Key Laboratory of Geographical Processes and Ecological Security of Changbai Mountains, Ministry of Education, School of Geographical Sciences, Northeast Normal University, Changchun 130024, China; State Environmental Protection Key Laboratory of Wetland Ecology and Vegetation Restoration, Northeast Normal University, Changchun 130024, China; Jilin Provincial Key Laboratory for Wetland Ecological Processes and Environmental Change in the Changbai Mountains, Institute for Peat and Mire Research, Northeast Normal University, Changchun 130024, China.
Key Laboratory of Geographical Processes and Ecological Security of Changbai Mountains, Ministry of Education, School of Geographical Sciences, Northeast Normal University, Changchun 130024, China.
Sci Total Environ. 2024 Apr 1;919:170688. doi: 10.1016/j.scitotenv.2024.170688. Epub 2024 Feb 4.
Drought induced by climate warming and human activities regulates carbon (C) cycling of peatlands by changing plant community composition and soil properties. Estimating the responses of peatlands C cycling to environmental changes requires further study of C: nitrogen (N): phosphorus (P) stoichiometric ratios of soil, plants, and enzyme activities. However, systematic studies on the stoichiometry of above-ground and below-ground ecosystems of peatlands post drainage remain scarce. This study compared stoichimetric ratios of plant and soil and stoichimetric ratios of enzyme activities with different functions in two different parts of a minerotrophic peatland, a natural undisturbed part and a part that had been drained for almost 50 years, in Northern China. For the shrub plants, the average C:N:P ratios of leaf in natural and drained peatland were 448:17:1 and 393:15:1, respectively. This indicated that the growth rate of shrub plants is higher in the drained peatland than in the natural peatland, which makes P element more concentrated in the photosynthetic site. However, from the perspective of the dominant plant, the mean C:N:P ratio of Carex leaf was 650:25:1 in the natural peatland, but was 1028:50:1 for Dasiphora fruticosa in drained peatland. This indicated that the intensification of P-limitation of plant growth after drainage. Soil C:N:P ratios of above water table depth (AWT) were 238:15:1 and 277:12:1, but were 383:17:1 and 404:19:1 for below water table depth (BWT) in the natural and the drained peatland, respectively. Soil C:P ratios were greater than the threshold elemental ratio of C:P (174:1), but the soil C:N ratios were less than the threshold elemental ratio of C:N (23:1), which suggested that P was the most limiting nutrient of soil. The soil microbial activities were co-limited by C&P in Baijianghe peatlands. However, the microbial metabolic P limitation was intensified, but the C limitation was weakened for the above water table depth soil after long-term drainage. There are connection between plant-microbe P limitation in peatlands. The P limitation of microbial metabolism was significant positively correlated with soil C:N but negatively with soil moisture. The increase in the lignocelluloses index suggested considerable decomposition of soil organic matter after peatland drainage. These results of stoichiometric ratios from above- to below ground could provide scientific base for the C cycling of peatland undergone climate change.
气候变暖与人类活动引起的干旱通过改变植物群落组成和土壤性质来调节泥炭地的碳(C)循环。要估计泥炭地 C 循环对环境变化的响应,需要进一步研究土壤、植物和酶活性的 C:氮(N):磷(P)化学计量比。然而,对排水后泥炭地地上和地下生态系统的化学计量比的系统研究仍然很少。本研究比较了中国北方一个富营养泥炭地的自然未干扰部分和已排水近 50 年的部分中不同功能的地上和地下生态系统的植物和土壤的化学计量比以及酶活性的化学计量比。对于灌木植物,天然和排水泥炭地叶片的平均 C:N:P 比分别为 448:17:1 和 393:15:1。这表明,排水泥炭地中灌木植物的生长速度高于天然泥炭地,这使得 P 元素在光合部位更加集中。然而,从优势植物的角度来看,天然泥炭地苔草叶片的平均 C:N:P 比为 650:25:1,而排水泥炭地的山莓叶片的平均 C:N:P 比为 1028:50:1。这表明排水后植物生长的磷限制加剧。表水深度(AWT)以上土壤的 C:N:P 比分别为 238:15:1 和 277:12:1,但天然和排水泥炭地的表水深度以下土壤的 C:N:P 比分别为 383:17:1 和 404:19:1。土壤 C:P 比大于 C:P 的元素阈值比(174:1),但土壤 C:N 比小于 C:N 的元素阈值比(23:1),这表明 P 是土壤最限制的养分。在白江河泥炭地,土壤微生物活性受到 C 和 P 的共同限制。然而,长期排水后,表水深度土壤的微生物代谢 P 限制加剧,而 C 限制减弱。泥炭地植物-微生物 P 限制之间存在联系。微生物代谢的 P 限制与土壤 C:N 呈显著正相关,与土壤水分呈负相关。木质纤维素指数的增加表明泥炭地排水后土壤有机物质的大量分解。这些地上到地下的化学计量比的结果可为经历气候变化的泥炭地的 C 循环提供科学依据。
