Abstract
The transition toward a circular economy (CE) in global manufacturing is hindered by challenges such as limited traceability, fragmented waste flows, and lack of compliance enforcement. Blockchain technology, with its capabilities in transparency, immutability, and decentralization, presents a promising solution to address these gaps. This study develops a decision-oriented framework to evaluate blockchain-enabled strategies for circular waste management. Drawing on expert insights collected through a Delphi process and applying the Best-Worst Method (BWM) and TOPSIS, the research prioritizes strategic alternatives based on key criteria including traceability, regulatory compliance, and ease of integration. The results reveal that material traceability platformsand smart contracts for reverse logistics are the most viable blockchain applications for enhancing circularity. A case study in the electronics sector and sensitivity analysis further validate the robustness and applicability of the findings. This research contributes to both theory and practice by offering a structured, replicable model for aligning blockchain adoption with sustainable manufacturing goalsainable manufacturing goals.
Bathaei, A.; Bahramimianrood, B.; Awang, S. R. 2025. Blockchain-enabled circular economy: Rethinking waste management in global manufacturing. Transformations and Sustainability. eISSN 3030-2285. 1(2), p. 118–131. DOI: 10.63775/1xwx6s13.