中国陆地生态系统的碳储量及其空间格局(英文)

地球系统的碳库变化和碳循环过程机制是气候变化成因分析、变化趋势预测、减缓和适应对策的科学基础,受到科技界和国际社会的广泛关注。从20世纪80年代中后期开始,中国学者就开展了陆地生态系统碳循环研究工作,并且在许多研究领域都取得了可喜的进展。本文在回顾中国的陆地生态系统碳循环研究发展历程基础上,重点评述陆地生态系统的碳储量及其空间格局方面的研究成果,评价有关研究的不确定性以及亟待解决的重要科学问题。分析表明,中国的陆地生态系统碳循环研究经过了陆地生态系统碳循环的前期研究、区域尺度生态系统碳循环综合研究、生态系统碳循环过程对环境变化适应性实验研究,以及生态系统碳-氮-水耦合循环及其区域调控管理研究4个主要发展阶段。大多的研究表明,中国陆地生态系统碳储量及其空间格局是温度和降水控制的。全国土壤、森林和草地植被储存约为97.95 —118.93 Pg C;自20世纪70年代中期以来,我国的植树造林和林业管理、草地保护、农作制度改革和保护性耕作等措施发挥了重要的固碳功能,但是各种方法评估的结果仍然存在较大不确定性。今后的研究重点工作是建立天地空一体化碳储量和碳汇动态监测体系、开展生态系统碳-氮-水耦合循环及其区域调控管理的前瞻性研究,定量评价中国区域生态系统的碳收支状况和增汇潜力,评估各种典型生态系统增汇技术的经济效益,为国家尺度的温室气体管理和碳交易机制与政策体系的建立提供可报告、可度量和可核查的科学数据和技术支持。     

过去陆地生态系统碳储量估算研究

准确估算陆地生态系统碳储量并认识其空间分布和时间演变规律是碳循环研究的关键 问题。本文回顾了全球与中国陆地生态系统在碳储量估算研究方面的若干进展, 包括基于各种方 法和资料的主要估算结果及其尚存在的不确定性。重点评述了末次盛冰期和中全新世两个时期 陆地生态系统碳储量的变化及其影响因素, 对8.2kaB.P.以来全球大气CO₂ 浓度呈现升高的现象 及其可能原因进行了讨论。全新世中晚期全球大气CO₂ 浓度逐渐升高与旧大陆地区陆地生态系 统碳储量减少的事实是一致的, 新石器时期特别是农业文明开始以后人类活动对陆地植被的持 续干预可能是造成陆地生态系统碳储量减少的原因之一。     

1980s-2010s中国陆地生态系统土壤碳储量的变化（英文）

Soil stores a large amount of the terrestrial ecosystem carbon(C) and plays an important role in maintaining global C balance. However, very few studies have addressed the regional patterns of soil organic carbon(SOC) storage and the main factors influencing its changes in Chinese terrestrial ecosystems, especially using field measured data. In this study, we collected information on SOC storage in main types of ecosystems(including forest, grassland, cropland, and wetland) across 18 regions in China during the 1980 s(from the Second National Soil Survey of China, SNSSC) and the 2010 s(from studies published between 2004 and 2014), and evaluated its changing trends during these 30 years. The SOC storage(0–100 cm) in Chinese terrestrial ecosystems was 83.46 ± 11.89 Pg C in the 1980 s and 86.50 ± 8.71 Pg C in the 2010 s, and the net increase over the 30 years was 3.04 ± 1.65 Pg C, with an overall rate of 0.101 ± 0.055 Pg C yr~(–1). This increase was mainly observed in the topsoil(0–20 cm). Forests, grasslands, and croplands SOC storage increased 2.52 ± 0.77, 0.40 ± 0.78, and 0.07 ± 0.31 Pg C, respectively, which can be attributed to the several ecological restoration projects and agricultural practices implemented. On the other hand, SOC storage in wetlands declined 0.76 ± 0.29 Pg C, most likely because of the decrease of wetland area and SOC density. Combining these results with those of vegetation C sink(0.100 Pg C yr~(–1)), the net C sink in Chinese terrestrial ecosystems was about 0.201 ± 0.061 Pg C yr~(–1), which can offset 14.85%–27.79% of the fossil fuel C emissions from the 1980 s to the 2010 s. These first estimates of soil C sink based on field measured data supported the premise that China's terrestrial ecosystems have a large C sequestration potential, and further emphasized the importance of forest protection and reforestation to increase SOC storage capacity.     

