Biotic degradation at night, abiotic degradation at day: positive feedbacks on litter decomposition in drylands

Gliksman, Daniel; Rey, Ana; Seligmann, Ron; Dumbur, Rita; Sperling, Or; Navon, Yael; Haenel, Sabine; Angelis, Paolo De; Arnone, John A.; Grünzweig, José M.

doi:10.1111/gcb.13465

Cited by 83 publications

(101 citation statements)

References 63 publications

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“…In addition, moisture is an important requirement for decomposition in dry environments (Gliksmanet al. ). The strong sun and dry conditions in our open sites likely impede the microbial process that would facilitate decomposition.…”

Section: Discussionmentioning

confidence: 99%

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Wood decomposition is more rapid on than off termite mounds in an African savanna

2019

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Decomposition is important for nutrient cycling and the dynamics of soil organic matter. The factors that influence local decomposition rates in savannas dominated by Macrotermes mounds remain uncertain. Here, we experimentally assessed the effects of macro-and micro-detritivores, active and inactive mounds, and vegetation cover on wood decomposition rates for eight common woody plant species in Lake Mburo National Park, in Uganda. Five pairs of Macrotermes mounds, one active and one inactive per pair, were selected. Each mound provided two sample locations, one, the most shaded (with canopy cover), and one, the most open (without canopy cover) edge of mound. In addition, for each mound pair, one additional sample location was located off-mound, in an open level area between the mounds. After one, three, and 12 months, protected (wrapped in 1-mm mesh fiber-glass excluding macrodetritivores) and unprotected wood samples from each location were retrieved, brushed clean, oven-dried, and weighed. After 12 months, mean percentage mass loss was four times higher for unprotected than protected wood samples across all species located on mound sites (when decomposition in shaded and open microhabitats was combined). Mean percentage mass loss across all species combined was 1.2 times higher on active than inactive mounds. Across all mounds, decomposition was on average 1.1 times more rapid in the shaded than open mound parts. These differences were more pronounced on inactive mounds (1.3 times more rapid in the shaded than open parts). Percentage mass loss was markedly lower off-mound (12.6 AE 0.8%) than on active (25.9 AE 1.5%) or inactive mounds (19.7 AE 1.2%). Proportional mass loss for unprotected wood decreased with increasing wood density, but proportional mass loss of protected wood samples was not detectably influenced by wood density. Our study highlights the strong and locally contingent influence of termite mounds, termite activity, vegetation, and their interactions on wood decomposition rates within a savanna landscape. Furthermore, variation in per-species wood decomposition rates, including the negative correlation with wood density, depends on accessibility to macrodetritivores.

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Section: Discussionmentioning

confidence: 99%

“…We expected decomposition rates to be higher in the shaded microhabitat because of enhanced moisture availability (Gliksman et al. ). (4) Does wood density influence decomposition?…”

Section: Introductionmentioning

confidence: 99%

Wood decomposition is more rapid on than off termite mounds in an African savanna

2019

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“…Hence, the contribution of photodegradation to soil C balance could be greater than our estimation at the ecosystem level (see, e.g. Gliksman et al, 2016). Although the contribution of surface exchanges was only marginal as compared to the annual CO 2 efflux, removing the biocrust processes would substantially reduce the model validity.…”

Section: Modelled Plant-interspace Differences In C Flux Componentsmentioning

confidence: 73%

“…Photodegradation is likely to dominate the mineralization during dry daytime periods, when radiation is strong and microbial activities are prohibited by low moisture content and high temperatures (e.g. Gliksman et al, 2016). On an annual basis, photodegradation could consume more than 10 % of soil organic matter (SOM) at the surface (e.g.…”

Section: Introductionmentioning

confidence: 99%

Modelling the diurnal and seasonal dynamics of soil CO<sub>2</sub> exchange in a semiarid ecosystem with high plant–interspace heterogeneity

