Scientists have long recognised the Arctic as a final sink for many persistent pollutants, but the precise ways in which microplastics influence the region's fragile climate balance have remained elusive. Their unique physical and chemical properties—light absorption, gas emission potential, and capacity to carry toxic additives—set them apart from conventional contaminants. Although earlier surveys confirmed the presence of plastics in sea ice and snow, the magnitude and mechanisms of their climatic effects have been hampered by disparate monitoring protocols, limited spatial coverage, and a lack of standardised quality control. Based on these challenges, an international research team synthesised the available evidence to construct a comprehensive framework that links pollution sources, transport, ecological impacts, and climate feedbacks, providing a much‑needed roadmap for future investigation and policy action.
Now, a critical review published (DOI: 10.1007/s11783‑026‑2239‑0) in the journal ENGINEERING Environment (Volume 20, Issue 9, 2026;) by researchers from Tongji University (Shanghai, China), the Norwegian Polar Institute, and The Arctic University of Norway delivers the most integrated assessment to date. The study systematically maps the major transport pathways—atmospheric, oceanic, and local—and details how microplastics infiltrate Arctic food webs and interact with physical and biogeochemical processes that govern regional climate.
The review presents several striking findings. Fibrous particles, predominantly polyester from textiles, constitute the overwhelming majority of microplastics, accounting for up to 92% in snow and 73% in sea ice algae. In the ice alga Melosira arctica, concentrations reached 31,000 particles per cubic metre—over ten times higher than in the ambient seawater—making it a potent entry point for pollutants into the pelagic food web. Beyond biological uptake, the study quantifies how microplastics reduce surface albedo, thereby enhancing solar absorption and accelerating melt, while also emitting carbon dioxide (CO₂) and methane (CH₄) under ultraviolet irradiation and microbial action. These mechanisms directly amplify the “Arctic amplification” effect, where the region warms three to four times faster than the global mean. The authors also highlight that airborne microplastic fibres can act as cloud condensation nuclei, potentially altering cloud properties and precipitation, adding another layer of climatic influence that has been largely overlooked in current climate models.
The authors said, “We are witnessing a paradigm shift: microplastics are no longer just a waste problem—they are geophysical agents. They modify surface energy balance, contribute to greenhouse gas fluxes, and interfere with carbon sequestration. The Arctic, already warming at an alarming rate, is now subject to this additional stressor, which could accelerate feedbacks that are difficult to reverse. Our review underscores the urgent need to treat microplastics as a climate‑relevant pollutant in international negotiations and monitoring programmes.”
The implications extend far beyond scientific curiosity. Current governance structures are fragmented and largely non‑binding, lacking specific concentration thresholds or enforceable mechanisms tailored to Arctic conditions. The study proposes a new regulatory model inspired by the European Union’s Registration, Evaluation, Authorization and Restriction of Chemicals (REACH) framework, recommending clear limits on microplastic content in products and discharge caps for ships, research stations, and coastal communities. It also calls for standardised multi‑matrix monitoring—covering water, ice, snow, sediments, and biota—to enable consistent trend assessments. This research provides the scientific underpinning for a legally binding international plastics treaty, urging policymakers to act decisively before the Arctic’s feedback loops become irreversible and fundamentally destabilise the global climate system.
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References
DOI
10.1007/s11783-026-2239-0
Original Source URL
https://doi.org/10.1007/s11783-026-2239-0
Funding information
This study was supported by the National Natural Science Foundation of China (Nos. 52070145 and 51778453).
About ENGINEERING Environment
ENGINEERING Environment is an international journal in environmental disciplines, jointly sponsored by the Chinese Academy of Engineering, Tsinghua University, and Higher Education Press. The journal is dedicated to advancing and disseminating the discoveries of cutting-edge theories, innovations in engineering technology, and practices in technological application within the environmental discipline. Adhering to the principle of integrating scientific theories with engineering technologies, the journal emphasizes the convergence of environmental protection with One Health, climate change response, and sustainable development. It places particular emphasis on the forward-looking nature of novel technologies and emerging challenges, the practicality of solutions, and interdisciplinary innovations.