Abstract
Climate change presents systemic uncertainties for coastal industrial infrastructure, where the interaction between severe meteorological hazards and accelerated structural aging remains partially understood. This study proposes an empirical evaluation framework designed to intersect high-resolution local climate projections with real-time structural dynamic response tracking in aggressive marine environments. During a six-month deployment at an operational coastal manufacturing facility, our initial linear predictive flows regarding thermodynamic loading were severely disrupted by unexpected, non-linear coupling effects between micro-chemical electrolyte accumulation and boundary layer wind field variations, which induced premature sealing failures in critical sensory systems and required iterative structural calibration. Empirical data from multi-objective simulations indicate that while optimizing building thermal energy allocation nominally reduces macro-environmental strain, the concurrent low-frequency vibrations from extreme wind events simultaneously amplify localized stress concentrations along mechanical interfaces. This structural paradox might be explained by micro-scale material fatigue or localized galvanic couplings accelerated by high-salinity brine exposure. Considering these entangled dynamics, this multidimensional assessment offers a possible methodology for reinforcing heavy industrial assets against climate volatility without inducing secondary material wear; however, further research is needed to fully quantify the long-term non-linear degradation kinetics of synthetic dampening polymers under fluctuating thermo-mechanical stress.

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