Laser micro- and nano-material processing – Part 2

IF 2.3 Q2 OPTICS

Advanced Optical Technologies Pub Date : 2020-06-01 DOI:10.1515/aot-2020-0025

A. Lasagni, J. Bonse

{"title":"Laser micro- and nano-material processing – Part 2","authors":"A. Lasagni, J. Bonse","doi":"10.1515/aot-2020-0025","DOIUrl":null,"url":null,"abstract":"This special issue of Advanced Optical Technologies (AOT) is dedicated to the field of laser-based microand nanostructuring methods. Due to the unique characteristics of pulsed laser systems, among them ultrafast sources with picosecond and femtosecond pulse durations, today we are experiencing an explosion of new technological developments that will open new perspectives for industrial applications in the near future. This becomes possible due to a continuous reduction in the cost of laser sources as well as the outstanding improvement of the power stability, increased pulse repetition frequencies, as well as the simplicity of the new laser devices. However, although these developments are necessary for boosting the availability of lasers in modern industrial manufacturing, they alone will not define the industrialization of laser-based applications. In this context, additional efforts are still necessary for understanding how specific surface functionalities on different materials can be created or even improved by developing specific textured surfaces as well as how to produce these topographies at high throughput by the full utilization of the laser performance. Our list of contributors for this issue reflects a leading-edge mix of experts in these areas, from all around the world. The special issue is published in two parts. Part 2 of the special issue ‘Laser Microand NanoMaterial Processing’ contains four original research articles that are briefly summarized here: Fosodeder et al. demonstrate in in-vitro experiments that a ring of hierarchical micro-nanostructures (selforganized micro-spikes covered with laser-induced periodic surface structures) processed on a titanium alloy cylinder by femtosecond laser irradiation and subsequent anodic oxidation can act as an efficient barrier preventing the overgrowth with fibroblast cells. These results pave way for applications in miniaturized cardiac pacemakers that can be implanted directly into the heart. Ocaña et al. process hierarchical micro-nanostructures (complex two-dimensional periodic multi-gratings) on plane titanium alloy samples by combining the techniques of nanosecond direct laser writing (DLW) with picosecond direct laser interference patterning (DLIP). The processed surfaces feature a strongly hydrophobic surface wettability and may exhibit an improved electrochemical corrosion resistance. Genieys et al. study the ablation of four different metals (Al, Cu, Ni, W) irradiated by single titanium sapphire laser pulses with durations ranging between 15 fs and 100 fs. For these metals, a constant ablation threshold is reported and the energy specific ablation efficiency is quantified on the basis of an analysis of the ablation depths. The authors demonstrate that for metals there is no real interest in using few-optical-cycle pulse durations for ablation-based application processes. Bauerhenne and Garcia analyze the phenomenon of non-thermal melting by performing systematic ab-initio molecular dynamics (MD) simulations of femtosecond laser excited silicon using electron temperature-dependent density functional theory (DFT). The simulations reveal that the indirect electronic band gap decreases as a universal function of the atomic mean-square displacement almost independently of the electronic temperature (laser fluence) and that the dependence is linear for a wide range of mean-square displacements. We would like to thank all authors for their contributions to this special issue, reporting on new insights in this fascinating topic that significantly increase the capabilities in manufacturing technology. We would also like to acknowledge AOT for coordinating and guiding this special issue as well as all reviewers for their fruitful comments, which permitted improving the quality of the presented articles. We hope you will enjoy reading the articles in this special issue as much as we have enjoyed putting them together. *Corresponding authors: Andrés Fabián Lasagni, Technische Universität Dresden, Institute for Manufacturing Technology, 01062 Dresden, Germany, e-mail: andres_fabian.lasagni@tu-dresden.de; and Jörn Bonse, Bundesanstalt für Materialforschung und -prüfung (BAM), Unter den Eichen 87, 12205 Berlin, Germany, e-mail: joern.bonse@bam.de. https://orcid.org/0000-00034984-3896","PeriodicalId":46010,"journal":{"name":"Advanced Optical Technologies","volume":"9 1","pages":"111 - 112"},"PeriodicalIF":2.3000,"publicationDate":"2020-06-01","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://sci-hub-pdf.com/10.1515/aot-2020-0025","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Advanced Optical Technologies","FirstCategoryId":"1085","ListUrlMain":"https://doi.org/10.1515/aot-2020-0025","RegionNum":0,"RegionCategory":null,"ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q2","JCRName":"OPTICS","Score":null,"Total":0}

