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1.
土壤固碳功能和固碳潜力已成为全球气候变化和陆地生态系统研究的重点。草地土壤有机碳库,作为陆地土壤有机碳库的重要组成部分,其较小幅度的波动,将会影响整个陆地生态系统碳循环,进而影响全球气候变化。因此,深入研究草地土壤固碳功能和固碳潜力对于适应和减缓气候变化具有重要意义。在土壤固碳潜力相关概念界定基础上,结合《2006年IPCC国家温室气体清单指南》,从样点及区域尺度上综述了目前关于草地土壤固碳潜力的一般估算方法,同时对各类方法的特点及适用性进行了评述,提出了草地生态系统固碳潜力研究概念模型。最后在对草地土壤固碳的影响因素及固碳措施总结的基础上,阐明了草地土壤有机碳固定研究中存在的问题和发展前景。 相似文献
2.
桑思月;杨沂杰;赵京东;乌云娜;吕林有;宋彦涛 《生态学杂志》2025,44(3):884-891
以辽西北农牧交错带退化草地为研究对象;研究土壤有机碳含量、储量以及土壤固碳能力随围封年限的变化特征。结果表明: 围封6年后0~20 cm土层土壤有机碳储量增加了18.6%。随围封年限的增加;土壤有机碳含量、储量均呈现下降-上升-下降-上升的“W”型的变化趋势;围封3年、6年时;土壤固碳潜力较高。相关性分析结果表明;0~10 cm土壤有机碳储量与土壤pH呈显著负相关(P<0.05);与凋落物量、地上生物量呈显著正相关(P<0.05);10~20 cm土壤有机碳储量与凋落物量呈显著正相关、与植物优势度指数呈显著负相关(P<0.05)。短期围封(6年)通过增加地上生物量促进土壤有机碳的积累;同时通过降低土壤pH减缓有机碳分解;从而增加土壤有机碳含量和固碳潜力。本研究为辽西北退化草地的生态恢复提供了技术支撑。 相似文献
3.
以国内长期定位试验的数据为基础,评价了我国草地生态系统的固碳现状和潜力.分析发现,通过减少畜牧承载量等方法恢复退化草地,我国草地土壤的有机碳库可以增加4561.62 Tg C ,主要分布在内蒙古、西藏和新疆.草场围栏、种草和退耕还草3种草地管理措施的固碳潜力分别是12.01、1.46 Tg·a-1和25.59 Tg·a-1,总计39.06 Tg·a-1.2004年是我国草地管理投资较多的年份,种草、退耕还草和草场围栏的工程面积均有较大的提高,3种措施新增的固碳能力分别为5.70、0.38 Tg·a-1和3.09 Tg·a-1,合计9.17 Tg·a-1. 相似文献
4.
放牧是影响草地土壤碳固存的重要因素。本研究选取黄土高原水蚀风蚀交错区西部、中部、东部地区及水蚀区,以各区20年以上退耕封禁地为对照,分析3个放牧强度下(羊粪球密度分别为0~10、10~20、>20 ind·m-2)退耕草地0~20 cm土层土壤有机碳储量的分布特征,研究放牧及其强度对退耕草地土壤固碳效应的影响。结果表明: 放牧对交错区西部0~20 cm、东部0~10 cm,水蚀区0~5 cm土层土壤有机碳储量有显著影响,对交错区中部各土层均无显著影响;羊粪球密度0~10、>20 ind·m-2强度的放牧使交错区西部0~20 cm土层土壤有机碳储量显著降低了34.8%~50.9%,而在其他3个区域,放牧对有机碳储量的影响较退耕封禁地差异不显著。在交错区东部,放牧强度是影响退耕草地土壤有机碳储量的主要因素,而其他3个区域有机碳储量主要受土壤理化性质和(或)枯落物生物量的影响。羊粪球密度10~20 ind·m-2强度的放牧对各区域退耕草地0~20 cm土层土壤有机碳储量无显著影响。 相似文献
5.
