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about the vibrational (phonon) dynamics of a molecule’s interactions with its environment [2]. We will extend this to, e.g., complex molecules, ultimately seeking to identify photonic signatures of non
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, curriculum over geometry/BCs, calibration of predictive uncertainty, and robustness to sensor noise. Tasks: forward prediction (temperature fields), inverse reconstruction (defect size, depth, orientation
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uncertainty, modality dropout, and noise propagation, which can degrade robustness and erode trust in model outcomes. This project aims to create a unified framework for building lightweight, data-efficient
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terahertz (THz) radiation and the collective vibrational modes of biological macromolecules is an emerging field in physical chemistry. Terahertz radiation can be exploited to studying spectroscopic and
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will uncover the interfacial solvation structure, validated through comparison between computed and experimental sum-frequency vibrational spectroscopies, as well as the mechanism of chemical
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scattering (SERS) and infrared (IR) spectroscopy will be employed to probe vibrational signatures, revealing structural changes and interactions at the single-molecule level [1-5]. A significant aspect of the
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, optimized for coupling with molecular vibrational and electronic transitions. By embedding selected organic or hybrid molecules into these cavities, the research will probe the emergence of quantum light
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on developing optical setup to achieve controlled ultrafast switching driven by intense femtosecond laser pulses. The project will explore how localized plasmonic fields modulate the electronic and vibrational
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recordings from the Seismic Research Centre (SRC) at the University of the West Indies (1) and those to be collected in a large nodal deployment, the candidate will apply noise tomographic technique to reveal
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Mapping and Embodied Listening for Long-Term Public Engagement with Anthropogenic Marine Noise Exploring Techno-Spiritual Experiences for Place-Based Interaction Networks of Play: Community Building, Tools