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The Role of the Ecosystem Engineer, the Leaf‐Cutter Ant Atta cephalotes , on Soil CO 2 Dynamics in a Wet Tropical Rainforest
Author(s) -
FernandezBou A. S.,
Dierick D.,
Swanson A. C.,
Allen M. F.,
Alvarado A. G. F.,
ArtaviaLeón A.,
CarrasquilloQuintana O.,
Lachman D. A.,
Oberbauer S.,
PintoTomás A. A.,
RodríguezReyes Y.,
Rundel P.,
Schwendenmann L.,
Zelikova T. J.,
Harmon T. C.
Publication year - 2019
Publication title -
journal of geophysical research: biogeosciences
Language(s) - English
Resource type - Journals
eISSN - 2169-8961
pISSN - 2169-8953
DOI - 10.1029/2018jg004723
Subject(s) - soil water , nest (protein structural motif) , environmental science , ecosystem , ecology , agronomy , biology , soil science , biochemistry
Abstract Leaf‐cutter ants are dominant herbivores that disturb the soil and create biogeochemical hot spots. We studied how leaf‐cutter ant Atta cephalotes impacts soil CO 2 dynamics in a wet Neotropical forest. We measured soil CO 2 concentration monthly over 2.5 years at multiple depths in nonnest and nest soils (some of which were abandoned during the study) and assessed CO 2 production. We also measured nest and nonnest soil efflux, nest vent efflux, and vent concentration. Nest soils exhibited lower CO 2 accumulation than nonnest soils for the same precipitation amounts. During wet periods, soil CO 2 concentrations increased across all depths, but were significantly less in nest than in nonnest soils. Differences were nonsignificant during drier periods. Surface efflux was equal across nest and nonnest plots (5 μmol CO 2 m −2 s −1 ), while vent efflux was substantially (10 3 to 10 5 times) greater, a finding attributed to free convection and sporadic forced convection. Vent CO 2 concentrations were less than in soil, suggesting CO 2 efflux from the soil matrix into the nest. Legacy effects in abandoned nests were still observable after more than two years. These findings indicate that leaf‐cutter ant nests provide alternative transport pathways to soil CO 2 that increase total emissions and decrease soil CO 2 concentrations, and have a lasting impact. Estimated total nest‐soil CO 2 emissions were 15 to 60% more than in nonnest soils, contributing 0.2 to 0.7% to ecosystem‐scale soil emissions. The observed CO 2 dynamics illuminate the significant carbon footprint of ecosystem engineer Atta cephalotes and have biogeochemical implications for rainforest ecosystems.