This study aimed to investigate the impact of long-term grassland management on the temporal dynamic of SOC density in two temperate grasslands. The top soil SOC density, soil total nitrogen density and soil bulk density (0–20 cm) under long-term fencing and grazing treatments, the aboveground net primary productivity of fenced plots and the associated climatic factors of Leymus chinensis and Stipa grandis grasslands in Inner Mongolia were collected from literatures and analyzed. The results showed that the SOC density increased linearly with fenced duration but was insensitive to grazed duration in both grasslands. Compared with long-term grazing, fenced plots had larger potential for carbon sequestration, and the accumulation rate of SOC density was 29 and 35 g Cm–2y–1 for L. chinensis and S. grandis grasslands. Fenced duration and mean annual temperature jointly contributed large effect on temporal pattern of SOC density. Climate change and grazed duration had little influence on the inter-annual variance of SOC density in grazed plots. Our results confirmed the enhancement effect of long-term fencing on soil carbon sequestration in degraded temperate grassland, and long-term permanent plot observation is essential and effective for accurately and comprehensively understanding the temporal dynamic of SOC storage. 相似文献
6.
WILLIAM H. SCHLESINGER 《Global Change Biology》2010,16(2):849-850
Applications of fertilizer, often thought to enhance carbon sequestration in agricultural soils, are of no value to the mitigation of climate change if the carbon dioxide released during the production and distribution of nitrogen fertilizer exceeds the incremental carbon storage in soils from its use. Nitrogen fertilizer is also a source of the greenhouse gas nitrous oxide. The recent analysis of carbon sequestration in cropland soils of China does not apply these ‘discounts’ to the global warming mitigation expected from greater use of fertilizer; doing so would likely eliminate all the climate benefits of the postulated enhanced carbon sequestration. 相似文献
7.
土壤有机碳的贮存和损失的研究是目前国际上前沿研究领域之一。研究农田土壤有机碳固定过程 ,对于了解农业生产过程和生态过程的关系具有十分重要的意义。在农田土壤中 ,发生变化的有机碳主要是年轻或轻组有机碳 ,而且土壤有机碳的损失或固定都是在土壤表层和有限的时间内发生 ,且数量巨大。传统的耕作体系是造成土壤有机碳损失的主要原因。为了增加农田土壤有机碳的保有量 ,农业管理措施应该从增加有机碳的输入量 (如草田轮作、保留残茬以及施用肥料等 )和减少土壤有机碳的矿化 (少、免耕等 )两方面入手 相似文献
8.
Carbon emission and sequestration by agricultural land use: a model study for Europe 总被引:13,自引:0,他引:13
A model was developed to calculate carbon fluxes from agricultural soils. The model includes the effects of crop (species, yield and rotation), climate (temperature, rainfall and evapotranspiration) and soil (carbon content and water retention capacity) on the carbon budget of agricultural land. The changes in quality of crop residues and organic material as a result of changes in CO2 concentration and changed management were not considered in this model. The model was parameterized for several arable crops and grassland. Data from agricultural, meteorological, soil, and land use databases were input to the model, and the model was used to evaluate the effects of different carbon dioxide mitigation measures on soil organic carbon in agricultural areas in Europe. Average carbon fluxes under the business as usual scenario in the 2008–2012 commitment period were estimated at 0.52 tC ha?1 y?1 in grassland and ?0.84 tC ha?1 y?1 in arable land. Conversion of arable land to grassland yielded a flux of 1.44 tC ha?1 y?1. Farm management related activities aiming at carbon sequestration ranged from 0.15 tC ha?1 y?1 for the incorporating of straw to 1.50 tC ha?1 y?1 for the application of farmyard manure. Reduced tillage yields a positive flux of 0.25 tC ha?1 y?1. The indirect effect associated with climate was an order of magnitude lower. A temperature rise of 1 °C resulted in a ?0.05 tC ha?1 y?1 change whereas the rising CO2 concentrations gave a 0.01 tC ha?1 y?1 change. Estimates are rendered on a 0.5 × 0.5° grid for the commitment period 2008–2012. The study reveals considerable regional differences in the effectiveness of carbon dioxide abatement measures, resulting from the interaction between crop, soil and climate. Besides, there are substantial differences between the spatial patterns of carbon fluxes that result from different measures. 相似文献
9.
