Quantum-Inspired Reinforcement Learning Shows Carbon Reduction for AIoT Supply Chains

The rapid expansion of AIoT devices across logistics has intensified the need for intelligent, environmentally responsible supply‑chain management. Traditional optimisation techniques often treat efficiency, security, and sustainability as separate problems, leading to sub‑optimal trade‑offs. Quantum‑inspired reinforcement learning bridges this gap by borrowing concepts from quantum control—specifically spin‑chain dynamics—to create a unified decision‑making framework that simultaneously addresses carbon footprints, inventory accuracy, and cyber‑risk mitigation.

At the core of the new method is a Hamiltonian spin‑chain representation of the supply network, which translates real‑time IoT signals into controllable quantum‑like states. A multi‑objective reward function, window‑normalised across fidelity, security, and emissions, guides a value‑based learner with ensemble updates. Simulations reveal smooth convergence, strong late‑episode performance, and graceful degradation under bit‑flip, depolarising, and phase‑flip noise—conditions that mimic real‑world disruptions and adversarial attacks. Compared with standard reinforcement‑learning and model‑based baselines, the quantum‑inspired approach consistently delivers higher stability and lower carbon metrics.

For industry, this breakthrough signals a viable route to meet tightening ESG regulations while safeguarding supply‑chain integrity. Companies can leverage the framework to design adaptive logistics policies that dynamically balance cost, speed, and environmental impact, reducing reliance on separate sustainability initiatives. Although current results are simulation‑based, ongoing research aims to validate the model on physical hardware and integrate distributed learning across decentralized IoT nodes. As quantum‑inspired algorithms mature, they are poised to become a cornerstone of next‑generation, resilient, and low‑carbon supply‑chain ecosystems.