引用次数: 0

Abstract

This special issue of Advanced Optical Technologies (AOT) is dedicated to the field of laser-based microand nanostructuring methods. Due to the unique characteristics of pulsed laser systems, among them ultrafast sources with picosecond and femtosecond pulse durations, today we are experiencing an explosion of new technological developments that will open new perspectives for industrial applications in the near future. This becomes possible due to a continuous reduction in the cost of laser sources as well as the outstanding improvement of the power stability, increased pulse repetition frequencies, as well as the simplicity of the new laser devices. However, although these developments are necessary for boosting the availability of lasers in modern industrial manufacturing, they alone will not define the industrialization of laser-based applications. In this context, additional efforts are still necessary for understanding how specific surface functionalities on different materials can be created or even improved by developing specific textured surfaces as well as how to produce these topographies at high throughput by the full utilization of the laser performance. Our list of contributors for this issue reflects a leading-edge mix of experts in these areas, from all around the world. The special issue is published in two parts. Part 2 of the special issue ‘Laser Microand NanoMaterial Processing’ contains four original research articles that are briefly summarized here: Fosodeder et al. demonstrate in in-vitro experiments that a ring of hierarchical micro-nanostructures (selforganized micro-spikes covered with laser-induced periodic surface structures) processed on a titanium alloy cylinder by femtosecond laser irradiation and subsequent anodic oxidation can act as an efficient barrier preventing the overgrowth with fibroblast cells. These results pave way for applications in miniaturized cardiac pacemakers that can be implanted directly into the heart. Ocaña et al. process hierarchical micro-nanostructures (complex two-dimensional periodic multi-gratings) on plane titanium alloy samples by combining the techniques of nanosecond direct laser writing (DLW) with picosecond direct laser interference patterning (DLIP). The processed surfaces feature a strongly hydrophobic surface wettability and may exhibit an improved electrochemical corrosion resistance. Genieys et al. study the ablation of four different metals (Al, Cu, Ni, W) irradiated by single titanium sapphire laser pulses with durations ranging between 15 fs and 100 fs. For these metals, a constant ablation threshold is reported and the energy specific ablation efficiency is quantified on the basis of an analysis of the ablation depths. The authors demonstrate that for metals there is no real interest in using few-optical-cycle pulse durations for ablation-based application processes. Bauerhenne and Garcia analyze the phenomenon of non-thermal melting by performing systematic ab-initio molecular dynamics (MD) simulations of femtosecond laser excited silicon using electron temperature-dependent density functional theory (DFT). The simulations reveal that the indirect electronic band gap decreases as a universal function of the atomic mean-square displacement almost independently of the electronic temperature (laser fluence) and that the dependence is linear for a wide range of mean-square displacements. We would like to thank all authors for their contributions to this special issue, reporting on new insights in this fascinating topic that significantly increase the capabilities in manufacturing technology. We would also like to acknowledge AOT for coordinating and guiding this special issue as well as all reviewers for their fruitful comments, which permitted improving the quality of the presented articles. We hope you will enjoy reading the articles in this special issue as much as we have enjoyed putting them together. *Corresponding authors: Andrés Fabián Lasagni, Technische Universität Dresden, Institute for Manufacturing Technology, 01062 Dresden, Germany, e-mail: andres_fabian.lasagni@tu-dresden.de; and Jörn Bonse, Bundesanstalt für Materialforschung und -prüfung (BAM), Unter den Eichen 87, 12205 Berlin, Germany, e-mail: joern.bonse@bam.de. https://orcid.org/0000-00034984-3896