在田间定位试验区 ,研究了不同施肥处理对表层红壤性水稻土微团聚体组成以及土壤有机碳在各级微团聚体中分布和赋存的影响。结果表明 ,红壤性水稻土中 0 .0 2~ 0 .0 5 mm微团聚体所占比例最大 ,达 4 0 % ;其次是 0 .0 0 2~ 0 .0 2 mm和 0 .0 5~0 .1mm的微团聚体 ;>0 .2 mm微团聚体占的比例最小。长期施用无机肥 (NPK)、有机肥 (猪粪 紫云英绿肥 ) (OM)、无机肥与有机肥配施 (NPKM) ,能显著增加 0 .0 0 2~ 0 .0 2 mm微团聚体的含量而降低 <0 .0 0 2 m m微团聚体的含量。土壤有机碳含量与0 .0 0 2~ 0 .0 2 mm微团聚体含量之间呈显著正相关关系 ;而与 <0 .0 0 2 mm微团聚体含量呈显著负相关关系。各级微团聚体有机碳含量从高到低顺序为 :>0 .2 mm,0 .1~ 0 .2 mm,<0 .0 0 2 m m,0 .0 5~ 0 .1m m,0 .0 0 2~ 0 .0 2 mm,0 .0 2~ 0 .0 5 m m。 OM、NPKM处理能显著增加 >0 .0 0 2 mm各级微团聚体有机碳的赋存量 ,新增加的有机碳主要向微团聚体 0 .1~ 0 .0 5 m m,0 .0 5~ 0 .0 2 mm和 0 .0 2~ 0 .0 0 2 mm富集 ,它们是土壤有机碳的主要载体。 3种施肥处理对提高土壤有机碳赋存效果高低顺序为 :NPKM>OM>NPK。 相似文献
10.
土地利用变化和耕作管理是人类影响陆地生态系统碳过程一个重要方面.对河西走廊中段张掖绿洲退化土地退耕种植苜蓿5a后土壤性状的分析表明, 49个退耕苜蓿地土壤与相邻未退耕农田土壤配对样本的比较,退耕苜蓿地0~15cm土层土壤粒级组成和容重并未发生显著变化,但土壤pH平均提高了0.11个单位,电导率降低34.8%,土壤有机碳(SOC)和全氮(全N)含量较对照农田土壤平均提高18.5%和9.3%,活性有机碳(labile C)增加53.3%.SOC含量受海拔高度和土壤粒粉粒含量的影响,退耕后SOC和全N的增加幅度沙壤土高于粉壤土,而labile C的增加幅度沙壤土低于粉壤土.退耕苜蓿地0~15cm土层SOC和全N储量较农田土壤分别增加2.84Mg hm~(-2)和0.21Mg hm~(-2),土壤C、N的固存率平均为0.57Mg hm~(-2)a~(-1)和0.04 Mg hm~(-2)a~(-1),表明退化土地由1年生作物向多年生牧草的转变有显著的固碳效应和潜力.活性有机碳的变化较总有机碳的变化更为显著,表明活性有机碳对土地利用变化的响应更为敏感. 相似文献
11.
盐沼湿地具有很高的碳捕获与存储能力, 是缓解全球变暖的有效蓝色碳汇(蓝碳)。未来气候变暖和海平面上升可能增加盐沼湿地的固碳能力, 其蓝碳功能越来越受到国际社会的重视。该文重点围绕盐沼湿地蓝碳形成的关键过程、光合碳分配过程及影响机制、碳沉积埋藏特征及其来源解析、盐沼湿地土壤碳库稳定性及其微生物机制、盐沼湿地蓝碳过程动态模拟及其增汇潜力等5个方面进行综述。在此基础上, 针对当前研究的不足, 提出今后的研究中需要进一步探究盐沼湿地植被海陆梯度分布格局对碳吸收能力和碳分配的影响, 土壤有机碳沉积和埋藏速率及其对全球变化的响应, 盐沼湿地土壤碳库的稳定性及其横向碳流动, 气候变化和海平面上升背景下盐沼湿地蓝碳模拟与增汇潜力评估, 以及盐沼湿地蓝碳的增汇技术和途径。以期为深入理解盐沼湿地蓝碳形成过程与机制, 预测全球变化背景下盐沼湿地蓝碳功能的潜在变化趋势和制定蓝碳增汇途径提供理论支持, 助力碳达峰、碳中和目标实现。 相似文献
12.
