Plastic is one of the most visibly polluting elements in our environment. From big plastic accumulation zones at sea to microplastic entering our everyday drinking water, plastic is becoming a more evident pollutant every day, which is damaging ecosystems, marine life and human health. This paper will envision a possible solution for plastic pollution in North West Europe, through the retrieval and recycling of plastic, and by proposing an alternative for plastics in the current textile industry; algae. The strategy of this project aims to create a more circular and local economy by envisioning how substituting bio-plastics in a specific industry can be a solution towards minimising overall plastic pollution. Drawing on climate change as an environmental impactor; algae bloom, which is seen as a negative climate change product, will in this project become a catalyst for a change within the textile industry by making bioplastics. Through introducing a new perspective on how the relationship between consumer hubs and production hubs could be adjusted to become more sustainable, this project aims to showcase a solution that could be implemented in other areas with plastic pollution, by taking North-West Europe as a test case. Simultaneously, the project aims to pinpoint how crisis can become an opportunity in times like these.

The Beijing-Tianjin-Hebei (BTH) Metropolitan Region faces significant challenges, including drought, severe precipitation, floods, subsidence, societal disparities, air pollution, and an aging population. Fragmented spatial and institutional frameworks hinder effective responses, perpetuating vulnerabilities. This study focuses on enhancing water resilience with an emphasis on environmental justice in vulnerable areas between major cities. The proposed low-density development approach aims to balance economic productivity with ecological sensitivity, creating a decentralized, self-reliant, and resilient region. The strategy integrates ecosystem-based adaptation, integrated water resources management, and water-sensitive village reorganization. A shift from a profit-centric model to one prioritizing water risk reduction in vulnerable areas is crucial for achieving environmental justice. The research employs pattern languages and the dynamic adaptive pathway method to organize potential measures, integrating future objectives, intervention patterns, and scenarios to feasibly implement actions by 2060. Ultimately, the research envisions self-resilient units contributing crucial ecosystem services to urban centers and receiving support through knowledge exchange and economic assistance. This transformation will turn these units from sacrificial entities into integral components of sustainable development in the BTH region. Validated by both quantitative and qualitative assessments, this shift is anticipated to strengthen the water resilience of individual units and enhance the overall resilience of the metropolitan area.