Carbon dioxide (CO₂) emissions by human activities have alarmingly increased in the past decades. A quarter of this anthropogenic CO₂ has been absorbed by the ocean, changing the chemistry and ultimately lowering the pH of the seawater, a phenomenon known as ocean acidification. The extra heat trapped in the atmosphere due to greenhouse gases is also causing the seawater warming. The process hampers the supply of nutrients to the upper ocean layers, due to a sharp stratification of the surface water column. Atmospheric warming is expected to evolve in the Mediterranean area 20% faster than the global average, and marine heatwaves will occur with increasing frequency by the end of the 21st century, with serious consequences for marine biodiversity and production. Coccolithophores, a very abundant group of marine calcifying phytoplankton, play a major role in the biogeochemical cycles and in the regulation of the global climate. These tiny algae, which measure 1/1000 of a mm, are at the basis of the aquatic trophic chain, and interact with atmospheric and oceanic CO₂ through calcification and photosynthesis. The study detailed the behaviour of these algae under conditions of water temperature ≥ 28°C and a pH of approximately 7.8 units. The results highlight a negative effect of thermal stress on coccolithophore cell production and calcification. Likewise, anomalous calcification in this group of phytoplankton was associated with ocean acidification.  This highlights the importance of looking at species-specific responses to climate change and addressing their specific adaptation mechanisms. Scientists believe that, due to the progressive increase of CO₂ emissions in the atmosphere, the risks derived from ocean warming and acidification will become even more acute in the coming decades, thus changing the plankton communities of the Mediterranean. In the future, a clear understanding of the interactions between the different components of the plankton communities will be essential to better understand the future impact of environmental changes on their adaptation and productivity.

My recent research led in collaboration with researchers from the BCNUEJ lab and colleagues from the United States highlights that urban climate resilience planning produces a new type of urban climate injustice: green climate gentrification. 

Our studies find that low-income, working class, and minority residents are among the social groups most likely to experience residential and social displacement—in the short and mid-term—from green climate infrastructure. Although green roofs, resilient parks and greenways, rain gardens, or detention basins and canals are increasingly hailed as win-win infrastructure to protect cities against climate change impacts, we argue that such interventions overlook or minimize negative impacts for socially vulnerable groups. At the same time, those projects sell the image of a green and resilient 21st-century city to investors, real estate developers, and new sustainability-class residents who are those most benefiting from green interventions. 

The research we conducted in Boston (on greening and resilience planning in East Boston) and Philadelphia (on green stormwater management infrastructure throughout the city) reveals that vulnerable populations—many of whom have already been exposed to hazardous conditions in their neighborhoods—now stand to benefit least from greening initiatives. For instance, in Philaldephia, we find a negative association between the siting of green infrastructure and increased minority population, and a strong positive association between green infrastructure siting, gentrification, and reduced minority and low-income population. In Boston, we find that the Boston real estate industry is building resilient properties for elites and displacing lower-income residents in East Boston, while advocating for the City of Boston to create new protection zones for future investments.

In sum, improvement of marginalized neighborhoods through green infrastructure may cause these vulnerable populations to lose their neighborhoods altogether.