氮化硼气凝胶的制备及其应用进展

doi:10.15541/jim20190628

摘要/Abstract

摘要：

氮化硼气凝胶是一类以固体为骨架、气体为分散介质的, 具有三维多孔网络结构的新型纳米材料, 展现出高比表面积、高孔隙率、低密度等优异的性能。此外, 相比于石墨烯气凝胶, 氮化硼气凝胶拥有更好的绝缘性、抗氧化性、热稳定性和化学稳定性, 因此它在气体吸附、催化、污水净化、导热/隔热等领域极具应用前景。本文结合国内外研究现状, 重点介绍了硬模板法、软模板法、低维氮化硼组装法和无模板法制备氮化硼气凝胶的结构和性能特点, 总结了其在关键领域的重要应用, 并对其未来发展方向进行了展望。

关键词: 氮化硼气凝胶, 吸附, 催化, 导热, 隔热, 综述

Abstract:

Boron nitride aerogel is a kind of new nanomaterials with three-dimensional porous network structure, which takes solid as the framework and gas as the dispersion medium. It has high specific surface area, high porosity, low density and other excellent properties. In addition, compared with graphene aerogels, it exhibits better insulation, oxidation resistance, thermal stability and chemical stability. These outstanding properties make it promising application in the fields of gas adsorption, catalysis, sewage purification, thermal insulation/conduction. This article systematically reviewed the preparation methods of boron nitride aerogels including the hard template method, soft template method, low-dimensional boron nitride assembly method, and template-free method in the light of domestic and foreign research status. Moreover, the important applications of boron nitride aerogels in key fields are summarized, and the future development direction is prospected.

Key words: boron nitride aerogels, adsorption, catalysis, thermal conductivity, thermal insulation, review

中图分类号:

TQ174

柳凤琦, 冯坚, 姜勇刚, 李良军. 氮化硼气凝胶的制备及其应用进展[J]. 无机材料学报, 2020, 35(11): 1193-1202.

LIU Fengqi, FENG Jian, JIANG Yonggang, LI Liangjun. Preparation and Application of Boron Nitride Aerogels[J]. Journal of Inorganic Materials, 2020, 35(11): 1193-1202.

图/表 13

图1 六方氮化硼分子结构示意图

Fig. 1 Molecular structure of hexagonal boron nitride

图2 (a, b)活性炭和(c, d)BN气凝胶的SEM照片[24]

Fig. 2 SEM images of (a, b) activated carbon and (c, d) BN aerogels[24]

图3 (a)双壁双曲线型BN气凝胶的制备流程示意图, (b)BN气凝胶与其他材料的密度对比, (c)BN气凝胶的相对高度、最大压力和杨氏模量与循环次数的关系曲线, (d)BN气凝胶在不同压力下的光学照片和SEM照片[26]

Fig. 3 (a) Schematic illustration of the metastructure design of BN aerogels; (b) The lightest hBN aerogels sample compared with other ultralight materials; (c) The ultimate stress, Young’s modulus, and relative height for 100 compression cycles; (d) Optical and SEM images of BN aerogels under different pressures[26]

图4 有机-无机杂化的嵌段共聚物聚降冰片烯-癸硼烷制备多孔BN流程示意图[36]

Fig. 4 Schematic illustration of organic-inorganic hybrid block copolymer polynorbornene-decorane for preparing BN aerogels[36]

图5 (a)超临界干燥法制备BN气凝胶流程示意图, (b)BN气凝胶、MoS2气凝胶和GA照片[40]

Fig. 5 (a) Schematic representation of aerogel production by a critical point drying method; (b) Picture of the as-obtained BN aerogels, MoS2 aerogels and GA[40]

图6 (a)冷冻干燥法制备纳米带状BN气凝胶流程示意图, (b,c)BN纳米带气凝胶在液氮和火焰中的柔韧性[41]

Fig. 6 (a) Schematic illustration of the freeze-drying method for preparing nano-ribbon BN aerogels; (b, c) The flexibility of BN nano-ribbon aerogels in liquid nitrogen and flame[41]

