Assessing year-round capacity of single-species and mixed hedges to provide rainfall attenuation—case study of containerised model hedges

Blanusa, Tijana; Hadley, James; Larsen, Elisabeth K.; Bilsborrow, Jordan; Gush, Mark B.

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Blanusa, T., Hadley, J., Larsen, E. K., Bilsborrow, J. and Gush, M. B. (2026) Assessing year-round capacity of single-species and mixed hedges to provide rainfall attenuation—case study of containerised model hedges. Environments, 13 (5). 252. ISSN 2076-3298 doi: 10.3390/environments13050252

Abstract/Summary

Single-species hedges can help mitigate a range of urban and climate change-related issues, such as slowing stormwater flow and reducing rainfall runoff, particularly during the growing season. There is, however, little information on the service delivery of mixed hedges and their comparison to single-species, year-round, as well as on the practicality of functional rather than ornamental plant mixing. Here, we report on an initial case study to address this. Chosen hedge taxa (Crataegus monogyna, Elaeagnus × submacrophylla ‘Gilt Edge’, Ligustrum ovalifolium, Thuja plicata ‘Atrovirens’) represented a range of plant characteristics. These were trialled outdoors in Reading (SE England, UK) as treatment groupings of either single-species or mixed-species (‘evergreen’ and ‘broadleaf’ mix), along with a bare soil control, in 110 L troughs. We applied 5 min simulated rainfall onto each treatment twice in every meteorological season and assessed canopy throughfall. We also monitored substrate moisture content change as a proxy for evapotranspiration and substrate storage capacity of subsequent rainfall. During summer, the deciduous taxa and mixed hedges had the highest evapotranspiration rates, suggesting their potential to influence soil water storage, but in our experimental setup, that did not translate into significant differences in substrate moisture between treatments. During autumn and winter, the single-species Thuja treatment had the highest rainfall interception rate, followed by both mixed species treatments. In winter, canopy and leaf characteristics rather than physiological activity correlated with increased rainfall attenuation. However, by the end of the experiment (spring 2023), Crataegus, Thuja and both mixed hedge treatments had significantly lower throughfall (higher interception) compared to bare soil. We are continuing to test these treatments in a longer-term field experiment. Management of mixed-species hedges for rainfall attenuation is practically achievable, despite some differences in in-dividual species’ growth rates and plant habits.

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Item Type	Article
URI	https://centaur.reading.ac.uk/id/eprint/129547
Identification Number/DOI	10.3390/environments13050252
Refereed	Yes
Divisions	Life Sciences > School of Agriculture, Policy and Development > Department of Crop Science
Uncontrolled Keywords	canopy retention; Crataegus; Elaeagnus; hawthorn; Ligustrum; Thuja; soil moisture
Publisher	MDPI
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