首页|期刊导航|无机材料学报|BNNS/聚硼氮烷杂化先驱体转化BN纤维中的纳米片尺寸效应

BNNS/聚硼氮烷杂化先驱体转化BN纤维中的纳米片尺寸效应OA

Size Effect of Nanosheet on BN Fibers Derived from BNNS/Polyborazine Hybrid Precursor

中文摘要英文摘要

BN陶瓷纤维因其优异的耐高温、导热和透波性能,在高温透波及半导体领域具有广泛的应用前景.但目前制备得到的 BN 陶瓷纤维结晶度较低,无法充分展现 h-BN 晶体结构所具有的优异性能.本工作基于 BN 纳米片(BNNS)作为异质成核剂能够加速基底材料结晶的机制,采用一步球磨法制备了三种横向尺寸(0.5、2、4 μm)的氨基功能化 BNNS;再通过化学键合方式将氨基功能化的 BNNS 接枝至聚硼氮烷先驱体分子链中,制备了 BNNS/聚硼氮烷杂化先驱体,最终转化为高结晶、高强度 BN 陶瓷纤维.本工作详细探究了 BNNS 横向尺寸对先驱体分子结构、理化性能及纺丝性能的影响,探索了BNNS横向尺寸-BN陶瓷纤维微结构-BN陶瓷纤维力学性能三者间的构效关系.结果表明,增大BNNS尺寸能够提高先驱体陶瓷产率(最高可达 64.1%),但同时会破坏先驱体熔融纺丝稳定性.研究发现,改变 BNNS 尺寸能够有效调控最终陶瓷纤维晶体结构,改善纤维力学性能.BNNS 尺寸与最终BN陶瓷纤维的结晶度、晶粒尺寸及其力学性能不呈线性关系.虽然BNNS造成纤维表面凸起,导致含 2 μm BNNS的BN陶瓷纤维平均拉伸强度(0.90 GPa)略低,但其结晶度(94%)、h-BN晶粒尺寸(12.5 nm)以及密度(2.00 g/cm3)均达到最高.0.5 μm BNNS接枝的BN陶瓷纤维因兼具较高的结晶度(90%)和光滑的纤维表面,表现出最出色的力学强度(平均拉伸强度0.94 GPa).本工作为后续精细化调控纤维微结构以及制备高性能BN陶瓷纤维提供了重要的参考价值.

BN ceramic fibers exhibit significant potential for applications in high-temperature wave-transparent and semiconductor fields,due to their excellent resistance to high temperatures and thermal conductivity,as well as their outstanding wave-transparent performance.However,the low crystallinity observed in BN ceramic fibers inhibits complete realization of their potential superior properties associated with the h-BN crystal structure.In this work,based on the mechanism that inorganic nanofillers could act as heterogeneous nucleating agents to accelerate matrix crystallization,three lateral sizes(0.5,2 and 4 μm)of amino-functionalized BN nanosheets(BNNSs)were prepared utilizing a one-step ball milling method.BNNSs were chemically bonded to molecular chain of polyborazine to synthesize hybrid BNNS/polyborazine precursors,which were finally derived into high-performance BN ceramic fibers with high crystallinity.This investigation thoroughly explored the scale effects of BNNS on the molecular structure of hybrid precursor,as well as their physicochemical properties and melt spinning performance.Relationship among the BNNSs'size,microstructure and mechanical properties was elucidated.Increasing BNNSs size could enhance the ceramic yield of precursor(up to 64.1%),but destroy the viscosity-time stability.Moreover,it was demonstrated that BNNS scale could evidently regulate crystal structure of BN ceramic fibers.Relationship among the BNNSs'lateral sizes,crystal structure and mechanical performance was determined to be non-linear.BN ceramic fibers containing 2 μm BNNS displayed the highest crystallinity(94%),grain size(12.5 nm)and density(2.00 g/cm3).However,surface defects associated with 2 μm BNNS resulted in a non-optimal average tensile strength(0.90 GPa).BN ceramic fibers doped with 0.5 μm BNNS exhibited the best average tensile strength(0.94 GPa),attributed to the favorable combination of high crystallinity and smooth surface.This work could provide crucial references for fine regulation of microstructure and preparation of high-performance BN ceramic fibers.

张韵铂;王兵;李威;宋曲之;杜贻昂;王应德

国防科技大学 新型陶瓷纤维及其复合材料重点实验室,长沙 410073国防科技大学 新型陶瓷纤维及其复合材料重点实验室,长沙 410073国防科技大学 新型陶瓷纤维及其复合材料重点实验室,长沙 410073国防科技大学 新型陶瓷纤维及其复合材料重点实验室,长沙 410073国防科技大学 新型陶瓷纤维及其复合材料重点实验室,长沙 410073国防科技大学 新型陶瓷纤维及其复合材料重点实验室,长沙 410073

化学化工

BN陶瓷纤维晶体结构力学性能BN纳米片BNNS尺寸效应

BN ceramic fibercrystal structuremechanical propertyBN nanosheetBNNS size effect

《无机材料学报》 2026 (3)

359-369,中插7,12

国防科技大学(23-ZZCX-JDZ-38)湖南省自然科学基金(2023JJ40673)National University of Defense Technology(23-ZZCX-JDZ-38)Hunan Provincial Natural Science Foundation(2023JJ40673)

10.15541/jim20250275

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