Research in climaticecology covers scales from local habitats to global biomes and examines terrestrial and aquatic systems, including human-modified landscapes. Core topics include shifts in species distributions and phenology, changes in ecosystem productivity and resilience, carbon and nutrient cycling, disturbance regimes such as fire and drought, invasive species, biodiversity patterns, ecosystem services, and adaptation and mitigation strategies. It also considers the timing and intensity of extreme events and their ecological consequences.
Methodologically, climaticecological work combines climate-model outputs with ecological models and empirical data. It relies on long-term observations, remote sensing, field and lab experiments (for example warming experiments or CO2 enrichment), and meta-analyses to attribute ecological changes to climate drivers and project future trajectories.
Applications include informing conservation planning, land-use management, restoration, and climate policy. By linking ecological responses to climate scenarios, climaticecology supports assessments of carbon budgets, ecosystem resilience, and the potential co-benefits of adaptation and mitigation options.
As a cross-disciplinary field, climaticecology faces challenges such as uncertainties in climate projections, scale mismatches between models and ecological processes, data limitations, and attribution of observed changes to climate vs other drivers. The term is not universally formalized and is used variably, often as a descriptor for integrative work rather than a standalone discipline. It complements related fields such as climatology, ecology, eco-physiology, and Earth-system science. Notable areas of study include polar and alpine ecosystem responses to warming, tropical forest dynamics under rainfall changes, coral reef vulnerability to warming and acidification, and peatland carbon release following permafrost thaw.