This research investigates whether small mangrove patches can effectively protect coastal areas from hurricanes. Using insect biodiversity and environmental DNA, it evaluates ecosystem functionality across patch sizes. The goal is to identify the minimum viable size for resilient mangrove systems, informing urban planning and improving coastal protection in space-limited environments.

This study modeled wild edible mushroom yields in Mediterranean forests using Planet satellite imagery, LiDAR, climate data, and field measurements. Results show that seasonal NDVI differences, precipitation, and forest structure are key predictors. Integrating high-resolution intra-annual remote sensing significantly improves yield prediction and ecological understanding.

This project addresses the gap between national and local forest data by integrating Spanish National Forest Inventories, forest maps, and municipal boundaries into interactive dashboards. Using Palencia as a case study, it tracks long-term evolution of pine and oak forests, supporting local decision-making through accessible visualization of forest stocks, carbon storage, and ecosystem services.

This study reviews mangroves of the Americas and their vulnerability to climate change. Mangroves are vital carbon sinks, biodiversity hotspots, and coastal protectors, but face threats from deforestation, pollution, and urban expansion. Effective conservation requires ecosystem-based restoration, improved management, and reduced human pressures to ensure long-term resilience.

This research examines Rotterdam’s urban tree planting practices and their impact on air quality and drought resilience. Findings show that current reliance on single-species tree lines reduces resilience, while greater species and functional diversity improves pollutant removal and climate adaptability. The study recommends transitioning to mixed-species, biodiversity-focused urban forestry strategies.