et al. 2018

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Abstract. We used process-based modelling to investigate the roles of carbon-flux (C-flux) components and plantinterspace heterogeneities in regulating soil CO 2 exchanges (F S ) in a dryland ecosystem with sparse vegetation. To simulate the diurnal and seasonal dynamics of F S , the modelling considered simultaneously the CO 2 production, transport and surface exchanges (e.g. biocrust photosynthesis, respiration and photodegradation). The model was parameterized and validated with multivariate data measured during the years 2013-2014 in a semiarid shrubland ecosystem in Yanchi, northwestern China. The model simulation showed that soil rewetting could enhance CO 2 dissolution and delay the emission of CO 2 produced from rooting zone. In addition, an ineligible fraction of respired CO 2 might be removed from soil volumes under respiration chambers by lateral water flows and root uptakes. During rewetting, the lichen-crusted soil could shift temporally from net CO 2 source to sink due to the activated photosynthesis of biocrust but the restricted CO 2 emissions from subsoil. The presence of plant cover could decrease the root-zone CO 2 production and biocrust C sequestration but increase the temperature sensitivities of these fluxes. On the other hand, the sensitivities of root-zone emissions to water content were lower under canopy, which may be due to the advection of water flows from the interspace to canopy. To conclude, the complexity and plant-interspace heterogeneities of soil C processes should be carefully considered to extrapolate findings from chamber to ecosystem scales and to predict the ecosystem responses to climate change and extreme climatic events. Our model can serve as a useful tool to simulate the soil CO 2 efflux dynamics in dryland ecosystems.

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“…During summer in SDS, the Cistus plant community, unable to access deep water, moved to a dormant status in order to maintain turgor. This caused a reduction in photosynthates and substrate availability; however, the observed summer depression of SR was not due to a modification of SR h but to the suppression of autotrophic respiration, as already similarly observed in other ecosystem types under drought [13,58,59], and SR h accounted for almost 100% of SR. Concurrently, a significant increase in WEOC was observed, likely because of the high root mortality occurring in summer in Mediterranean ecosystems [60,61] and the simultaneous photodegradation of surface litter at high irradiance [62,63], which both release high amounts of C into the soil. At the same time, a change in the microbial community assemblage could be detected.…”

Section: Discussionmentioning

confidence: 99%

The Response of Soil CO2 Efflux to Water Limitation Is Not Merely a Climatic Issue: The Role of Substrate Availability

Dato¹,

Lagomarsino²,

Lellei‐Kovács

et al. 2017

Forests

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Abstract:Water availability, together with temperature, represents the most limiting abiotic factor regulating soil CO 2 efflux (SR). Besides the direct effect of water limitation, drought also influences plant activity, determining changes in the quality and quantity of root exudates, thus indirectly affecting soil microbial activity. To determine how the seasonal changes of plant activity and soil microbial metabolism and structure affect SR response to drought, we investigated the correlation between leaf gas exchange, soil carbon pools and soil respiration sources and the role of soil carbon pools on microbial populations and soil respiration, in a summer deciduous Mediterranean (SDS) and a winter deciduous temperate (WDS) shrublands, experiencing a dry summer period. In both sites, drought reduced photosynthesis, but affected SR differently: in SDS, SR decreased, although microbial heterotrophic respiration (SR h ) remained unchanged; in WDS, SR did not vary but SR h was reduced. While in SDS the microbial community was able to respire more complex substrates, in WDS it was strongly dependent on easily decomposable molecules, thus on plant activity. Therefore, the response of soil CO 2 efflux to water limitation is not exclusively influenced by climate as it is modulated by the degree of adaptation of the microbial community to drought.

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Biotic degradation at night, abiotic degradation at day: positive feedbacks on litter decomposition in drylands

Cited by 83 publications

References 63 publications

Wood decomposition is more rapid on than off termite mounds in an African savanna

Wood decomposition is more rapid on than off termite mounds in an African savanna

Modelling the diurnal and seasonal dynamics of soil CO<sub>2</sub> exchange in a semiarid ecosystem with high plant–interspace heterogeneity

The Response of Soil CO2 Efflux to Water Limitation Is Not Merely a Climatic Issue: The Role of Substrate Availability

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Biotic degradation at night, abiotic degradation at day: positive feedbacks on litter decomposition in drylands

Cited by 83 publications

References 63 publications

Wood decomposition is more rapid on than off termite mounds in an African savanna

Wood decomposition is more rapid on than off termite mounds in an African savanna

Modelling the diurnal and seasonal dynamics of soil CO&lt;sub&gt;2&lt;/sub&gt; exchange in a semiarid ecosystem with high plant–interspace heterogeneity

The Response of Soil CO2 Efflux to Water Limitation Is Not Merely a Climatic Issue: The Role of Substrate Availability

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Modelling the diurnal and seasonal dynamics of soil CO<sub>2</sub> exchange in a semiarid ecosystem with high plant–interspace heterogeneity