Supply chains are increasingly exposed to systemic disruptions arising from geopolitical tensions, climate extremes, and volatile demand patterns, challenging traditional risk management approaches. Conventional predictive analytics often rely on correlational models that perform poorly under structural breaks, cascading failures, and policy-driven shocks. From a broader perspective, advances in artificial intelligence and data science offer new opportunities to model complex interdependencies, anticipate nonlinear propagation effects, and support resilient decision making across global supply networks. This abstract focuses on causal machine learning and advanced data analytics as an emerging paradigm for supply chain resilience modeling. Causal approaches move beyond prediction to explicitly represent cause–effect relationships among suppliers, transportation links, inventories, policies, and external stressors. By integrating causal graphs, structural causal models, and counterfactual reasoning with large-scale operational data, these methods enable analysts to distinguish spurious correlations from actionable drivers of disruption. When combined with probabilistic forecasting, graph-based learning, and simulation, causal models provide a robust foundation for stress testing supply chains under hypothetical geopolitical sanctions, climate-induced infrastructure failures, and abrupt demand surges. The discussion narrows to practical implementation considerations, including data integration from trade flows, climate observations, and policy indicators; model identification under partial observability; and validation using historical shock events. The abstract also highlights how causal analytics support scenario planning, intervention evaluation, and resource allocation decisions, allowing organizations to compare mitigation strategies before deployment. Ultimately, causal machine learning enhances supply chain resilience by improving interpretability, adaptability, and decision confidence in environments characterized by uncertainty, interdependence, and rapid change, positioning it as a critical capability for resilient global operations. Future research should integrate policy feedbacks, governance mechanisms, and real-time decision support systems.