中国激光, 2021, 48 (2): 0202020, 网络出版: 2021-01-06   

超快激光调控晶体形核与生长过程研究进展 下载: 1323次特邀综述

Progress in Ultrafast Laser-Induced Nucleation and Crystal Growth
作者单位
1 清华大学机械工程系, 北京 100084
2 北京理工大学机械车辆学院, 北京 100081
3 清华大学化学系, 北京 100084
摘要
物质的结晶在生物制药、大分子结构分析等领域有着重要的应用,这些应用对结晶结果(包括晶体数量、大小、晶型等)提出了一定的需求,而通过蒸发溶剂或改变温度使溶质析出结晶的传统方法,存在结晶结果难以控制的问题。近年来,超快激光在调控晶体形核生长中的应用得到了关注和研究。超快激光以其超快、超强的特点,在调控晶体形核与生长方面具有独特的作用,且具有热影响区域小、适用材料范围广等优势。本文综述了超快激光调控晶体形核生长过程的研究进展,主要包括超快激光诱导结晶形核、控制晶体生长过程以及晶面图案化加工三个方面,并对超快激光调控晶体形核生长研究的应用前景进行了展望。
Abstract

Significance Crystallization has applications in biomedicine, structural analysis, and other related fields. For example, single crystal X-ray diffraction (XRD) is a common method for the structural analysis of biomacromolecules. Polymorph crystallization is also of significance in the pharmaceutical industry. These applications require the number, size, and polymorph of the crystals to be determined. Conventionally, crystals are obtained by evaporation of a solution or via a batch cooling process. However, the complex nature of the crystallization process means that precise control of crystallization is difficult.

The crystallization process consists of two main stages: nucleation and crystal growth. When the concentration of a solute exceeds its solubility, the supersaturated solution is in a metastable zone. When the solute concentration reaches the supersaturation limit, nucleation occurs. The nucleus will then grow into larger crystals when the concentration drops back to the solubility level.

In recent years, various methods have been studied for controlling crystal nucleation and growth processes, including those involving lasers, ultrasonics, and electromagnetic fields ( Table 1, Table 2). Among these methods, ultrafast laser, because of its ultrashort pulse width and ultrahigh peak intensity, interacts uniquely with the solution and crystals. It has advantages including limited thermal effects and can be applied to many materials. Therefore, the ultrafast laser method has been applied for the control of the crystallization process. In this review, we introduce the research progress of ultrafast laser-controlled crystallization. Many different methods and mechanisms of laser-induced nucleation and crystallization are discussed. Studies on effective control of the crystallization process will not only benefit the biomedical industry, but also shed new light on current academic crystallography research.

Progress The ultrafast laser-controlled crystallization process can be categorized into several different types depending on stage of crystallization where the laser is involved ( Fig. 1). Ultrafast laser interaction with a supersaturated solution will induce the nucleation of crystals. Many different mechanisms contribute to this process, including laser heating of the substrate, formation of cavitation bubbles, and the electromagnetic effect. Local heating of the substrate or laser-induced cavitation in solution increases the local concentration and results in nucleation. Laser irradiation with lower power leads to electromagnetic field interactions with the solution or the heating of impurities within the solution. These methods are collectively known as non-photochemical laser induced nucleation (NPLIN) since the laser is not directly absorbed by the solution. The electromagnetic effects, including polarization and Kerr effects, reduce the energy barrier and enhance the nucleation rate ( Fig. 2). Through these methods, researchers are able to enhance the nucleation probability, and control the number and size of the crystals. Most importantly, the spatial selectivity of laser radiation allows local nucleation while the global concentration is lower than the supersaturation limit. This means fewer initial nuclei compared to spontaneous nucleation, which further results in crystals with large size and high quality. Ultrafast laser irradiation can also influence the polymorph of nucleation and enhance the ratio of metastable crystal phases ( Fig. 4). This is useful in biomedical research and within the pharmaceutical industry.

After the crystal nucleus dissolves out from the solution, laser interaction with the crystals or the surrounding solution can influence the crystal growth process. Laser irradiation of the solution can be performed to change the growth rate of crystals through a laser trapping phenomenon. For some organic materials, laser trapping increases the concentration at the focal point and accelerates the crystal growth. For some other materials, such as proteins, the electromagnetic field will keep the molecules and clusters in a low energy state and restrain the crystal growth. In addition to the control of the entire crystal growth rate, the growth of a specific crystal face can also be promoted. Ultrafast laser ablation on a crystal surface alters the growth mode and enhances the growth speed of the specific crystal face( Fig. 5). This will be helpful in obtaining single crystals with ideal size and shape, which is crucial in single-crystal XRD and other biomedical applications. Ultrafast laser processing on crystal surfaces can also be performed to achieve micropatterning on single crystals.

Ultrafast laser ablation has high precision and has a limited thermal effect on the surrounding materials because of the nonlinear absorption effect and non-thermal ablation process. Therefore, it is suitable for the processing of thermally sensitive materials, including proteins, amino acids, and other biomaterials. Arbitrary micropatterns such as microarrays can be achieved on the surface of single protein crystals without thermal damage using femtosecond laser processing. Ultrafast laser cleaving of protein crystals can be performed to fabricate crystal seeds with high quality. Micropatterning on single crystals has potential applications in the fabrication of biological devices.

Conclusion and Prospect In conclusion, ultrafast laser can be used to control the nucleation and crystal growth processes. This approach is applicable for many biomedical fields because it can control crystallization and has limited thermal effects. Ultrafast laser control of the crystallization process still poses challenges such as lack of mechanism understanding and limits in practical applications. Future studies on its mechanism and cross-disciplinary collaboration will enhance the significance and application prospect of this method.

俞嘉晨, 闫剑锋, 李欣, 曲良体. 超快激光调控晶体形核与生长过程研究进展[J]. 中国激光, 2021, 48(2): 0202020. Jiachen Yu, Jianfeng Yan, Xin Li, Liangti Qu. Progress in Ultrafast Laser-Induced Nucleation and Crystal Growth[J]. Chinese Journal of Lasers, 2021, 48(2): 0202020.

本文已被 1 篇论文引用
被引统计数据来源于中国光学期刊网
引用该论文: TXT   |   EndNote

相关论文

加载中...

关于本站 Cookie 的使用提示

中国光学期刊网使用基于 cookie 的技术来更好地为您提供各项服务,点击此处了解我们的隐私策略。 如您需继续使用本网站,请您授权我们使用本地 cookie 来保存部分信息。
全站搜索
您最值得信赖的光电行业旗舰网络服务平台!