Collaborative Research: Dynamic Manipulation of Micro-scale Liquid-Liquid Interfaces within Complex Droplets for Tunable Optics

合作研究：可调谐光学器件复杂液滴内微尺度液-液界面的动态操控

• 批准号: 1804092
• 负责人: Lauren Zarzar
• 金额: $ 18.24万
• 依托单位: Pennsylvania State Univ University Park
• 依托单位国家: 美国
• 项目类别: Standard Grant
• 财政年份: 2018
• 资助国家: 美国
• 起止时间: 2018-08-15 至 2022-07-31
• 项目状态: 已结题
• 来源: https://www.nsf.gov/awardsearch/showAward?AWD_ID=1804092&HistoricalAwards=false
• 关键词: Collaborative; Research; Dynamic; Manipulation; Micro

Optical materials that can be tuned and adjusted in real time have become important in many applications. These include display technology, compact imaging devices, biomedical sensors, and point-of-care diagnostic tools. Liquids have many properties that would be beneficial for tunable optics. Liquids are deformable, have a broad range of adjustable properties, and have ultra-smooth surfaces with variable curvature. These characteristics could be particularly beneficial in tunable micro-lenses. In this project, the investigators will examine how complex droplets behave as tunable optical materials. Here, the complex droplets will be composed of two or three immiscible oils within an aqueous outer phase. A combination of experiments and analytical and computational modeling will be used. The aim is to provide a comprehensive understanding of the opportunities for realizing novel fluid-based optical technologies.Micron-scale optical elements have contributed significantly to the miniaturization of devices and instrumentation. They have been used in integral imaging and 3D displays, spatial light modulators, endoscopes, plenoptic cameras, and solar concentrators. Dynamically switchable reflective micro-optics, based on digital micro-mirror displays and continuously reconfigurable absorptive pixel technology enabled by liquid crystal displays, have enabled transformative advances in optical technology. Similarly, dynamic refractive micro-optics are poised to complement and extend the capabilities of present micro-optical devices. Although not yet a staple in the optical engineer's toolbox, liquids offer tremendous flexibility, design advantages, miniaturization promise, and manufacturing benefits in applications that require tunability. Despite the promise of using liquids within optical devices, the same malleability and sensitivity to many stimuli that make liquids so valuable for tunable optics can also make them difficult to control with the precision required for optical applications. A deeper fundamental understanding of strategies for liquid interface manipulation to fine-tune a fluid optical element and new approaches for controlling fluid-fluid interfaces within complex multiphase systems are critical for the advancement of optofluidic devices. In this collaborative effort, researchers aim to demonstrate that careful design of the composition and morphology of multiphase emulsion droplets provides a powerful strategy to form tunable lenses and micro-scale total internal reflection modules. This research pushes the boundaries of current liquid optics by exploring how droplets containing multiple reconfigurable fluid interfaces can be used to control lensing, correct for optical aberrations, and enable efficient spectral dispersion through total internal reflection. Understanding how liquid interfaces can be addressed independently or in tandem to dynamically tune the optical behavior of complex droplets will enable applications of fluids as optical components. Through this collaboration, the team aims to bring together optical theory with an enhanced understanding of how to manipulate multiphase liquids with the goal of broadening the role that complex fluids play in the realm of dynamic optical materials. Given the ease by which the complex droplets used in this proposal can be fabricated and reconfigured, the researchers will use fluid optical materials as a teaching tool to introduce K-12 students and educators to concepts in surface science. Broader societal impact of the research program is expected through applications in point-of-care diagnostics. Development of more sensitive, quantitative, and low cost platforms for health monitoring will have far-reaching global impact on healthcare.This award reflects NSF's statutory mission and has been deemed worthy of support through evaluation using the Foundation's intellectual merit and broader impacts review criteria.

