Microlens arrays on curved surfaces are regarded as critical elements of bionic compound eyes (BCEs), which exhibit the comparative advantages of a wide field of view and tracking fast-moving objects. However, the fabrication of a curved microlens array is still challenging. Along these lines, in this work, a straightforward, rapid, and low-cost technique for the fabrication of curved microlens arrays is reported by using the self-assembly technique. A reactive ion etching process treated the surface of the curved polydimethylsiloxane (PDMS) substrate to generate a hydrophobic-hydrophilic pattern. Then, the curved microlens array can be realized by dewetting a liquid glue onto the substrate using the dip-coating method and followed by crosslinking. The proposed BCE structure consists of 2400 microlenses (400 - µm diameter and 440 - µm center distance) arranged in a hexagonal configuration on a curved PDMS surface (34 - mm diameter and 40.4 - mm curvature radius). A field-of-view of 50° was demonstrated, which has potential applications in various fields including imaging sensors, medical diagnostics, machine vision systems, and photodetectors.
A transparent fluid dibutyl adipate (DBA) is suitable for fabricating the adaptive lens due to its unique deformation under a direct current (DC) electric field. In this report, a DBA liquid microlens array (LMA) with a tunable focal length is demonstrated. A hydrophobic layer deposited in the ring array patterns on the electrode induced the formation of the DBA liquid microdroplets array self-assembly. The electronegative DBA liquid tends to move to the anode at a DC voltage. The proposed DBA LMA with a diameter of 100 µm can change its focal length from 0.92 to 1.42 mm when the voltage changes from 0 to 200 V. The response time is relatively fast (
∼
790
m
s
). Due to the high optical transmittance (
∼
91
%
) and good thermal stability in the temperature range of
−
24.8
−
161.5
∘
C, our DBA LMA shows good focusing properties and has potential applications in the field of image processing, portable electronic devices, beam steering, ophthalmology, and 3D displays.
A liquid crystal microlens array (LCMLA) with positive and negative focal lengths based
on a ring-array patterned electrodes is demonstrated. By carefully
designing patterned electrodes with a circular electrode array area
and outer ring electrode region area, the switching of the positive
and negative lens effect can be easily achieved in a single cell. A
positive lens effect appeared when the voltage was applied to the
outer ring electrode region and the top substrate. The focal length
changed from infinity to 1 mm as the voltage varied from 0 to
3
V
r
m
s
. A negative lens effect occurred when
the voltage was applied to the circular electrode array and the top
substrate. The focal length varied from infinity to
−
1
m
m
when the voltage changed from 0 to
2
V
r
m
s
. The imaging properties of the LCMLA
at different voltages are evaluated. Our LCMLA, with simple structure,
low driving voltage, and good stability, has potential applications in
optical communication, imaging processing, and displays.
A curved
integral imaging three-dimensional (3D) display attracts
a lot of interest due to its enhanced 3D sense of immersion and wider
viewing angle. In this paper, a microlens array (MLA) based on a flexible
poly(ethylene terephthalate) (PET) substrate was achieved by a straightforward,
rapid, and low-cost technique. The reactive ion etching (RIE) process
treated PET/CYTOP covered with a flexible mask to generate a hydrophilic–hydrophobic
patterned surface. The well-designed arrays of confined adhesive droplets
with a controlled geometry on a hydrophilic–hydrophobic patterned
surface were formed using the blade-coating method. A flexible MLA
with a diameter of 820 μm, a size of 5.3 cm × 5.1 cm, and
a radius of curvature of 25 cm was fabricated and combined with a
curved two-dimensional (2D) monitor to realize a lateral viewing range
of 6.4 cm at a viewing distance of 25 cm, which is 4 times larger
than with flat integral imaging 3D display system. The flexible MLA
has the advantages of a controllable lens profile and large pitch,
and it can be manufactured on a large scale. In addition, it provides
a large viewing angle for the reconstructed 3D image.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.