Xuefei Liu, Chuanzhen Huang, Hanlian Liu, Dun Liu, Peng Yao, Bin Zou, H. Zhu, Zhen Wang, Longhua Xu, Shuiquan Huang
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引用次数: 0
Abstract
Monocrystalline silicon-based microstructure functional surfaces are widely used in the field of photoelectricity. However, the traditional process is prone to damage due to the hardness and brittleness of monocrystalline silicon. In this study, the depth, width, and depth-width ratio of the micro-V-groove on the surface of monocrystalline silicon were studied using laser-assisted waterjet technology. Firstly, the nanosecond laser pulse width was optimized to minimize processing damage. Then, the response surface method (RSM) was employed to optimize the V-groove’s depth-width ratio and show the process parameters’ interactive effects. The results show that the heated affected zone (HAZ) and lattice disorder at 10 ns are significantly smaller than those at other pulse widths, and there is almost no amorphous phase on the surface of V-grooves. Single process parameter usually has different effects on the size of the V-groove, and the process parameters have significant interactive effects, which are discussed in detail in the study. According to the prediction model, the highest depth-width ratio of a V-groove is 1.39. Near-damage-free V-groove with a high depth-width ratio helps to lower the reflectivity and increase the hydrophobicity of monocrystalline silicon.
基于单晶硅的微结构功能表面被广泛应用于光电领域。然而,由于单晶硅的硬度和脆性,传统工艺容易造成损坏。本研究利用激光辅助水刀技术研究了单晶硅表面微 V 形槽的深度、宽度和深宽比。首先,对纳秒激光脉冲宽度进行了优化,以尽量减少加工损伤。然后,采用响应面法(RSM)优化了 V 形槽的深宽比,并显示了工艺参数的交互影响。结果表明,10 ns 时的受热影响区(HAZ)和晶格紊乱明显小于其他脉冲宽度,V 形槽表面几乎没有非晶相。单个工艺参数通常会对 V 形槽的尺寸产生不同的影响,而工艺参数之间存在显著的交互影响,本研究对此进行了详细讨论。根据预测模型,V 形槽的最大深宽比值为 1.39。高深宽比的近无损 V 型槽有助于降低单晶硅的反射率和增加疏水性。
期刊介绍:
Manufacturing industries throughout the world are changing very rapidly. New concepts and methods are being developed and exploited to enable efficient and effective manufacturing. Existing manufacturing processes are being improved to meet the requirements of lean and agile manufacturing. The aim of the Journal of Engineering Manufacture is to provide a focus for these developments in engineering manufacture by publishing original papers and review papers covering technological and scientific research, developments and management implementation in manufacturing. This journal is also peer reviewed.
Contributions are welcomed in the broad areas of manufacturing processes, manufacturing technology and factory automation, digital manufacturing, design and manufacturing systems including management relevant to engineering manufacture. Of particular interest at the present time would be papers concerned with digital manufacturing, metrology enabled manufacturing, smart factory, additive manufacturing and composites as well as specialist manufacturing fields like nanotechnology, sustainable & clean manufacturing and bio-manufacturing.
Articles may be Research Papers, Reviews, Technical Notes, or Short Communications.