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1. Ultrafast observation of intense light-matter interactions in flexible glass via single-shot frequency domain holography

   https://doi.org/10.1364/FIO.2020.FM1C.4  

   Dempsey, Dennis; Nagar, Garima C.; Renskers, Christopher K.; Grynko, Rostislav I.; Sutherland, James S.; Shim, Bonggu (September 2020, Frontiers in Optics / Laser Science)

   We use frequency domain holography (FDH) to spatio-temporally visualize the laser-matter interaction caused by the optical Kerr effect and plasma in flexible Corning® Willow® Glass in a single-shot. 

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2. Multi-shot and single-shot time-resolved visualization of material modification during laser micromachining with flexible glass

   https://doi.org/10.1364/CLEO_AT.2019.JTu2A.58  

   Dempsey, Dennis; Nagar, Garima C.; Sutherland, James S.; Grynko, Rostislav I.; Shim, Bonggu (July 2019, 2019 Conference on Lasers and Electro-Optics (CLEO))

   We visualize material modification during laser micromachining, in particular, laser waveguide fabrication in flexible Corning® Willow® Glass via time-resolved interferometry, and single-shot frequency-domain holography which is a robust technique for studying permanent material change/damage. 

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3. Fabrication of waveguides in flexible glass via femtosecond laser micromachining and visualization of ultrafast dynamics of the laser-glass interaction

   Agnes, J; Nagar, G; Dempsey, D; Batista, N; Sutherland, J; Shim, B (November 2021, 63rd Annual Meeting of the APS Division of Plasma Physics)

   We fabricate waveguides in Corning® flexible glass using Femtosecond Laser Micromachining (FLM) and visualize the ultrafast plasma dynamics which lead to waveguide formation via time-resolved interferometry. Due to minimal thermal effects and highly-nonlinear optical processes [1], FLM is an ideal tool to fabricate waveguides in glass with high precision and without post processing. We optimize laser fabrication of waveguides by varying scanning speed and pulse energy and, in particular, achieve waveguides with circular cross-sections using slit beam shaping [2]. Further optimization requires investigation of the underlying dynamics of how structural changes in glass are made during and after laser-glass interactions. Thus, we visualize the creation and recombination of plasma in glass which leads to the formation of waveguides using time- resolved interferometry [3]. [1] Rafael R. Gattass and Eric Mazur, Nature Photonics 2, 219–225 (2008)); [2] M. Ams et al. Opt. Express 13, 5676-5681 (2005); [3] G. C. Nagar, D. Dempsey, and B. Shim, Communications Physics 4, 96 (2021). 

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4. Single-shot ultrafast visualization of plasma dynamics and nonlinear index of refraction in flexible glass using frequency domain holography

   Dempsey, Dennis; Nagar, Garima; Renskers, Christopher; Grynko, Rostislav; Sutherland, James; Shim, Bonggu (October 2019, APS Division of Plasma Physics Meeting 2019)

   We measure the nonlinear index of refraction (n2) and investigate plasma dynamics in flexible Corning® Willow® Glass using single-shot Frequency Domain Holography (FDH). Flexible glass has received a lot of attention recently due to various applications such as 3-D photonics and wearable devices. Femtosecond laser micromachining (FLM) is a viable tool to fabricate these devices because of minimal thermal effects and thus enables fabrication of small and clean 3-D structures. To control and understand the underlying dynamics of FLM, ultrafast visualization of plasma and optical Kerr effect is important. FDH is a robust femtosecond time-resolved technique in which chirped reference and probe pulses centered at 404 nm are used to measure and visualize the plasma and Kerr effect produced by an intense, ultrashort pump pulse centered at 808 nm. Using FDH, we study laser-matter interactions in Willow Glass and measure its n2 to be 3.41 +/-0.08 ×10-16 cm2/W and visualize the plasma dynamics. 

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5. Spatially selective drop-motion programming using metamaterials

   https://doi.org/10.1098/rspa.2024.0429  

   Charara, Mohammad; Kujala, Zakari; Lee, Sungyon; Gonella, Stefano (February 2025, Proceedings of the Royal Society A: Mathematical, Physical and Engineering Sciences)

   Motion control of droplets has generated much attention for its application to microfluidics, where precisely controlling small fluid volumes is an imperative requirement. Mechanical vibrations can induce controllable depinning and activation of a variety of drop-motion regimes. However, existing vibration-based strategies establish homogeneous rigid-body dynamics on the entire substrate, thus lacking any form of spatial heterogeneity and tuning. Addressing this limitation, elastic metamaterials provide an ideal platform to achieve spectrally and spatially selective drop-motion control. This capability results from the intrinsic ability of metamaterials to attenuate vibrations in selected frequency bands and regions of an elastic domain. In this work, we experimentally demonstrate a variety of droplet motion capabilities on the surface of a vibrating metaplate endowed with locally resonant stubs. The experiments leverage the design reconfigurability of a LEGO^®component-enabled prototyping platform, which allows us to switch in an agile manner between different configurations of resonators. We use laser vibrometry measurements with high spatial resolution to capture the spatial variability of the metaplate response. Beyond the discipline-specific boundaries, this work begins to illustrate a broader employment of elastic metamaterials in applications where their signature wave control capability is not the end goal, but rather an enabling tool for other more complex multiphysical effects. 

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