In other fields of technology, such as high dense magnetism record component and light record component, the ultra-smooth surface is also necessary.
在另外的一些技术领域,如高密度磁记录器件和光记录器件等的制造方面,也存在着对超光滑表面的需求。
参考来源 - 流体二维振动超光滑表面加工振动场分析与实验研究The paper carries out a systematic concept of super smooth surface processing according to the requirements of crystallite glass substrate, it also mentions the solving methods of every steps for super smooth surface processing.
针对磁盘微晶玻璃基板的表面要求,论文提出了获取超光滑表面的系统的观点,并对获取超光滑表面的各个环节提出了解决方法。
参考来源 - 微晶玻璃基板超光滑表面加工技术研究In the ICF system, huge number of optical components with super smooth surface is required and the requirements accuracy control for the system come to the limits.
ICF系统对超光滑表面光学元件的需求量极大,对加工精度的要求近乎极限的要求,超光滑表面光学加工问题已经成为瓶颈问题,急待加工水平的提高。
参考来源 - 控制光学元件超光滑表面粗糙度的研究Therefore, it is tar-reaching to introduce laser-cleaning technology to clean the super-smooth surface of optical glass substrate.
因此将激光清洗技术应用于清洗光学基片超光滑表面具有重要的意义。
参考来源 - 超光滑光学基片表面激光清洗的机理和试验研究Using optimized polishing parameters, an ultra-smooth surface with roughness of Ra 6.93nm is obtained.
使用改进的实验参数抛光,最终获得了微观表面粗糙度Ra为6.93nm的超光滑表面。
参考来源 - 机械与氧化化学法抛光金刚石膜研究·2,447,543篇论文数据,部分数据来源于NoteExpress
超光滑表面在现代科学技术中具有重要意义。
Supersmooth surfaces are of great importance to the modern science and technology.
结果表明,这种抛光工艺能获得原子级的超光滑表面。
Results show that this process can reach surface roughness with angstrom dimension.
因此将激光清洗技术应用于清洗光学基片超光滑表面具有重要的意义。
Therefore, it is tar-reaching to introduce laser-cleaning technology to clean the super-smooth surface of optical glass substrate.
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