可以实时调谐和调整的光学材料在许多应用中变得非常重要。这些技术包括显示技术、紧凑型成像设备、生物医学传感器和即时诊断工具。液体有许多对可调谐光学器件有益的特性。液体是可变形的，具有广泛的可调节特性，并且具有可变曲率的超光滑表面。这些特性在可调微透镜中特别有用。在这个项目中，研究人员将研究复杂液滴作为可调光学材料的行为。在这里，复合液滴将由水相中的两种或三种不混溶油组成。将使用实验、分析和计算模型相结合的方法。目的是提供实现新型流体光学技术的机会的全面理解。微米级光学元件对设备和仪器的小型化做出了重大贡献。它们已被用于集成成像和3D显示器、空间光调制器、内窥镜、全光相机和太阳能聚光器。基于数字微镜显示和液晶显示实现的连续可重构吸收像素技术的动态切换反射微光学，使光学技术实现了变革性的进步。同样，动态折射微光学也准备好补充和扩展现有微光学器件的能力。虽然液体还不是光学工程师工具箱中的主要部件，但在需要可调性的应用中，液体提供了巨大的灵活性、设计优势、小型化前景和制造优势。尽管在光学设备中使用液体是有希望的，但同样的延展性和对许多刺激的敏感性使得液体对可调光学如此有价值，也使得它们难以控制光学应用所需的精度。对液体界面操纵策略的更深入的基本理解以微调流体光学元件和控制复杂多相系统中流体-流体界面的新方法对于光流体器件的进步至关重要。在这项合作中，研究人员旨在证明多相乳化液液滴的组成和形态的精心设计为形成可调透镜和微尺度全内反射模块提供了强有力的策略。本研究通过探索包含多个可重构流体界面的液滴如何用于控制透镜，校正光学像差，并通过全内反射实现有效的光谱色散，从而突破了当前液体光学的界限。了解如何单独或串联处理液体界面以动态调整复杂液滴的光学行为，将使流体作为光学元件的应用成为可能。通过这次合作，该团队旨在将光学理论与对如何操纵多相液体的更好理解结合在一起，目标是扩大复杂流体在动态光学材料领域的作用。考虑到该方案中使用的复杂液滴易于制造和重新配置，研究人员将使用流体光学材料作为教学工具，向K-12学生和教育工作者介绍表面科学的概念。研究计划的更广泛的社会影响，预计通过在点护理诊断的应用。开发更加敏感、定量和低成本的健康监测平台将对全球医疗保健产生深远的影响。该奖项反映了美国国家科学基金会的法定使命，并通过使用基金会的知识价值和更广泛的影响审查标准进行评估，被认为值得支持。

项目成果

Tunable and Responsive Structural Color from Polymeric Microstructured Surfaces Enabled by Interference of Totally Internally Reflected Light

• DOI: 10.1021/acsmaterialslett.0c00143
• 发表时间: 2020-07-06
• 期刊: ACS MATERIALS LETTERS
• 影响因子: 11.4
• 作者: Goodling, Amy E.;Nagelberg, Sara;Zarzar, Lauren D.
• 通讯作者: Zarzar, Lauren D.

Structural Color due to Interference of Totally Internally Reflected Light in Bi-Phase Droplets

双相液滴中全内反射光干涉导致的结构颜色

• DOI: 10.1364/isa.2019.im2b.4
• 发表时间: 2019
• 期刊: Proc. SPIE
• 作者: Saunders, Ashley;Nagelberg, Sara;Goodling, Amy;Kaehr, Bryan;Kolle, Mathias;Zarzar, Lauren
• 通讯作者: Zarzar, Lauren

Colouration by total internal reflection and interference at microscale concave interfaces

• DOI: 10.1038/s41586-019-0946-4
• 发表时间: 2019-02-28
• 期刊: NATURE
• 影响因子: 64.8
• 作者: Goodling, Amy E.;Nagelberg, Sara;Zarzar, Lauren D.
• 通讯作者: Zarzar, Lauren D.