<i>In Situ</i> Electrohydrodynamic Jet Printing-Based Fabrication of Tunable Microlens Arrays

Zhong, Ya; Yu, Haibo; Zhou, Peilin; Wen, Yangdong; Zhao, Wenxiu; Zou, Wuhao; Luo, Hao; Wang, Yuechao; Liu, Lianqing

doi:10.1021/acsami.1c06205

Cited by 21 publications

(19 citation statements)

References 43 publications

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“…Also, liquid microlenses can be reshaped through various external stimuli. For example, electrowetting on dielectric (EWOD) has been widely applied to change the contact angle of individual microlens to adjust the focal length of the MLAs. − Besides, another strategy based on the surface modification of substrate to change liquid contact angles and microlens’ focal length is also reported . Although these methods can achieve tunable liquid MLAs, the liquids are limited to conductive and photosensitive materials, and the tuning process is also complicated and time-consuming.…”

Section: Introductionmentioning

confidence: 99%

Tunable and Dynamic Optofluidic Microlens Arrays Based on Droplets

Shi

et al. 2022

Anal. Chem.

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Microlens arrays (MLAs) are acquiring a key role in the micro-optical system, which have been widely applied in the fields of imaging processing, light extraction, biochemical sensing, and display technology. Compared with solid MLAs, liquid MLAs have received extensive attention due to their natural smooth interface and adjustability. However, manufacturing tunable liquid MLAs with ideal structures is still a key challenge for current technologies. In this paper, a novel and simple optofluidic method is demonstrated, enabling the tunable focusing and high-quality imaging of liquid MLAs. Tunable droplets are fabricated and self-assembled into arrays as the MLAs, which can be easily adjusted to focus, form images, and display different focal lengths. Tuning of MLAs’ focusing properties (range from 550 to 5370 μm) is demonstrated by changing the refractive index (RI) of the droplets with a fixed size of 200 μm, which can be changed by adjusting the flow rates of the two branch streams. Also, the corresponding numerical apertures of the MLAs range from 0.026 to 0.26. Furthermore, the MLAs’ functionality for microparticle imaging applications is also illustrated. Combining the MLAs with a 4× objective, microparticle imaging is magnified two times, and the resolution has also been improved on the original basis. Besides, both the size and RI of the MLAs in an optofluidic chip can be further adjusted to detect samples at different positions. These MLAs have the merits of high optical performance, a simple fabrication procedure, easy integration, and good tunability. Thus, it shows promising opportunities for many applications, such as adaptive imaging and sensing.

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Section: Introductionmentioning

confidence: 99%

Tunable and Dynamic Optofluidic Microlens Arrays Based on Droplets

Shi

et al. 2022

Anal. Chem.

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“…In recent years, interest has grown in the fabrication of tunable microlenses and MLA as a result of their attractive merits such as being small and lightweight, enabling image magnification extinction for optical switching, and having a field of view for multiple imaging. − Therefore, microlenses and MLA have enabled great progress and applications in the focal plane optical concentration, optical efficiency enhancements, color separation, beam-shaping spatial-light-modulating systems, , optical fiber coupling, and miniature optical scanning . Comparatively speaking, for conventional optical equipment, their focal lengths are generally realized by adjusting the relative position of optical elements and mechanical parts such as gears, motors, and shutters. − Thus, conventional optical equipment is bulky and heavy and has a slow response.…”

Section: Introductionmentioning

confidence: 99%

Microfluidic Fabrication of a PDMS Microlens for Imaging Tunability

et al. 2022

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A microfluidic system was created to fabricate polydimethylsiloxane (PDMS) microspheres, whose shape, surface smoothness, and size were controlled. Resulting from their excellent optical properties and elasticity prepared by the apparatus, each PDMS microsphere could act as a microlens and separate imaging unit. The focal length of the microlens was simply tuned by the forces posed on the beads. For the microlens array (MLA) application, it was constructed simply through the assembly of the monodisperse PDMS beads.

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“…Most of the application scenarios for the ACE are related to imaging and sensing, and these functions attract much attention of researchers. Unlike mammalian eyes, arthropod compound eyes consisting of the crystal vertebra, visual rod, etc., lack zooming functions and thereby have difficulty in detecting objects at different distances. , In order to achieve the zoom function of the ACE, researchers have devoted great efforts. − To endow the ACE with the zoom function, researchers commonly employed various drive forces, e.g., electromagnetic force, photothermal actuation, and pressure etc. − However, the existence of the power source increases the complexity of manufacturing and restricts applicable environments. − Additionally, this power source enables the ACE variable-focus imaging on the curved surface, and the lack of planar imaging function makes it difficult to clearly observe planar objects due to defocusing. Ommatidia have same focal lengths, and they are distributed on the curved substrate, which decides their curved imaging characteristics.…”

Section: Introductionmentioning

confidence: 99%

“…Unlike mammalian eyes, arthropod compound eyes consisting of the crystal vertebra, visual rod, etc., lack zooming functions and thereby have difficulty in detecting objects at different distances. 14,15 In order to achieve the zoom function of the ACE, researchers have devoted great efforts. 16−21 To endow the ACE with the zoom function, researchers commonly employed various drive forces, e.g., electromagnetic force, photothermal actuation, and pressure etc.…”

Section: Introductionmentioning

confidence: 99%

Artificial Hyper Compound Eyes Enable Variable-Focus Imaging on both Curved and Flat Surfaces

Luan

Cao

Deng

et al. 2022

ACS Appl. Mater. Interfaces

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The artificial compound eye (ACE) with zoom imaging requires complex power sources. Meanwhile, its curved substrate makes it difficult for the ACE to realize the zoom imaging on flat surfaces. To realize a wide field of view and a zoom function on both curved and flat surfaces simultaneously, a novel ACE is proposed, which is a bionic design inspired by an ancient creature, trilobite. Compared with a dragonfly, photosensitive units of a trilobite's compound eye are composed of ommatidia with different focal lengths. By learning from this concept, an artificial hyper compound eye (AHCE) was fabricated. Its basic components are five microlenses with different curvatures, and they are capable of being treated as five ommatidia with different focal lengths. Five ommatidia form a photosensitive unit to realize a zoom function. AHCE is capable of variable-focus imaging on curved surfaces. With the information share function, we found that the AHCE not only images on curved surfaces but also has a zoom-imaging function on flat surfaces. The results confirm that the AHCE demonstrates an advanced imaging capability, a variable-focus imaging function on both curved and flat surfaces, which may open new opportunities in developing advanced micro-optical devices.

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In Situ Electrohydrodynamic Jet Printing-Based Fabrication of Tunable Microlens Arrays

Cited by 21 publications

References 43 publications

Tunable and Dynamic Optofluidic Microlens Arrays Based on Droplets

Tunable and Dynamic Optofluidic Microlens Arrays Based on Droplets

Microfluidic Fabrication of a PDMS Microlens for Imaging Tunability

Artificial Hyper Compound Eyes Enable Variable-Focus Imaging on both Curved and Flat Surfaces

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