Preparation and Application of Boron Nitride Aerogels

Fengqi LIU; Jian FENG; Yonggang JIANG; Liangjun LI

doi:10.15541/jim20190628

[2] M DU, Y LI, R ZHANG G. Progress in preparation and application of boron nitride nanosheets. Inorganic Chemicals Industry, 51, 8(2019).

[3] Z WANG G. Summarization about the peculiarities of cBN. Jewellery Science and Technology, 17, 41-45(2005).

[4] Z WANG G. Synthesis and structure transformation of wBN under HPHT. Inorganic Chemicals Industry, 18, 21-24(2006).

[5] P YANG Y, B LI, Y ZHANG C. The Morphology, synthesis, properties, and applications of graphene-like two-dimensional h-BN nanomaterials. Materials Review, 30, 143-148(2016).

[6] A PAKDEL, Y BANDO, D GOLBERG. Nano boron nitride flatland. Chemistry Society Reviews, 43, 934-959(2014).

[7] Y LIN, W CONNELL J. Advances in 2D boron nitride nanostructures: nanosheets, nanoribbons, nanosheets, and hybrids with graphene. Nanoscale, 4, 6908-6939(2012).

[8] Y ZHI C, Y BANDO, C TANG C. Large-scale fabrication of boron nitride nanosheets and their utilization in polymeric composites with improved thermal and mechanical properties.. Advanced Materials, 21, 2889-2893(2009).

[9] Y ZHAO, J WU X, L YANG J. Oxidation of a two-dimensional hexagonal boron nitride monolayer: a first-principles study.. Physical Chemistry Chemical Physics, 14, 5545-5550(2012).

[10] K WATANABE, T TANIGUCHI, H KANDA. Direct-bandgap properties and evidence for ultraviolet lasing of hexagonal boron nitride single crystal. Nature Materials, 3, 404-409(2004).

[11] H LI L, Y CHEN. Atomically thin boron nitride: unique properties and applications. Advanced Functianal Materials, 26, 2594-2608(2016).

[12] M DUAN X, H YANG J, J WANG Y et al. Research and application progress of hexagonal boron nitride (h-BN) based composite ceramics. Materials China, 34, 770-782(2015).

[13] F JIANG X, Q WENG, B WANG X. Recent progress on fabrications and applications of boron nitride nanomaterials: a review. Journal of Materials Science & Technology, 31, 589-598(2015).

[14] S NICOLA H U. Aerogels-airy materials: chemistry, structure, and properties. Angewandte Chemie International Edition, 37, 22-45(1998).

[15] Y XIAO Y, G JIANG Y, Z FENG J. Research progress of polyurethane based aerogel insulation materials. Materials Review, 32, 449-453(2018).

[16] Y LUO, G JIANG Y, Z FENG J et al. Progress on the preparation of SiO₂ aerogel composites by ambient pressure drying technique. Materials Review, 32, 780-787(2018).

[17] K WATANABE, T TANIGUCHI, H KANDA. Direct-bandgap properties and evidence for ultraviolet lasing of hexagonal boron nitride single crystal. Nature Materials, 3, 404(2004).

[18] Y MENG, J CHEN J, X LIANG W et al. Progress in catalysis of hexagonal boron nitride and boron nitride nanosheets. Journal of Southwest University for Nationalities (Natural Science Edition), 41, 331-337(2015).

[19] J LI, J LI L, F GAO Y et al. Preparation of nanomaterials employing template method. Materials Review, 2011, 5-9.

[20] X RUAN, L DONG, J YU et al. The progress of nanomaterials prepared in the presence of soft template. Materials Review, 26, 56-60(2012).

[21] Q WENG, X WANG, Y BANDO et al. One-step template-free synthesis of highly porous boron nitride microsponges for hydrogen storage. Advanced Energy Materials, 4, 130-152(2014).

[22] J DAI, X WU, J YANG et al. Unusual metallic microporous boron nitride networks. Journal of Physical Chemistry Letters, 4, 3484-3488(2013).

[23] J DAI, X WU, J YANG et al. Porous boron nitride with tunable pore size. Journal of Physical Chemistry Letters, 5, 393-398(2014).

[24] Q HAN W, R BRUTCHEY, D TILLEY T et al. Activated boron nitride derived from activated carbon. Nano Letters, 4, 173-176(2004).