图7 无交联剂法制备rGO/BN复合气凝胶的流程示意图[43]

Fig. 7 Schematic illustration of the preparation procedure of crosslinking-free rGO/BN composite aerogels[43]

图8 BN气凝胶的(a,b)TEM照片及(c)微观结构示意图[21]

Fig. 8 (a,b) TEM images of BN aerogels and (c) schematic illustration of microstructure[21]

图9 (a)在273和298 K下, BN气凝胶对CO2和N2的吸收量及(b)相应的柱状图[28], (c)Pt纳米晶/BN气凝胶的SEM照片, (d)Pt纳米晶/BN气凝胶对丙烷的响应/恢复曲线[52]

Fig. 9 (a) The absorption of CO2 and N2 at 273 and 298 K by BN aerogel and (b) corresponding histograms[28]; (c) SEM image of Pt nanocrystals/BN aerogel; (d) Response/recovery curve of Pt nanocrystal/BN aerogel towards propane[52]

图10 (a)Pt/BN-GA催化剂的SEM照片[55], (b)Pt/BN-GA、Pt/GA、Pt/G和Pt/C的ECSA对比图和(c)电流-时间曲线[57]

Fig. 10 (a) SEM images of Pt/BN-GA catalyst[55]; (b) ECSA comparison chart of Pt/BN-GA, Pt/GA, Pt/G and Pt/C and (c) corresponding current-time curves[57]

图11 (a~d) rGO/BN气凝胶的润湿行为和吸油能力, (e) rGO/BN气凝胶吸收不同有机液体的能力, (f) rGO/BN气凝胶反复吸收己烷并在热处理(85℃)下释放其蒸汽的循环曲线, (g) rGO/BN气凝胶在反复吸收-挤压下吸收己烷的循环曲线[59]

Fig. 11 (a-d) The Wetting behaviour and oil absorption capacity of rGO/BN sponge; (e) The ability of rGO/BN sponge to absorb different organic liquids; (f) The rGO/BN sponge repetitively absorbed hexane and released its vapour under heat treatment (85 ℃); (g) Recyclability of the rGO/BN sponge for absorption of hexane under absorption-squeezing cycles[59]

图12 rGO/BN混合气凝胶的制备流程示意图[64]

Fig. 12 Schematic illustrating the fabrication of graphene/BN hybrid aerogels[64]

图13 层状双壁结构BN气凝胶的SEM照片[26]

Fig. 13 SEM images of the double-pane wall structure of BN aerogels[26] (a) hBNAG; (b) Double-pane wall structure of hBNAGs. Scale bars, 20 nm

