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in liquid-like lasers (fast-gain devices with quasi-constant intensity) we can go further: resonant radio-frequency (RF) modulation transforms the spectrum into a synthetic frequency lattice, enabling
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for Perovskite On-Chip Integration. ACS Nano, 2025. State-of-the-art electronic device fabrication techniques will be applied during the project, including thermal evaporation, magnetron sputtering, spin-coating
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. We take a bottom-up approach to robotics and develop soft materials and devices that would enable unusual form and unconventional functions for broader robotic applications. Job description Track 1
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Versatile Top-Down Patterning Technique for Perovskite On-Chip Integration. ACS Nano, 2025. State-of-the-art electronic device fabrication techniques will be applied during the project, including thermal
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concepts to connect detuned frequency ladders and induce phase locking across devices Studying the interplay of nonlinear dynamics, symmetry, and disorder in coupled comb arrays The first milestone is to
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capability of edge devices in buildings coupled with the complex interconnections and time varying dynamics. Addressing these challenges requires the development of the next generation of efficient data-driven
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at the nanoscale on magnetic and ferroelectric materials. Project background Ferromagnetic and ferroelectric (“ferroic”) materials lie at the heart of modern technologies, underpinning devices from motors and
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devices. In the endeavor to make faster and more energy efficient materials, we will manufacture arrays of interacting nanomagnets (so-called artificial spin ice) and determine their interaction with
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running codes on HPC clusters). Knowledge of (or prior research) in robotics (e.g., ROS, forward/inverse kinematics), manufacturing (e.g., Additive or Subtractive Manufacturing), or computer vision/language