The Contribution of Photodegradation to Litter Decomposition in Semiarid Mediterranean Grasslands Depends on its Interaction with Local Humidity Conditions, Litter Quality and Position

• Published in: Ecosystems (New York) Vol. 20; no. 3; pp. 527 - 542
• Main Authors: Almagro, María, Martínez-López, Javier, Maestre, Fernando T., Rey, Ana
• Format: Journal Article
• Language: English
• Published: New York Springer Science + Business Media 01.04.2017; Springer US; Springer; Springer Nature B.V
• Subjects: Arid zones; Biomass; Biomedical and Life Sciences; Carbon content; Carbon cycle; Climate change; Climatic conditions; Decay; Decomposition; Ecological function; Ecology; Ecosystems; Environmental Management; Experimental design; Geoecology/Natural Processes; Global temperature changes; Grasslands; Humidity; Hydrology/Water Resources; Leaf litter; Life Sciences; Moisture availability; Nitrogen; Original Articles; Photodegradation; Plant Sciences; Radiation; Retama; Retama sphaerocarpa; Soils; Steppes; Stipa; Ultraviolet radiation; Zoology; Mediterranean Area; MED; litter chemistry; drylands; moisture availability; photodegradation; leaf litter decomposition
• ISSN: 1432-9840; 1435-0629
• DOI: 10.1007/s10021-016-0036-5

Understanding how UV radiation interacts with prevailing climatic conditions and litter quality to determine leaf litter decomposition is fundamental for understanding soil carbon cycling pathways and ecosystem functioning in drylands. We carried out a field manipulative experiment to investigate how litter quality (labile and nitrogen-rich Retama sphaerocarpa vs. recalcitrant and nitrogen-poor Stipa tenacissima), position (on the ground vs. standing) and different UV radiation levels (UV pass vs. UV block) affect litter decomposition rates at two semiarid Mediterranean steppes with contrasting climates (continental vs. maritime) in a fully factorial experimental design. As expected, Retama litter decomposed faster than that of Stipa, and litter placed on the ground decayed faster than standing litter. However, and surprisingly, contrasting effects of UV radiation on litter decomposition were observed between the two sites. At the continental site, UV radiation increased litter decay constants by 21 % on average, although the contribution of photodegradation was larger when litter was placed on the ground rather than in standing litter. At the maritime site, decay constants were 15 % larger in the absence of UV radiation regardless of litter position. Significant litter type × UV exposure radiation and litter type × position interactions indicate that photodegradation contributes more to litter decomposition under less favorable moisture and substrate availability conditions for microbial decomposers. Our results emphasize the need to consider interactions between moisture availability, litter quality and UV radiation in litter decomposition models to fully understand litter decomposition impacts on soil carbon cycling and storage in drylands under climate change.