基于374个高寒草原和温带草原土壤样品的测试结果,运用多元逐步回归分析模型定量评估了土壤环境因子对土壤有机碳(SOC)含量的影响.结果表明:高寒草原土壤有机碳含量(20.18 kg C/m2)高于温带草原(9.23 kg C/m2).土壤理化生物学因子对高寒草原和温带草原SOC含量(10 cm)变化的贡献分别是87.84%和75.00%.其中,土壤总氮含量和根系对高寒草原SOC含量变化的贡献均大于对温带草原SOC含量变化的相应贡献.土壤水分是温带草原SOC含量变化的主要限制性因素,其对SOC含量变化的贡献达33.27%.高寒草原土壤C/N比显著高于温带草原土壤的相应值,揭示了青藏高原高寒草原较高的SOC含量是由于较低的土壤微生物活性所导致. 相似文献
13.
Alasdair J. Sykes Michael Macleod Vera Eory Robert M. Rees Florian Payen Vasilis Myrgiotis Mathew Williams Saran Sohi Jon Hillier Dominic Moran David A. C. Manning Pietro Goglio Michele Seghetta Adrian Williams Jim Harris Marta Dondini Jack Walton Joanna House Pete Smith 《Global Change Biology》2020,26(3):1085-1108
To limit warming to well below 2°C, most scenario projections rely on greenhouse gas removal technologies (GGRTs); one such GGRT uses soil carbon sequestration (SCS) in agricultural land. In addition to their role in mitigating climate change, SCS practices play a role in delivering agroecosystem resilience, climate change adaptability and food security. Environmental heterogeneity and differences in agricultural practices challenge the practical implementation of SCS, and our analysis addresses the associated knowledge gap. Previous assessments have focused on global potentials, but there is a need among policymakers to operationalise SCS. Here, we assess a range of practices already proposed to deliver SCS, and distil these into a subset of specific measures. We provide a multidisciplinary summary of the barriers and potential incentives towards practical implementation of these measures. First, we identify specific practices with potential for both a positive impact on SCS at farm level and an uptake rate compatible with global impact. These focus on: (a) optimising crop primary productivity (e.g. nutrient optimisation, pH management, irrigation); (b) reducing soil disturbance and managing soil physical properties (e.g. improved rotations, minimum till); (c) minimising deliberate removal of C or lateral transport via erosion processes (e.g. support measures, bare fallow reduction); (d) addition of C produced outside the system (e.g. organic manure amendments, biochar addition); (e) provision of additional C inputs within the cropping system (e.g. agroforestry, cover cropping). We then consider economic and non‐cost barriers and incentives for land managers implementing these measures, along with the potential externalised impacts of implementation. This offers a framework and reference point for holistic assessment of the impacts of SCS. Finally, we summarise and discuss the ability of extant scientific approaches to quantify the technical potential and externalities of SCS measures, and the barriers and incentives to their implementation in global agricultural systems. 相似文献
14.
Marcus Schiedung Craig S. Tregurtha Michael H. Beare Steve M. Thomas Axel Don 《Global Change Biology》2019,25(7):2296-2309
Sequestration of soil organic carbon (SOC) has been recognized as an opportunity to off‐set global carbon dioxide (CO2) emissions. Flipping (full inversion to 1–3 m) is a practice used on New Zealand's South Island West Coast to eliminate water‐logging in highly podzolized sandy soils. Flipping results in burial of SOC formed in surface soil horizons into the subsoil and the transfer of subsoil material low in SOC to the “new” topsoil. The aims of this study were to quantify changes in the storage and stability of SOC over a 20‐year period following flipping of high‐productive pasture grassland. Topsoils (0–30 cm) from sites representing a chronosequence of flipping (3–20 years old) were sampled (2005/07) and re‐sampled (2017) to assess changes in topsoil carbon stocks. Deeper samples (30–150 cm) were also collected (2017) to evaluate the changes in stocks of SOC previously buried by flipping. Density fractionation was used to determine SOC stability in recent and buried topsoils. Total SOC stocks (0–150 cm) increased significantly by 69 ± 15% (179 ± 40 Mg SOC ha‐1) over 20 years following flipping. Topsoil burial caused a one‐time sequestration of 160 ± 14 Mg SOC ha‐1 (30–150 cm). The top 0–30 cm accumulated 3.6 Mg SOC ha‐1 year‐1. The chronosequence and re‐sampling revealed SOC accumulation rates of 1.2–1.8 Mg SOC ha‐1 year‐1 in the new surface soil (0–15 cm) and a SOC deficit of 36 ± 5% after 20 years. Flipped subsoils contained up to 32% labile SOC (compared to <1% in un‐flipped subsoils) thus buried SOC was preserved. This study confirms that burial of SOC and the exposure of SOC depleted subsoil results in an overall increase of SOC stocks of the whole soil profile and long‐term SOC preservation. 相似文献
15.