[25] B RUSHTON, R MOKAYA. Mesoporous boron nitride and boron- nitride-carbon materials from mesoporous silica templates. Journal of Materials Chemistry, 18, 235-241(2007).

[26] X XU, Q ZHANG Q, L HAO M et al. Double-negative-index ceramic aerogels for thermal superinsulation. Science, 363, 723-727(2019).

[27] Q ZHANG, X XU, D LIN et al. Hyperbolically patterned 3D graphene metamaterial with negative poisson ratio and superelasticity. Advanced Materials, 28, 2229-2237(2016).

[28] G KUTTY R, S SREEJITH, X KONG et al. A topologically substituted boron nitride hybrid aerogel for highly selective CO₂ uptake. Nano Research, 11, 6325-6335(2018).

[29] J YIN, X LI, J ZHOU et al. Ultralight three-dimensional boron nitride foam with ultralow perm ittivity and superelasticity. Nano Letters, 13, 3232-3236(2013).

[30] G ALAUZUN J, S NGURN, N BRUN et al. Novel monolith-type boron nitride hierarchical foams obtained through integrative chemistry. Journal of Materials Chemistry, 21, 14025-14030(2011).

[31] F HUANG Y, E LIU H, Y WANG Z et al. Preparation of graphene aerogels with soft templates and their oil adsorption mechanism from water. Journal of Chemical Engineering of Chinese Universities, 26, 56-60(2012).

[32] Y YAMAUCHI, K KURODA. Rational design of mesoporous metals and related nanomaterials by a soft-template approach. Chemistry - An Asian Journal, 3, 664-676(2010).

[33] H WANG, G FAN, C ZHENG et al. Facile sodium alginate assisted assembly of Ni/Al layered double hydroxide nanostructures. Industrial & Engineering Chemistry Research, 49, 2759-2767(2010).

[34] R XIU, L DONG, U JING Y et al. The progress of nanomaterials prepared in the presence of soft template. Materials Review, 1, 56-60(2012).

[35] S BERNARD, P MIELE. Nanostructured and architectured boron nitride from boron, nitrogen and hydrogen-containing molecular and polymeric precursors. Materials Today, 17, 443-450(2014).

[36] L MALENFANT P R, J WAN, T TAYLOR S et al. Self-assembly of an organic-inorganic block copolymer for nano-ordered ceramics. Nature Nanotechnology, 2, 43-46(2007).

[37] H QIAN X, B LIU H, L LI Y. Self-assembly low dimensional inorganic/organic heterojunction nanomaterials. Chinese Science Bulletin, 1-14(2014).

[38] A KLOK H, S LECOMMANDOUX. Supramolecular materials via block copolymer self-assembly. Advanced Materials, 13, 1217-1229(2010).

[39] A CIFERRI. Assembling nano and macrostructures and the supramolecular liquid crystal. Progress in Polymer Science, 20, 1081-1120(1995).

[40] M JUNG S, Y JUNG H, S DRESSELHAUS M et al. A facile route for 3D aerogels from nanostructured 1D and 2D materials. Scientific Reports, 2, 849(2013).

[41] Y LI G, Y ZHU M, B GONG W et al. Boron nitride aerogels with super-flexibility ranging from liquid nitrogen temperature to 1000 ℃. Advanced Functional Materials, 29, 1900188(2019).

[42] G GAO, W GAO, E CANNUCCIA et al. Artificially stacked atomic layers: toward new van der waals solids. Nano Letters, 12, 3518-3525(2012).

[43] H LI, J LIN, Y TAY R et al. Multifunctional and highly compressive cross-linker-free sponge based on reduced graphene oxide and boron nitride nanosheets. Chemical Engineering Journal, 328, 825-833(2017).

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

[45] X MENG, N LUN, Y QI et al. Low-temperature synthesis of meshy boron nitride with a large surface area. European Journal of Inorganic Chemistry, 2010, 3174-3178.

[46] L MENG X, N LUN, X QI Y et al. Simple synthesis of mesoporous boron nitride with strong cathodoluminescence emission. Journal of Solid State Chemistry, 184, 859-862(2011).

[47] W MENG, M LI, L XU et al. High yield synthesis of novel boron nitride submicro-boxes and their photocatalytic application under visible light irradiation. Catalysis Science & Technology, 1, 1159(2011).

