catalysis. Accounts of Chemical Research, 46, 1740-1748(2013).

[9] S D OH, M R KIM, S H CHOI et al. Radiolytic synthesis of Pd-M (M=Ag, Au, Cu, Ni and Pt) alloy nanoparticles and their use in reduction of 4-nitrophenol. Journal of Industrial and Engineering Chemistry, 14, 687-692(2008).

[10] P MUNNIK, JONGH P E DE, JONG K P DE. Recent developments in the synthesis of supported catalysts. Chemical Reviews, 46, 6687-6714(2015).

[11] X YAN, X WANG, Y TANG et al. Unusual loading-dependent sintering-resistant properties of gold nanoparticles supported within extra-large mesopores. Chemistry of Materials, 25, 1556-1563(2013).

[12] A NAG, K RAIDOGIA, K P HEMBRAM et al. Graphene analogues of BN: novel synthesis and properties. ACS Nano, 4, 1539-1544(2010).

[13] R LASKOWSKI, P BLAHA, K SCHWARZ. Bonding of hexagonal BN to transition metal surfaces: an ab initio density-functional theory study. Physical Review B Condensed Matter, 78, 1436-1446(2008).

[14] C HUANG, C CHEN, X YE et al. Stable colloidal boron nitride nanosheet dispersion and its potential application in catalysis. Journal of Materials Chemistry A, 1, 12192-12197(2013).

[15] M ZHENG, Y LIU, Y GU et al. Synthesis and characterization of boron nitride sponges as a novel support for metal nanoparticles. Science in China Series B: Chemistry, 51, 205-210(2008).

[16] H L LIANG. Research on the physical properties of fully hydrogenated boron nitride films. Jinan: Shandong University, 1-24(2012).

[17] C LI, T L WANG, Y Z WU et al. Fabrication of two-dimensional nanosheets via water freezing expansion exfoliation. Nanotechnology, 25, 1-6(2014).

[18] L GUARDIA, J I PAREDES, R ROZADA et al. Production of aqueous dispersions of inorganic graphene analogues by exfoliation and stabilization with non-ionic surfactants. RSC Advances, 4, 14115-14127(2014).

[19] Q LIU, N KAZUAKI, K KENSUKE et al. Effects of reaction parameters on the preparation of submicron Cu particles by liquid phase reduction method and the study of reaction mechanism. Powder Technology, 241, 98-104(2013).

[20] H SONG, T LI, J ZHANG et al. Highly anisotropic Sb₂Se₃ nanosheets: gentle exfoliation from the bulk precursors possessing 1D crystal structurep. Advanced Materials, 29, 1-7(2017).

[21] R J SMITH, P J KIBG, M LOTYA et al. Large-scale exfoliation of inorganic layered compounds in aqueous surfactant solutions. Advanced Materials, 23, 3944-3948(2011).

[22] P MA, J T SPENCER. Non-covalent stabilization and functionalization of boron nitride nanosheets (BNNSs) by organic polymers: formation of complex BNNSs-containing structures. Journal of Materials Science, 50, 313-323(2015).

[23] W GAO, Y ZHAO, H YIN. Lateral size selection of liquid exfoliated hexagonal boron nitride nanosheets. RSC Advances, 8, 5976-5983(2018).

[24] G HUMINIC, A HUMINIC. Application of nanofluids in heat exchangers: a review. Renewable & Sustainable Energy Reviews, 16, 5625-5638(2012).

[25] K S PARK, D Y LEE, K J KIM et al. Observation of a hexagonal BN surface layer on the cubic BN film grown by dual ion beam sputter deposition. Applied Physics Letters, 70, 315-317(1997).

[26] C D WAGNER, W M RIGGS, L E Davis et al. Muilenber, handbook of X-ray Photoelectron Spectroscopy. erkin Elmer Corporation Physical Electronics Division, USA, 1-190(1979).

[27] J P ESPINOS, J MORALES, A BARRANCO et al. Interface effects for Cu, CuO, and Cu₂O deposited on SiO₂ and ZrO₂. XPS determination of the valence state of copper in Cu/SiO₂ and Cu/ZrO₂ Catalysts. Journal of Physical Chemistry B, 106, 6921-6929(2002).

[28] Q SUN, Y LI, X SUN et al. Improved photoelectrical performance of single-crystal TiO₂ nanorod arrays by surface sensitization with copper quantum dots. ACS Sustainable Chemistry & Engineering, 1, 798-804(2013).

[29] X Y YAN, X L TONG, Y F ZHANG et al. Cuprous oxide nanoparticles dispersed on reduced graphene oxide as an efficient electrocatalyst for oxygen reduction reaction. Chemical Communications, 48, 1892-1894(2012).

[30] H MICHIKAZU, K TAKESHI, K MUTSUKO et al. Cu₂O as a photocatalyst for overall water splitting under visible light irradiation. Chemical Communication, 3, 357-358(1998).

[31] J HUANG, S VOGEHR, S TANG et al. Highly catalytic Pd-Ag bimetallic dendrites. Journal of Physical Chemistry C, 114, 15005-15010(2010).