不同Ni含量镍包石墨的吸波性能研究OA
Microwave Absorption Properties of Nickel-coated Graphite with Different Ni Contents
目的 通过制备不同Ni含量镍包石墨/石蜡复合样品,探讨镍包石墨的介电性能、磁性能及吸波性能,确定最佳的比例与工艺,拓展镍包石墨在吸波材料领域的应用.方法 采用二次包覆的方法代替传统工艺,不采用贵金属活化,在石墨上进行化学镀镍研究,对镍包石墨复合粉体进行XRD(X射线衍射)分析和镀层形貌分析,使用矢量网络分析仪通过矩形波导方法测试镍包石墨复合粉末的电磁参数.结果 通过对比实验得知,随着镍含量升高,石墨表面的镍颗粒数量增多,颗粒之间彼此相互连接,镀层趋于致密,但镍含量过高时,游离镍增多,出现明显团聚,易引发爆发式形核;当Ni含量(质量分数)为 45%,样品厚度为1.6 mm时,镍包石墨/石蜡复合样品的反射率在频率为 10 GHz处可达-26.5 dB,在9.3~10.7 GHz范围内的反射损耗均低于-10 dB.结论 镀层致密并不利于镍包石墨的吸波性能,片状石墨表面分布适量不规则的镍颗粒,有利于改善镍包石墨的吸波性能;镍包石墨的吸波性能较好,未来有望拓展其在防辐射织物、特种面料等产业用纺织品领域的应用.
This research presents a novel and cost-effective electroless nickel plating process on graphite substrates,with a double encapsulation method used as a superior alternative to conventional techniques.A significant advantage of this method is its elimination of the need for precious metal activation,which is typically required to initiate the plating process in traditional approaches.The core methodology involves a two-stage reduction mechanism.Firstly,the nickel ions adsorbed onto the graphite surface undergo an initial reduction to form discrete active centers.Subsequently,a secondary reduction step is employed,where additional nickel ions are reduced preferentially around these established active centers,thereby facilitating the formation of a continuous and relatively dense nickel coating.The successful synthesis of the nickel-coated graphite composite powder is confirmed through comprehensive characterization,including X-ray diffraction(XRD)for phase identification and coating morphology analysis for microstructural evaluation. To systematically evaluate the functional properties,a series of nickel-coated graphite/paraffin composite samples are fabricated with precisely controlled variations in nickel content.The primary objective of this research is to investigate the influence of nickel loading on the resulting dielectric,magnetic,and ultimately,the microwave absorption properties.This investigation is crucial for determining the optimal compositional ratio and process parameters,thereby aiming to expand and optimize the application of nickel-coated graphite composites in high-performance microwave absorption materials.The electromagnetic parameters,namely the complex permittivity and the complex permeability,which are fundamental to the material's interaction with electromagnetic waves,are measured accurately.The measurements are conducted in the X-band frequency range(8.2-12.4 GHz),which is critical for many radar and telecommunications applications,with a vector network analyzer(Agilent Technologies E8362B)according to the standardized rectangular waveguide method.For the preparation of test specimens,the nickel-coated graphite powders with different Ni contents are used as functional fillers.These are uniformly mixed with paraffin,serving as a non-dispersive binder matrix,at a fixed mass fraction of 30%on a heated plate to ensure homogeneity.The resulting mixtures are then precision-pressed into rectangular samples with standardized dimensions of 22.86 mm in length,10.16 mm in width,and a thickness of 2.0 mm to fit the waveguide fixtures. The findings of this research provide detailed insights into the microstructure-property relationships.It is observed that as the nickel content increases,the population of nickel particles on the graphite surface correspondingly rises.These particles begin to interconnect with one another,causing the coating to evolve from a discrete island structure to a more continuous and denser film.However,a critical threshold is identified;when the nickel content is excessively high,it leads to an increase in free nickel,pronounced agglomeration of particles,and a phenomenon prone to explosive nucleation,which is detrimental to coating uniformity.The optimal microwave absorption performance is achieved with a specific Ni content of 45%and a reduced sample thickness of 1.6 mm.Under these optimized conditions,the composite sample exhibits a superior minimum reflection loss of-26.5 dB at a frequency of 10 GHz.Furthermore,it demonstrates an effective absorption bandwidth(defined as the frequency range where reflection loss is below-10 dB)spanning from 9.3 to 10.7 GHz.This research conclusively demonstrates that an excessively dense and continuous coating is,in fact,detrimental to the microwave absorption performance of nickel-coated graphite.The optimal performance is achieved when the flake graphite surface is decorated with an appropriate amount of discrete,irregular nickel particles,which enhances impedance matching and promotes multiple scattering and dissipation of incident microwave energy.The compelling microwave absorption properties and the facile,economical fabrication process of nickel-coated graphite,as established in this research,suggest significant potential for its future commercialization and expansion into practical applications.These include the next generation of radiation-protective fabrics,smart specialty textiles,and other functional composites in the field of industrial textiles.
司佳佳;苏晓磊;张亮;付晓艳;侯水利
陕西省纺织科学研究院有限公司,西安 710016西安工程大学 材料工程学院,西安 710048西安超码科技有限公司,西安 710000陕西省纺织科学研究院有限公司,西安 710016陕西省纺织科学研究院有限公司,西安 710016
通用工业技术
镍包石墨吸波化学镀复合材料反射损耗界面
nickel-coated graphitemicrowave absorptionelectroless platingcompositesreflection lossinterface
《表面技术》 2026 (4)
191-197,207,8
陕西省共性技术研发平台资助项目(2024ZG-GXPT-05) Funded Project of the Generic Technology R&D Platform of Shaanxi Province(2024ZG-GXPT-05)
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