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/or computational biology. Research will focus on both top-down and bottom-up mapping of local interactions between relatively simple dynamic entities and their emergent complex behavior. We study these
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(yes, that means some museum and fieldwork!). Comparative analysis using advanced computational tools and wet lab techniques. Hands-on dissections of invertebrates for anatomical and physiological
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habitats to develop “beaver-bots,” robotic tools inspired by beavers that work within and alongside natural systems; and (5) Planetary Design Computation—testing the potential of using targeted local
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degree in Computer Science or a related area by the expected start date. Additional Qualifications Relevant areas of expertise include: algorithms and complexity, natural language processing, and knowledge
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habitats to develop “beaver-bots,” robotic tools inspired by beavers that work within and alongside natural systems; and (5) Planetary Design Computation—testing the potential of using targeted local
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basic skills coding with AI assistance. Proven ability to lead workshops and effectively communicate complex ideas to academic and general audiences. Strong analytical, problem-solving, and communication
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, and how brains acquire heritable adaptations for complex, learned behaviors. Comparisons between modern humans and our living primate relatives provide a way to address this question in the context
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closely with experts in AI, materials science, and microfluidics to create a modular, tunable system for complex analyte analysis. Subprojects include: 1. Development of Highly Specific Gas Sensors
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., PISA), (2) Non-biochemical Evolution of Chemical Complexity, (3) Non-biochemical Self-reproducing Chemical Systems, (4) Chemical Computation using Oscillatory Chemistry or Cellular Automata, and (5) Life
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. We are looking for exceptional candidates with background in machine learning and/or computational biology. Research will focus on both top-down and bottom-up mapping of local interactions between