参考文献 67

[1]	冯伟 . 不同衬底上氮化硼薄膜制备与场发射性质研究. 长春: 吉林大学硕士学位论文, 2004.
[2]	DU M, LI Y, ZHANG G R ,et al. Progress in preparation and application of boron nitride nanosheets. Inorganic Chemicals Industry, 2019,51(2):8.
[3]	WANG G Z . Summarization about the peculiarities of cBN. Jewellery Science and Technology, 2005,17(5):41-45.
[4]	WANG G Z . Synthesis and structure transformation of wBN under HPHT. Inorganic Chemicals Industry, 2006,18(4):21-24.
[5]	YANG Y P, LI B, ZHANG C Y ,et al. The Morphology, synthesis, properties, and applications of graphene-like two-dimensional h-BN nanomaterials. Materials Review, 2016,30(11):143-148.
[6]	PAKDEL A, BANDO Y, GOLBERG D . Nano boron nitride flatland. Chemistry Society Reviews, 2014,43(3):934-959. DOI URL
[7]	LIN Y, CONNELL J W . Advances in 2D boron nitride nanostructures: nanosheets, nanoribbons, nanosheets, and hybrids with graphene. Nanoscale, 2012,4(22):6908-6939. DOI URL
[8]	ZHI C Y, BANDO Y, TANG C C , et al. Large-scale fabrication of boron nitride nanosheets and their utilization in polymeric composites with improved thermal and mechanical properties. Advanced Materials, 2009,21(28):2889-2893. DOI URL
[9]	ZHAO Y, WU X J, YANG J L , et al. Oxidation of a two-dimensional hexagonal boron nitride monolayer: a first-principles study. Physical Chemistry Chemical Physics, 2012,14(16):5545-5550. DOI URL
[10]	WATANABE K, TANIGUCHI T, KANDA H . Direct-bandgap properties and evidence for ultraviolet lasing of hexagonal boron nitride single crystal. Nature Materials, 2004,3(6):404-409. DOI URL PMID
[11]	LI L H, CHEN Y . Atomically thin boron nitride: unique properties and applications. Advanced Functianal Materials, 2016,26(16):2594-2608.
[12]	DUAN X M, YANG J H, WANG Y J ,et al. Research and application progress of hexagonal boron nitride (h-BN) based composite ceramics. Materials China, 2015,34(10):770-782.
[13]	JIANG X F, WENG Q, WANG X B , et a1. Recent progress on fabrications and applications of boron nitride nanomaterials: a review. Journal of Materials Science & Technology, 2015,31(6):589-598. DOI URL
[14]	NICOLA H U S . Aerogels-airy materials: chemistry, structure, and properties. Angewandte Chemie International Edition, 1998,37(1/2):22-45. DOI URL
[15]	XIAO Y Y, JIANG Y G, FENG J Z ,et al. Research progress of polyurethane based aerogel insulation materials. Materials Review, 2018,32(1):449-453.
[16]	LUO Y, JIANG Y G, FENG J Z ,et al. Progress on the preparation of SiO₂ aerogel composites by ambient pressure drying technique. Materials Review, 2018,32(5):780-787.
[17]	WATANABE K, TANIGUCHI T, KANDA H . Direct-bandgap properties and evidence for ultraviolet lasing of hexagonal boron nitride single crystal. Nature Materials, 2004,3(6):404. DOI URL PMID
[18]	MENG Y, CHEN J J, LIANG W X ,et al. Progress in catalysis of hexagonal boron nitride and boron nitride nanosheets. Journal of Southwest University for Nationalities (Natural Science Edition), 2015,41(3):331-337.
[19]	LI J, LI L J, GAO Y F , et al. Preparation of nanomaterials employing template method. Materials Review, 2011(s2):5-9.
[20]	RUAN X, DONG L, YU J , et al. The progress of nanomaterials prepared in the presence of soft template. Materials Review, 2012,26(1):56-60.
[21]	WENG Q, WANG X, BANDO Y ,et al. One-step template-free synthesis of highly porous boron nitride microsponges for hydrogen storage. Advanced Energy Materials, 2014,4(7):130-152.
[22]	DAI J, WU X, YANG J ,et al. Unusual metallic microporous boron nitride networks. Journal of Physical Chemistry Letters, 2013,4(20):3484-3488. DOI URL
[23]	DAI J, WU X, YANG J , et al. Porous boron nitride with tunable pore size. Journal of Physical Chemistry Letters, 2014,5(2):393-398. DOI URL