查看原文本刊更多论文

激光微纳材料加工第2部分

本期《先进光学技术》专刊致力于基于激光的微结构和纳米结构方法领域。由于脉冲激光系统的独特特性，其中包括具有皮秒和飞秒脉冲持续时间的超快光源，今天我们正在经历新技术的爆炸式发展，这将在不久的将来为工业应用开辟新的前景。由于激光源成本的持续降低、功率稳定性的显著提高、脉冲重复频率的增加以及新型激光器件的简单性，这成为可能。然而，尽管这些发展对于提高现代工业制造中激光的可用性是必要的，但仅凭它们并不能定义基于激光的应用的工业化。在这种情况下，仍然需要付出更多的努力来理解如何通过开发特定的纹理表面来创建甚至改善不同材料上的特定表面功能，以及如何通过充分利用激光性能来以高通量生产这些拓扑图。我们的本期撰稿人名单反映了来自世界各地的这些领域的前沿专家。特刊分两期出版。特刊“激光微纳材料加工”的第2部分包含四篇原创研究文章，简要总结如下：Fosodeder等人在体外实验中证明，飞秒激光在钛合金圆柱体上加工了一圈分级微纳米结构（覆盖有激光诱导的周期性表面结构的自组织微尖峰）照射和随后的阳极氧化可以作为防止成纤维细胞过度生长的有效屏障。这些结果为可以直接植入心脏的微型心脏起搏器的应用铺平了道路。Ocaña等人通过将纳秒直接激光写入（DLW）技术与皮秒直接激光干涉图案化（DLIP）技术相结合，在平面钛合金样品上处理分级微纳米结构（复杂的二维周期性多光栅）。经处理的表面具有强疏水性的表面润湿性，并且可以表现出改进的电化学耐腐蚀性。Geneyes等人研究了由持续时间在15fs和100fs之间的单个钛蓝宝石激光脉冲照射的四种不同金属（al、Cu、Ni、W）的烧蚀。对于这些金属，报告了恒定的消融阈值，并且基于对消融深度的分析来量化能量比消融效率。作者证明，对于金属，在基于烧蚀的应用过程中使用很少的光周期脉冲持续时间并没有真正的兴趣。Bauerhenne和Garcia利用电子温度相关密度泛函理论（DFT）对飞秒激光激发的硅进行了系统的从头算分子动力学（MD）模拟，分析了非热熔解现象。模拟表明，间接电子带隙作为原子均方位移的通用函数而减小，几乎与电子温度（激光注量）无关，并且对于宽范围的均方位移，这种相关性是线性的。我们要感谢所有作者对本期特刊的贡献，他们报道了这一引人入胜的主题中的新见解，这些见解大大提高了制造技术的能力。我们还要感谢AOT对本期特刊的协调和指导，以及所有审稿人富有成果的评论，这些评论提高了文章的质量。我们希望你会喜欢阅读本期特刊中的文章，就像我们喜欢把它们放在一起一样*通讯作者：Andrés Fabián Lasagni，德累斯顿工业大学制造技术研究所，德国德累斯顿01062，电子邮件：andres_fabian.lasagni@tu-dresden.de；和Jörn Bonse，Bundesanstalt für Materialforschung und-prüfung（BAM），Unter den Eichen 8712205 Berlin，德国，电子邮件：joern.bonse@bam.de.https://orcid.org/0000-00034984-3896

本文章由计算机程序翻译，如有差异，请以英文原文为准。

求助全文

约1分钟内获得全文求助全文

来源期刊

Advanced Optical Technologies OPTICS-

CiteScore

4.40

自引率

0.00%

发文量

期刊介绍： Advanced Optical Technologies is a strictly peer-reviewed scientific journal. The major aim of Advanced Optical Technologies is to publish recent progress in the fields of optical design, optical engineering, and optical manufacturing. Advanced Optical Technologies has a main focus on applied research and addresses scientists as well as experts in industrial research and development. Advanced Optical Technologies partners with the European Optical Society (EOS). All its 4.500+ members have free online access to the journal through their EOS member account. Topics: Optical design, Lithography, Opto-mechanical engineering, Illumination and lighting technology, Precision fabrication, Image sensor devices, Optical materials (polymer based, inorganic, crystalline/amorphous), Optical instruments in life science (biology, medicine, laboratories), Optical metrology, Optics in aerospace/defense, Simulation, interdisciplinary, Optics for astronomy, Standards, Consumer optics, Optical coatings.