16.
两个基因型水稻利用有机磷的差异及其与根系分泌酸性磷酸酶活性的关系 总被引:3,自引:0,他引:3
以低磷条件下根系分泌酸性磷酸酶活性有显著差异的两个基因型水稻中部51和Azucena为材料,通过琼脂培养试验研究它们在无菌条件下利用植酸钠(IHP)的情况以及接种土壤微生物对水稻利用植酸钠能力的影响.结果表明:以植酸钠为磷源生长的中部51和Azucena的植株地上部干物质量、吸磷量和磷浓度均显著低于以无机磷为磷源生长的植株,植酸钠处理的水稻植株地上部吸磷量和磷浓度也均显著高于无磷处理植株,表明无菌培养条件下水稻能部分利用植酸钠.低磷条件下两个基因型水稻根系分泌酸性磷酸酶活性显著高于正常供磷处理,且低磷条件下中部51根系分泌的酸性磷酸酶活性较高,这可能是无菌条件下中部51利用植酸钠的能力高于Azucena的机理之一.高水平植酸钠处理(0.96 mmol P·L-1)下两个基因型水稻植株地上部干物质量、磷含量及磷浓度均显著高于低水平植酸钠处理(0.16 mmol P·L-1),表明底物有效性可能是影响水稻利用植酸钠能力的限制因素之一.在低水平和高水平植酸钠处理下,接种土壤微生物对两个基因型水稻植株的地上部干物质量、磷含量及磷浓度均没有显著影响,表明在本试验中接种土壤微生物并不能显著提高水稻利用植酸钠的能力. 相似文献
17.
Chuancheng Fu Yuan Li Lin Zeng Haibo Zhang Chen Tu Qian Zhou Kuanxu Xiong Jiaping Wu Carlos M. Duarte Peter Christie Yongming Luo 《Global Change Biology》2021,27(1):202-214
Global vegetated coastal habitats (VCHs) represent a large sink for organic carbon (OC) stored within their soils. The regional patterns and causes of spatial variation, however, remain uncertain. The sparsity and regional bias of studies on soil OC stocks from Chinese VCHs have limited the reliable estimation of their capacity as regional and global OC sinks. Here, we use field and published data from 262 sampled soil cores and 181 surface soils to report estimates of soil OC stocks, burial rates and losses of VCHs in China. We find that Chinese mangrove, salt marsh and seagrass habitats have relatively low OC stocks, storing 6.3 ± 0.6, 7.5 ± 0.6, and 1.6 ± 0.6 Tg C (±95% confidence interval) in the top meter of the soil profile with burial rates of 44 ± 17, 159 ± 57, and 6 ± 45 Gg C/year, respectively. The variability in the soil OC stocks is linked to biogeographic factors but is mostly impacted by sedimentary processes and anthropic activities. All habitats have experienced significant losses, resulting in estimated emissions of 94.2–395.4 Tg CO2e (carbon dioxide equivalent) over the past 70 years. Reversing this trend through conservation and restoration measures has, therefore, great potential in contributing to the mitigation of climate change while providing additional benefits. This assessment, on a national scale from highly sedimentary environments under intensive anthropogenic pressures, provides important insights into blue carbon sink mechanism and sequestration capacities, thus contributing to the synchronous progression of global blue carbon management. 相似文献
18.
