Abstract:
As cities continue to densify, opportunities to introduce green areas decrease. Small urban green spaces, such as pocket parks, often represent the only remaining non-built-up areas within compact urban fabrics. Through shading, evapotranspiration, and the enhancement of air circulation, these spaces can provide microclimatic benefits; yet the cooling capacity of pocket parks and the role of their internal forest structure remain insufficiently explored. This study quantifies the association between forest structure, configuration, and species composition of urban pocket parks and morning cooling performance during a heat wave in the city of Barcelona, Spain. Moving beyond the conventional emphasis on tree canopy cover alone, the role of vertical structure of 627 urban trees was investigated. Five cooling indices—Park Cooling Distance (PCD), Park Cooling Area (PCA), Park Cooling Efficiency (PCE), Park Cooling Intensity (PCI), and Park Cooling Gradient (PCG)—were used to evaluate 18 pocket parks in densely built-up areas of the city. Statistical analyses assessed relationships between internal park characteristics and cooling performance, identifying the structural configurations with the strongest association. Results showed an average PCD of 55.8 m, PCA of 1.44 ha, PCE of 7.9, PCI of 1.2 °C, and PCG of 0.02 °C∙m⁻¹ in the studied pocket parks. Tree height, tree density, percentage of tree cover, and vertical structural variability were significantly correlated with PCE, PCI, and PCG, whereas no significant relationships were observed with PCD. The pocket parks exhibiting the strongest cooling performance association shared distinct structural characteristics, i.e., dense (>150 trees∙ha-1), predominantly monospecific trees concentrated in the upper canopy layer (>8.6 m) and were characterized by high canopy cover (>86%). These findings reveal that internal tree structure correlates to pocket park cooling performance. Design and management-oriented actions, focused on forest structure, may significantly enhance urban cooling and thermal comfort, contributing to climate adaptation strategies in compact urban environments.
Citation:
Eduardo Antenucci, Elena Di Pirro, Matilda van den Bosch, Rocco Pace, Bruno Lasserre, Marco Marchetti, Vittorio Garfì, Beyond Tree Cover: Vertical Canopy Structure Is Associated with the Cooling Impact of Pocket Parks in Mediterranean Cities, Urban Forestry & Urban Greening, 2026,129371, ISSN 1618-8667, https://doi.org/10.1016/j.ufug.2026.129371