Reducing conditions, reactive metals, and their interactions can explain spatial patterns of surface soil carbon in a humid tropical forest

Citation data:

Biogeochemistry, ISSN: 1573-515X, Vol: 125, Issue: 2, Page: 149-165

Publication Year:
2015
Usage 111
Abstract Views 53
Downloads 36
Full Text Views 18
Link-outs 4
Captures 30
Readers 30
Citations 19
Citation Indexes 19
Repository URL:
https://lib.dr.iastate.edu/eeob_ag_pubs/106; https://works.bepress.com/steven_hall1/10
DOI:
10.1007/s10533-015-0120-5
Author(s):
Hall, Steven J.; Silver, Whendee L.
Publisher(s):
Springer Nature
Tags:
Environmental Science; Earth and Planetary Sciences; Dead Fine Root Biomass; Lowe Montane Forest; Live Fine Root; Decomposition Rate; Montane Site; Tropical Montane Forest; Root Productivity; Total Fine Root; Bulk Soil; Root Biomass Allocation; Ous Horizon; Bulk Density; Litter Decomposition Rate; Oxalate; Landscape Pattern
article description
Humid tropical forests support large stocks of surface soil carbon (C) that exhibit high spatial variability over scales of meters to landscapes (km). Reactive minerals and organo-metal complexes are known to contribute to C accumulation in these ecosystems, although potential interactions with environmental factors such as oxygen (O) availability have received much less attention. Reducing conditions can potentially contribute to C accumulation, yet anaerobic metabolic processes such as iron (Fe) reduction can also drive substantial C losses. We tested whether these factors could explain variation in soil C (0–10 and 10–20 cm depths) over multiple spatial scales in the Luquillo Experimental Forest, Puerto Rico, using reduced iron (Fe(II)) concentrations as an index of reducing conditions across sites differing in vegetation, topographic position, and/or climate. Fine root biomass and Fe(II) were the best overall correlates of site (n = 6) mean C concentrations and stocks from 0 to 20 cm depth (r = 0.99 and 0.98, respectively). Litterfall decreased as reducing conditions, total and dead fine root biomass, and soil C increased among sites, suggesting that decomposition rates rather than C inputs regulated soil C content at the landscape scale. Strong relationships between Fe(II) and dead fine root biomass suggest that reducing conditions suppressed particulate organic matter decomposition. The optimal mixed-effects regression model for individual soil samples (n = 149) showed that aluminum (Al) and Fe in citrate/ascorbate and oxalate extractions, Fe(II), fine root biomass, and interactions between Fe(II) and Al explained most of the variation in C concentrations (pseudo R = 0.82). The optimal model of C stocks was similar but did not include fine root biomass (pseudo R = 0.62). In these models, soil C concentrations and stocks increased with citrate/ascorbate-extractable Al and oxalate-extractable Fe. However, soil C decreased with citrate/ascorbate-extractable Fe, an index of Fe susceptible to anaerobic microbial reduction. At the site scale (n = 6), ratios of citrate/ascorbate to oxalate-extractable Fe consistently decreased across a landscape O gradient as C increased. We suggest that the impact of reducing conditions on organic matter decomposition and the presence of organo-metal complexes and C sorption by short-range order Fe and Al contribute to C accumulation, whereas the availability of an Fe pool to sustain anaerobic respiration in soil microsites partially attenuates soil C accumulation in these ecosystems.