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1. High extinction ratio, low insertion loss, optical switch based on an electrowetting prism

   https://doi.org/10.1364/OE.381565  

   Zohrabi, Mo; Yang_Lim, Wei; Bright, Victor_M; Gopinath, Juliet_T (February 2020, Optics Express)

   An optical switch based on an electrowetting prism coupled to a multimode fiber has demonstrated a large extinction ratio with speeds up to 300 Hz. Electrowetting prisms provide a transmissive, low power, and compact alternative to conventional free-space optical switches, with no moving parts. The electrowetting prism performs beam steering of ±3^°with an extinction ratio of 47 dB between the ON and OFF states and has been experimentally demonstrated at scanning frequencies of 100–300 Hz. The optical design is modeled in Zemax to account for secondary rays created at each surface interface (without scattering). Simulations predict 50 dB of extinction, in good agreement with experiment. 

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2. Morphogenesis-inspired two-dimensional electrowetting in droplet networks

   https://doi.org/10.1088/1748-3190/acc779  

   El-Beyrouthy, Joyce; Makhoul-Mansour, Michelle; Gulle, Jesse; Freeman, Eric (April 2023, Bioinspiration & Biomimetics)

   Abstract Living tissues dynamically reshape their internal cellular structures through carefully regulated cell-to-cell interactions during morphogenesis. These cellular rearrangement events, such as cell sorting and mutual tissue spreading, have been explained using the differential adhesion hypothesis, which describes the sorting of cells through their adhesive interactions with their neighbors. In this manuscript we explore a simplified form of differential adhesion within a bioinspired lipid-stabilized emulsion approximating cellular tissues. The artificial cellular tissues are created as a collection of aqueous droplets adhered together in a network of lipid membranes. Since this abstraction of the tissue does not retain the ability to locally vary the adhesion of the interfaces through biological mechanisms, instead we employ electrowetting with offsets generated by spatial variations in lipid compositions to capture a simple form of bioelectric control over the tissue characteristics. This is accomplished by first conducting experiments on electrowetting in droplet networks, next creating a model for describing electrowetting in collections of adhered droplets, then validating the model against the experimental measurements. This work demonstrates how the distribution of voltage within a droplet network may be tuned through lipid composition then used to shape directional contraction of the adhered structure using two-dimensional electrowetting events. Predictions from this model were used to explore the governing mechanics for complex electrowetting events in networks, including directional contraction and the formation of new interfaces. 

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3. Enhancing the Response Time of Electrowetting Lenses Using Voltage Shaping

   https://doi.org/10.1364/CLEO_SI.2017.SM4C.7  

   Supekar, Omkar D.; Zohrabi, Mo; Brown, Joseph; Gopinath, Juliet T.; Bright, Victor M. (January 2017, Conference on Lasers and ElectroOptics)

   We have demonstrated tunability of the response time of electrowetting lenses from underdamped to overdamped through input voltage shaping. This strategy shows great promise to further optimize the response time of electrowetting lenses. 

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4. Tunable liquid lens for three-photon excitation microscopy

   https://doi.org/10.1364/BOE.516956  

   Gilinsky, Samuel_D; Jung, Diane_N; Futia, Greg_L; Zohrabi, Mo; Welton, Tarah_A; Supekar, Omkar_D; Gibson, Emily_A; Restrepo, Diego; Bright, Victor_M; Gopinath, Juliet_T (April 2024, Biomedical Optics Express)

   We demonstrate a novel electrowetting liquid combination using a room temperature ionic liquid (RTIL) and a nonpolar liquid, 1-phenyl-1-cyclohexene (PCH) suitable for focus-tunable 3-photon microscopy. We show that both liquids have over 90% transmission at 1300 nm over a 1.1 mm pathlength and an index of refraction contrast of 0.123. A lens using these liquids can be tuned from a contact angle of 133 to 48° with applied voltages of 0 and 60 V, respectively. Finally, a three-photon imaging system including an RTIL electrowetting lens was used to image a mouse brain slice. Axial scans taken with an electrowetting lens show excellent agreement with images acquired using a mechanically scanned objective. 

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5. Axisymmetrical resonance modes in an electrowetting optical lens

   https://doi.org/10.1063/5.0141787  

   Miscles, Eduardo_J; Lim, Wei_Yang; Supekar, Omkar_D; Zohrabi, Mo; Gopinath, Juliet_T; Bright, Victor_M (May 2023, Applied Physics Letters)

   Electrowetting-based adaptive optics are of great interest for applications ranging from confocal microscopy to LIDAR, but the impact of low-frequency mechanical vibration on these devices remains to be studied. We present a simple theoretical model for predicting the resonance modes induced on the liquid interface in conjunction with a numerical simulation. We experimentally confirm the resonance frequencies by contact angle modulation. They are found to be in excellent agreement with the roots of the zero-order Bessel functions of the first kind. Next, we experimentally verify that external axial vibration of an electrowetting lens filled with density mismatched liquids (Δρ = 250 kg/m3) will exhibit observable Bessel modes on the liquid–liquid interface. An electrowetting lens filled with density matched liquids (Δρ = 4 kg/m3) is robust to external axial vibration and is shown to be useful in mitigating the effect of vibrations in an optical system. 

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