Response of Afromontane soil organic carbon, nitrogen, and phosphorus to in situ experimental warming along an elevational gradient

IF 2.1 Q3 SOIL SCIENCE
J. Okello, M. Bauters, H. Verbeeck, J. Kasenene, P. Boeckx
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引用次数: 1

Abstract

Tropical montane forests store large amounts of carbon (C), nitrogen (N), and phosphorus (P) in soil. These soil C, N, and P pools are vulnerable to increased losses due to the increasing local temperatures. To gain better insight into the effects of climate warming on biogeochemistry in montane forests in Africa, we established study plots along a natural climate gradient in Uganda between 1,250 and 3,000 m in the Rwenzori Mountains. We studied soil C, N, and P contents as well as 13C and 15N isotopic compositions and leaf nutrient contents. Further, we simulated climate warming by 0.9°C–2.8°C for 2 years by conducting in situ soil mesocosms translocation downslope. The results revealed that, along the elevational gradient, soil organic C increased six-fold from 2.6 ± 1.0% at 1,250–1,300 m to 16.0 ± 1.9% at 2,700–3,000 m, with a linear increase of 0.94% per 100 m of elevation increase. Similarly, soil total N increased five-fold, from 0.3 ± 0.1% to 1.3 ± 0.1%, with a linear increase of 0.07% per 100 m of elevation increase. Further, soil bio-available P increased three-fold, from 9.6 ± 5.2 mg kg−1 to 29.5 ± 3.0 mg kg−1, with a linear increase of 1.4 mg kg−1 per 100 m of elevation increase. Soil δ15N decreased linearly by 0.39‰ per 100 m of elevation increase, ranging from 8.9 ± 0.2‰ to 2.9 ± 0.7‰ at 1,250–1,300 m and 2,700–3,000 m, respectively. The accumulation of soil organic C and total N with elevation is due to slow microbial activity under lower temperature. Indeed, the soil δ15N indicated a more closed N cycling with increasing elevation. However, despite the increasing trend in soil C and nutrient status with elevation, leaf N and P contents decreased linearly with elevation. This is likely due to the impairment of nutrient uptake under low temperature and low pH. In addition, following 2 years of in situ soil warming, we found that the soil δ13C and δ15N values relatively increased. Generally, the results imply that warming triggered accelerated transformation processes of accrued soil organic matter.
非洲山地土壤有机碳、氮、磷对海拔梯度原位实验升温的响应
热带山地森林在土壤中储存了大量的碳(C)、氮(N)和磷(P)。这些土壤碳、氮和磷库容易因当地气温升高而损失增加。为了更好地了解气候变暖对非洲山地森林生物地球化学的影响,我们在乌干达鲁文佐里山脉沿1250到3000米之间的自然气候梯度建立了研究区。研究了土壤C、N、P含量、13C、15N同位素组成和叶片养分含量。此外,通过原位土壤生态系统下坡迁移,模拟了2年升温0.9°C - 2.8°C的气候变化。结果表明,沿海拔梯度,土壤有机碳从1250 ~ 1300 m的2.6±1.0%增加到2700 ~ 3000 m的16.0±1.9%,每100 m海拔增加0.94%,呈线性增加;土壤全氮增加了5倍,从0.3±0.1%增加到1.3±0.1%,每100 m海拔增加0.07%。此外,土壤生物有效磷增加了3倍,从9.6±5.2 mg kg - 1增加到29.5±3.0 mg kg - 1,每100 m海拔增加1.4 mg kg - 1。土壤δ15N在海拔1250 ~ 1300 m和2700 ~ 3000 m分别为8.9±0.2‰~ 2.9±0.7‰,每100 m线性下降0.39‰。土壤有机碳和全氮随海拔升高的积累是由于低温下微生物活动缓慢所致。随着海拔的升高,土壤δ15N的循环更为封闭。然而,尽管土壤C和养分状况随海拔升高而增加,但叶片N和P含量随海拔升高而线性下降。这可能是由于低温和低ph条件下养分吸收受损所致。此外,经过2年的原位土壤增温,我们发现土壤δ13C和δ15N值相对增加。总体而言,气候变暖加速了累积土壤有机质的转化过程。
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CiteScore
1.90
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