[24]	HAN W Q, BRUTCHEY R, TILLEY T D ,et al. Activated boron nitride derived from activated carbon. Nano Letters, 2004,4(1):173-176. DOI URL
[25]	RUSHTON B, MOKAYA R . Mesoporous boron nitride and boron- nitride-carbon materials from mesoporous silica templates. Journal of Materials Chemistry, 2007,18(2):235-241. DOI URL
[26]	XU X, ZHANG Q Q, HAO M L , et al. Double-negative-index ceramic aerogels for thermal superinsulation. Science, 2019,363:723-727. DOI URL PMID
[27]	ZHANG Q, XU X, LIN D ,et al. Hyperbolically patterned 3D graphene metamaterial with negative poisson ratio and superelasticity. Advanced Materials, 2016,28(11):2229-2237. DOI URL PMID
[28]	KUTTY R G, SREEJITH S, KONG X , et al. A topologically substituted boron nitride hybrid aerogel for highly selective CO₂ uptake. Nano Research, 2018,11(12):6325-6335. DOI URL
[29]	YIN J, LI X, ZHOU J ,et al. Ultralight three-dimensional boron nitride foam with ultralow perm ittivity and superelasticity. Nano Letters, 2013,13(7):3232-3236. DOI URL PMID
[30]	ALAUZUN J G, NGURN S, BRUN N ,et al. Novel monolith-type boron nitride hierarchical foams obtained through integrative chemistry. Journal of Materials Chemistry, 2011,21(36):14025-14030. DOI URL
[31]	HUANG Y F, LIU H E, WANG Z Y ,et al. Preparation of graphene aerogels with soft templates and their oil adsorption mechanism from water. Journal of Chemical Engineering of Chinese Universities, 2012,26(1):56-60.
[32]	YAMAUCHI Y, KURODA K . Rational design of mesoporous metals and related nanomaterials by a soft-template approach. Chemistry - An Asian Journal, 2010,3(4):664-676. DOI URL
[33]	WANG H, FAN G, ZHENG C , et al. Facile sodium alginate assisted assembly of Ni/Al layered double hydroxide nanostructures. Industrial & Engineering Chemistry Research, 2010,49(6):2759-2767.
[34]	XIU R, DONG L, JING Y U , et al. The progress of nanomaterials prepared in the presence of soft template. Materials Review, 2012,1:56-60.
[35]	BERNARD S, MIELE P . Nanostructured and architectured boron nitride from boron, nitrogen and hydrogen-containing molecular and polymeric precursors. Materials Today, 2014,17(9):443-450. DOI URL
[36]	MALENFANT P R L, WAN J, TAYLOR S T ,et al. Self-assembly of an organic-inorganic block copolymer for nano-ordered ceramics. Nature Nanotechnology, 2007,2(1):43-46. DOI URL PMID
[37]	QIAN X H, LIU H B, LI Y L . Self-assembly low dimensional inorganic/organic heterojunction nanomaterials. Chinese Science Bulletin, 2014(1):1-14.
[38]	KLOK H A, LECOMMANDOUX S . Supramolecular materials via block copolymer self-assembly. Advanced Materials, 2010,13(16):1217-1229. DOI URL
[39]	CIFERRI A . Assembling nano and macrostructures and the supramolecular liquid crystal. Progress in Polymer Science, 1995,20(6):1081-1120. DOI URL
[40]	JUNG S M, JUNG H Y, DRESSELHAUS M S ,et al. A facile route for 3D aerogels from nanostructured 1D and 2D materials. Scientific Reports, 2013,2(11):849.
[41]	LI G Y, ZHU M Y, GONG W B , et al. Boron nitride aerogels with super-flexibility ranging from liquid nitrogen temperature to 1000 ℃. Advanced Functional Materials, 2019,29:1900188.
[42]	GAO G, GAO W, CANNUCCIA E ,et al. Artificially stacked atomic layers: toward new van der waals solids. Nano Letters, 2012,12(7):3518-3525. DOI URL
[43]	LI H, LIN J, TAY R Y , et al. Multifunctional and highly compressive cross-linker-free sponge based on reduced graphene oxide and boron nitride nanosheets. Chemical Engineering Journal, 2017,328:825-833. DOI URL
[44]	NAG A, RAIDONGIA K, HEMBRAM K P ,et al. Graphene analogues of BN: novel synthesis and properties. ACS Nano, 2010,4(3):1539-1544. DOI URL PMID
