Seasonal changes in soil organic matter after a decade of nutrient addition in a lowland tropical forest

Turner, Benjamín L.; Yavitt, Joseph B.; Harms, Kyle E.; García, M.; Wright, S. Joseph

doi:10.1007/s10533-014-0064-1

Cited by 62 publications

(60 citation statements)

References 66 publications

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“…Turner et al [50] found a similar increase in soil C during the dry season in a more strongly seasonal forest on Barro Colorado Island in Panama. However, we did not observe a significant increase in soil N whereas the study in Panama did [50].…”

Section: Effects On Soil Nitrogen and Carbonmentioning

confidence: 75%

Effects of Hurricane-Felled Tree Trunks on Soil Carbon, Nitrogen, Microbial Biomass, and Root Length in a Wet Tropical Forest

Lodge

Winter

González

et al. 2016

Forests

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Decaying coarse woody debris can affect the underlying soil either by augmenting nutrients that can be exploited by tree roots, or by diminishing nutrient availability through stimulation of microbial nutrient immobilization. We analyzed C, N, microbial biomass C and root length in closely paired soil samples taken under versus 20-50 cm away from large trunks of two species felled by Hugo (1989) and Georges (1998) three times during wet and dry seasons over the two years following the study conducted by Georges. Soil microbial biomass, % C and % N were significantly higher under than away from logs felled by both hurricanes (i.e., 1989 and 1998), at all sampling times and at both depths (0-10 and 10-20 cm). Frass from wood boring beetles may contribute to early effects. Root length was greater away from logs during the dry season, and under logs in the wet season. Root length was correlated with microbial biomass C, soil N and soil moisture (R = 0.36, 0.18, and 0.27, respectively; all p values < 0.05). Microbial biomass C varied significantly among seasons but differences between positions (under vs. away) were only suggestive. Microbial C was correlated with soil N (R = 0.35). Surface soil on the upslope side of the logs had significantly more N and microbial biomass, likely from accumulation of leaf litter above the logs on steep slopes. We conclude that decaying wood can provide ephemeral resources that are exploited by tree roots during some seasons.

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Section: Effects On Soil Nitrogen and Carbonmentioning

confidence: 75%

Effects of Hurricane-Felled Tree Trunks on Soil Carbon, Nitrogen, Microbial Biomass, and Root Length in a Wet Tropical Forest

Lodge

Winter

González

et al. 2016

Forests

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“…Soil C might on average originate predominantly from roots rather than shoots (Rasse et al, 2005), and that may be the case in our soils in Panama because although changes in litter inputs have caused changes in soil C, they are small -approximately 1 % of total soil C per year -compared to the "normal" turnover of C of 25 % (0-10 cm soil) within 6 months (as calculated from changes in C concentration from wet season to dry season; Turner et al, 2015) and an annual turnover of about 7 % based on incorporation of 13 C into soils over decades (Schwendenmann and Pendall, 2008). Turnover rates of soil C are also high in other tropical forests; for example, in eastern Brazil 40-50 % of the C in the top 40 cm of soil had been fixed in about 32 years (Trumbore, 2000).…”

Section: Soil Carbon Dynamicsmentioning

confidence: 95%

“…Carbon in tropical forest soils is dynamic: Schwendenmann and Pendall (2008) reported a turnover time of 15 years for the "slow" pool of soil C, comprising 38 % of the total soil C, in the top 10 cm of soil in semi-evergreen rain forest on Barro Colorado Island, Panama (61 % of total soil C was "passive" with a turnover time of the order of a 1000 years). Turner et al (2015) reported an approximate 25 % increase in soil C from one dry season to the next wet season in the top 10 cm of soil on the Gigante Peninsula in Barro Colorado Nature Monument, Panama, at a site close to the current litter manipulation experiment. Thus, there is the potential for the amount of C in tropical soils to change over only a few years, with potentially important consequences for atmospheric CO 2 concentrations.…”

Section: Introductionmentioning

confidence: 92%

Changes in soil carbon and nutrients following 6 years of litter removal and addition in a tropical semi-evergreen rain forest