基于1979—1985年全国第二次土壤普查和2015年实地采样数据,利用土壤类型法计算了近35年来松嫩平原及其各县农田表层土壤有机碳密度和土壤碳库储量;并分析了松嫩平原农田土壤有机碳密度的空间分布及变化特征;利用饱和值法对松嫩平原及其各县市农田土壤有机碳量的变化趋势进行拟合,估算其农田土壤的固碳潜力。结果表明:(1)2015年松嫩平原农田表层土壤有机碳密度平均值为1.61 kg/m~2,近35年来约有81.59%的农田土壤有机碳密度呈下降趋势,集中分布在松嫩平原北部、东部和东南部地区,以富裕县东部、依安县中部、肇东县西部、扶余县西部等地区土壤有机碳密度下降幅度最大;(2)2015年松嫩平原农田表层土壤有机碳库总储量为233.63 Tg,比全国第二次土壤普查减少了32.62 Tg;(3)2015年松嫩平原农田表层土壤总固碳潜力为-32.7 TgC,呈现出\"碳源\"趋势,农田土壤单位面积固碳潜力平均值为-1.793×10~(-3)Tg/km~2。 相似文献
19.
Raphael A. Viscarra Rossel Richard Webster Elisabeth N. Bui Jeff A. Baldock 《Global Change Biology》2014,20(9):2953-2970
We can effectively monitor soil condition—and develop sound policies to offset the emissions of greenhouse gases—only with accurate data from which to define baselines. Currently, estimates of soil organic C for countries or continents are either unavailable or largely uncertain because they are derived from sparse data, with large gaps over many areas of the Earth. Here, we derive spatially explicit estimates, and their uncertainty, of the distribution and stock of organic C in the soil of Australia. We assembled and harmonized data from several sources to produce the most comprehensive set of data on the current stock of organic C in soil of the continent. Using them, we have produced a fine spatial resolution baseline map of organic C at the continental scale. We describe how we made it by combining the bootstrap, a decision tree with piecewise regression on environmental variables and geostatistical modelling of residuals. Values of stock were predicted at the nodes of a 3‐arc‐sec (approximately 90 m) grid and mapped together with their uncertainties. We then calculated baselines of soil organic C storage over the whole of Australia, its states and territories, and regions that define bioclimatic zones, vegetation classes and land use. The average amount of organic C in Australian topsoil is estimated to be 29.7 t ha?1 with 95% confidence limits of 22.6 and 37.9 t ha?1. The total stock of organic C in the 0–30 cm layer of soil for the continent is 24.97 Gt with 95% confidence limits of 19.04 and 31.83 Gt. This represents approximately 3.5% of the total stock in the upper 30 cm of soil worldwide. Australia occupies 5.2% of the global land area, so the total organic C stock of Australian soil makes an important contribution to the global carbon cycle, and it provides a significant potential for sequestration. As the most reliable approximation of the stock of organic C in Australian soil in 2010, our estimates have important applications. They could support Australia's National Carbon Accounting System, help guide the formulation of policy around carbon offset schemes, improve Australia's carbon balances, serve to direct future sampling for inventory, guide the design of monitoring networks and provide a benchmark against which to assess the impact of changes in land cover, land management and climate on the stock of C in Australia. In this way, these estimates would help us to develop strategies to adapt and mitigate the effects of climate change. 相似文献
20.
DORIEN M. KOOL † HAEGEUN CHUNG KEVIN R. TATE‡ DES J. ROSS‡ PAUL C. D. NEWTON§ JOHAN SIX 《Global Change Biology》2007,13(6):1282-1293
Soil has been identified as a possible carbon (C) sink to mitigate increasing atmospheric CO2 concentration. However, several recent studies have suggested that the potential of soil to sequester C is limited and that soil may become saturated with C under increasing CO2 levels. To test this concept of soil C saturation, we studied a gley and organic soil at a grassland site near a natural CO2 spring. Total and aggregate‐associated soil organic C (SOC) concentration showed a significant increase with atmospheric CO2 concentration. An asymptotic function showed a better fit of SOC and aggregation with CO2 level than a linear model. There was a shift in allocation of total C from smaller size fractions to the largest aggregate fraction with increasing CO2 concentration. Litter inputs appeared to be positively related to CO2 concentration. Based on modeled function parameters and the observed shift in the allocation of the soil C from small to large aggregate‐size classes, we postulate that there is a hierarchy in C saturation across different SOC pools. We conclude that the asymptotic response of SOC concentration at higher CO2 levels indicates saturation of soil C pools, likely because of a limit to physical protection of SOC. 相似文献