[45]	MENG X, LUN N, QI Y , et al. Low-temperature synthesis of meshy boron nitride with a large surface area. European Journal of Inorganic Chemistry, 2010(20):3174-3178. DOI URL
[46]	MENG X L, LUN N, QI Y X ,et al. Simple synthesis of mesoporous boron nitride with strong cathodoluminescence emission. Journal of Solid State Chemistry, 2011,184(4):859-862. DOI URL
[47]	MENG W, LI M, XU L ,et al. High yield synthesis of novel boron nitride submicro-boxes and their photocatalytic application under visible light irradiation. Catalysis Science & Technology, 2011,1(7):1159.
[48]	LEI W, PORTEHAULT D, LIU D ,et al. Porous boron nitride nanosheets for effective water cleaning. Nature Communications, 2016,4(2):1777. DOI URL
[49]	ZHANG Q, XIANG X, HUI L ,et al. Mechanically robust honeycomb graphene aerogel multifunctional polymer composites. Carbon, 2015,93:659-670. DOI URL
[50]	SONG X, LIN L, RONG M ,et al. Mussel-inspired, ultralight, multifunctional 3D nitrogen-doped graphene aerogel. Carbon, 2014,80(1):174-182. DOI URL
[51]	JHI S H, KWON Y K . Hydrogen adsorption on boron nitride nanotubes: a path to room temperature hydrogen storage. Physical Review B, 2004,69(24):245407.
[52]	HARLEY-TROCHIMCZYK A, PHAM T, CHANG J ,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, 2016,26(3):314.
[53]	ZHENG M T, LIU Y L, GU Y L ,et al. Synthesis and characterization of boron nitride sponges as a noveI support for metal nanoparticles. Science China Chemistry, 2008,51(3):205-210. DOI URL
[54]	PERDIGON-MELON J A, AUROUX A, GUIMON C ,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, 2004,177(2):609-615. DOI URL
[55]	LI M, JIANG Q, YAN M ,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, 2018,6:6644-6653.
[56]	WENG Q, IDE Y, WANG X , et al. Design of BN porous sheets with richly exposed (002) plane edges and their application as TiO₂ visible light sensitizer. Nano Energy, 2015,16:19-27. DOI URL
[57]	LI M, JIANG Q, YAN M , 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, 2018,6:6644-6653.
[58]	LIU D, LEI W, QIN S , et al. Template-free synthesis of functional 3D BN architecture for removal of dyes from water. Scientific Reports, 2014,4:4453. DOI URL PMID
[59]	LI H, LIN J, TAY R Y ,et al. Multifunctional and highly compressive cross-linker-free sponge based on reduced graphene oxide and boron nitride nanosheets. Chemical Engineering Journal, 2017,328:825-833. DOI URL
[60]	ZHAO H, SONG X, ZENG H . 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., 2015,7(3):l68.
[61]	PHAM T, GOLDSTEIN A P, LEWICK J P ,et al. Nanoscale structure and superhydrophobicity of sp ²-bonded boron nitride aerogels. Nanoscale , 2015,7(23):10449-10458. DOI URL PMID
[62]	SONG Y, LI B, YANG S ,et al. Ultralight boron nitride aerogels via template-assisted chemical vapor deposition. Scientific Reports, 2015,5:10337. DOI URL PMID
[63]	XUE Y, DAI P, JIANG X ,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, 2016,4(4):1469-1478. DOI URL
[64]	AN F, LI X, MIN P ,et al. Highly anisotropic graphene/boron nitride hybrid aerogels with long-range ordered architecture and moderate density for highly thermally conductive composites. Carbon, 2018,126:119-127. DOI URL
[65]	NURUNNABI M, NAFIUJJAMAN M, LEE S J , et al. Preparation of ultrathin hexagonal boron nitride nanoplates for cancer cell imaging and neurotransmitter sensing. Chemical Communications, 2016,52(36):6146-6149. DOI URL PMID
[66]	LU F S, WANG F, CAO L ,et al. Hexagonal boron nitride nanomaterials: advances towards bio-applications. Nanoscience and Nanotechnology Letters, 2012,4(10):949-961. DOI URL
[67]	WENG Q, WANG B, WANG X ,et al. Highly water-soluble, porous, and biocompatible boron nitrides for anticancer drug delivery. ACS Nano, 2014,8(6):6123-6130. DOI URL PMID