2016

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Abstract. Increasing atmospheric CO 2 and temperature may increase forest productivity, including litterfall, but the consequences for soil organic matter remain poorly understood. To address this, we measured soil carbon and nutrient concentrations at nine depths to 2 m after 6 years of continuous litter removal and litter addition in a semi-evergreen rain forest in Panama. Soils in litter addition plots, compared to litter removal plots, had higher pH and contained greater concentrations of KCl-extractable nitrate (both to 30 cm); Mehlich-III extractable phosphorus and total carbon (both to 20 cm); total nitrogen (to 15 cm); Mehlich-III calcium (to 10 cm); and Mehlich-III magnesium and lower bulk density (both to 5 cm). In contrast, litter manipulation did not affect ammonium, manganese, potassium or zinc, and soils deeper than 30 cm did not differ for any nutrient. Comparison with previous analyses in the experiment indicates that the effect of litter manipulation on nutrient concentrations and the depth to which the effects are significant are increasing with time. To allow for changes in bulk density in calculation of changes in carbon stocks, we standardized total carbon and nitrogen on the basis of a constant mineral mass. For 200 kg m −2 of mineral soil (approximately the upper 20 cm of the profile) about 0.5 kg C m −2 was "missing" from the litter removal plots, with a similar amount accumulated in the litter addition plots. There was an additional 0.4 kg C m −2 extra in the litter standing crop of the litter addition plots compared to the control. This increase in carbon in surface soil and the litter standing crop can be interpreted as a potential partial mitigation of the effects of increasing CO 2 concentrations in the atmosphere.

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“…1100 g m −2 , with c . 60% falling as leaves (Wright et al ., ; Turner et al ., ). The B stock is calculated on the basis of two‐thirds of the total leaf litter falling in the dry season.…”

Section: Resultsmentioning

confidence: 97%

“…Boron is similar to P in terms of its distribution in the tropical forest soil studied here: soluble concentrations are < 1 mg kg −1 , while total concentrations are primarily contained in recalcitrant forms that are not directly available to plants (compare Table with values for total and soluble P on Gigante Peninsula) (Turner et al ., , ). However, comparison of B in rainfall and leaf litter fall provides support for our assertion that B is unlikely to be of importance in structuring the vegetation in lowland tropical forests.…”

Section: Discussionmentioning

confidence: 99%

No evidence that boron influences tree species distributions in lowland tropical forests of Panama

et al. 2016

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SummaryIt was recently proposed that boron might be the most important nutrient structuring tree species distributions in tropical forests. Here we combine observational and experimental studies to test this hypothesis for lowland tropical forests of Panama.Plant-available boron is uniformly low in tropical forest soils of Panama and is not significantly associated with any of the > 500 species in a regional network of forest dynamics plots. Experimental manipulation of boron supply to seedlings of three tropical tree species revealed no evidence of boron deficiency or toxicity at concentrations likely to occur in tropical forest soils. Foliar boron did not correlate with soil boron along a local scale gradient of boron availability.Fifteen years of boron addition to a tropical forest increased plant-available boron by 70% but did not significantly change tree productivity or boron concentrations in live leaves, wood or leaf litter. The annual input of boron in rainfall accounts for a considerable proportion of the boron in annual litterfall and is similar to the pool of plant-available boron in the soil, and is therefore sufficient to preclude boron deficiency.We conclude that boron does not influence tree species distributions in Panama and presumably elsewhere in the lowland tropics.

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Seasonal changes in soil organic matter after a decade of nutrient addition in a lowland tropical forest

Cited by 62 publications

References 66 publications

Effects of Hurricane-Felled Tree Trunks on Soil Carbon, Nitrogen, Microbial Biomass, and Root Length in a Wet Tropical Forest

Effects of Hurricane-Felled Tree Trunks on Soil Carbon, Nitrogen, Microbial Biomass, and Root Length in a Wet Tropical Forest

Changes in soil carbon and nutrients following 6 years of litter removal and addition in a tropical semi-evergreen rain forest

No evidence that boron influences tree species distributions in lowland tropical forests of Panama

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