[48] W LEI, D PORTEHAULT, D LIU et al. Porous boron nitride nanosheets for effective water cleaning. Nature Communications, 4, 1777(2016).

[49] Q ZHANG, X XIANG, L HUI et al. Mechanically robust honeycomb graphene aerogel multifunctional polymer composites. Carbon, 93, 659-670(2015).

[50] X SONG, L LIN, M RONG et al. Mussel-inspired, ultralight, multifunctional 3D nitrogen-doped graphene aerogel. Carbon, 80, 174-182(2014).

[51] H JHI S, K KWON Y. Hydrogen adsorption on boron nitride nanotubes: a path to room temperature hydrogen storage. Physical Review B, 69, 245407(2004).

[52] A HARLEY-TROCHIMCZYK, T PHAM, J CHANG et al. Gas sensors: platinum nanoparticle loading of boron nitride aerogel and its use as a novel material for low-power catalytic gas sensing. Advanced Functional Materials, 26(2016).

[53] T ZHENG M, L LIU Y, L GU Y et al. Synthesis and characterization of boron nitride sponges as a noveI support for metal nanoparticles. Science China Chemistry, 51, 205-210(2008).

[54] A PERDIGON-MELON J, A AUROUX, C GUIMON et al. Micrometric BN powders used as catalyst support: influence of the precursor on the properties of the BN ceramic. Journal of Solid State Chemistry, 177, 609-615(2004).

[55] M LI, Q JIANG, M YAN et al. Three-dimensional boron- and nitrogen-codoped graphene aerogel supported pt nanoparticles as highly active electrocatalysts for methanol oxidation reaction. ACS Sustainable Chemistry & Engineering, 6, 6644-6653(2018).

[56] Q WENG, Y IDE, X WANG et al. Design of BN porous sheets with richly exposed (002) plane edges and their application as TiO₂ visible light sensitizer. Nano Energy, 16, 19-27(2015).

[57] M LI, Q JIANG, M YAN et al. Three-dimensional boron- and nitrogen-codoped graphene aerogel supported Pt nanoparticles as highly active electrocatalysts for methanol oxidation reaction. ACS Sustainable Chemistry & Engineering, 6, 6644-6653(2018).

[58] D LIU, W LEI, S QIN et al. Template-free synthesis of functional 3D BN architecture for removal of dyes from water. Scientific Reports, 4, 4453(2014).

[59] H LI, J LIN, Y TAY R et al. Multifunctional and highly compressive cross-linker-free sponge based on reduced graphene oxide and boron nitride nanosheets. Chemical Engineering Journal, 328, 825-833(2017).

[60] H ZHAO, X SONG, H ZENG. 3D graphene foam scavengers: vesicant-assisted foaming boosts the gram-level yield and forms hierarchical pores for super-strong pollutant removal applications. NPG Asia Mater., 7, l68(2015).

[61] T PHAM, P GOLDSTEIN A, P LEWICK J et al. Nanoscale structure and superhydrophobicity of sp ²-bonded boron nitride aerogels. Nanoscale, 7, 10449-10458(2015).

[62] Y SONG, B LI, S YANG et al. Ultralight boron nitride aerogels via template-assisted chemical vapor deposition. Scientific Reports, 5, 10337(2015).

[63] Y XUE, P DAI, X JIANG et al. Template-free synthesis of boron nitride foam-like porous monoliths and their high-end applications in water purification. Journal of Materials Chemistry A, 4, 1469-1478(2016).

[64] F AN, X LI, P MIN et al. Highly anisotropic graphene/boron nitride hybrid aerogels with long-range ordered architecture and moderate density for highly thermally conductive composites. Carbon, 126, 119-127(2018).

[65] M NURUNNABI, M NAFIUJJAMAN, J LEE S et al. Preparation of ultrathin hexagonal boron nitride nanoplates for cancer cell imaging and neurotransmitter sensing. Chemical Communications, 52, 6146-6149(2016).

[66] S LU F, F WANG, L CAO et al. Hexagonal boron nitride nanomaterials: advances towards bio-applications. Nanoscience and Nanotechnology Letters, 4, 949-961(2012).

[67] Q WENG, B WANG, X WANG et al. Highly water-soluble, porous, and biocompatible boron nitrides for anticancer drug delivery. ACS Nano, 8, 6123-6130(2014).