1980s-2010s内蒙古草地表层土壤有机碳储量及其变化

以我国内蒙古草原为研究区域,结合1982-1988年第二次土壤普查资料以及2011-2012年实地考察数据,构建了基于遥感数据和土壤数据的区域表层土壤有机碳储量估算方法,对研究区1980s和2010s表层土壤有机碳储量、空间分布特征及其变化进行研究,结果表明：(1) 1980s、2010s内蒙古草地表层土壤 (0~20 cm) 有机碳储量分别为2.05 Pg C、2.17 Pg C,土壤有机碳密度约为3.48 kg C·m^-2、3.69 kg C·m^-2,其空间分布上呈现从草甸草原、典型草原、荒漠草原逐渐降低的特征;(2) 1982-2012年间,内蒙古草地表层土壤有机碳储量略有增加,但增加幅度较小,其中草甸草原和典型草原表层土壤有机碳储量增加,荒漠草原则表现为减少。研究结果将为研究区因地制宜地采取固碳措施,实现草地可持续管理提供科学参考。     

2000-2025年环境保护政策情景下中国陆地碳储量估算

政策总是通过对土地利用/土地覆被的强烈影响而影响陆地碳平衡。本研究旨在探讨环境保护政策（主要是退耕还林）政策对我国陆地碳平衡的影响,从而为政府部门等相关政策制定者提供环境保护和应对气候变化的决策支持。利用DLS（Dynamics Land System）模型对2000-2025年环境保护政策情景下的土地利用变化模拟结果和前人对碳密度的研究成果,运用碳密度法估算了该政策情景对中国陆地碳储量的影响。研究结果表明,在整个阶段,林地将增加23%,耕地和草地将分别减少37%和11%,由此会引起我国森林碳储量每年增加66.0 Tg C,土壤碳储量每年增加13.3 Tg C,而草地碳储量则每年减少5.7 Tg C。总体而言,在环境保护政策情景下,2000-2025年中国整个陆地生态系统的碳储量将增加1.8 Pg C,年均增加量为0.074 Pg C,而这种变化89.6%的原因源于森林碳储量的增加。     

1980—2020年气候和土地利用变化对甘肃省陆地生态系统碳储量的影响北大核心CSCD

土地利用变化对干旱区陆地生态系统碳储量影响显著,但气候变化对其的影响尚不明晰。本研究基于1980—2020年土地利用数据以及植被和土壤碳密度动态数据,利用InVEST模型测算1980—2020年甘肃省及各市州碳储量及固碳量的变化趋势,并定量评估气候变化和土地利用变化对陆地生态系统碳储量的影响。结果表明:(1)甘肃省气候状态整体趋向于暖湿化,同时土地利用转移强度逐渐剧烈,并由1980—2000年的耕地扩张和草地流失逐步转变为2000—2020年的未利用地治理及城镇扩张。(2)1980—2020年甘肃省生态系统平均碳储量为2651.01 Tg C(1 Tg=10^(12)g),碳密度高值区主要分布在甘南高原和祁连山山地区域,低值区主要分布在河西走廊西北荒漠区及内陆河流域下游地区;而固碳速率则呈现出自东南向西北递减的空间格局,其中固碳量排名前四的市州依次为甘南藏族自治州、陇南市、张掖市和庆阳市。(3)1980—2020年甘肃省生态系统碳储量净增长量为208.79Tg C。1980—2000年,碳储增加量主要来源于气候变化(63.01 Tg C);而2000—2020年,土地利用变化则是甘肃省陆地生态系统碳储量变化的主要驱动因素,尤其体现在林-草-沙治理和人工绿洲扩张方面。     

中国陆地土壤有机碳库的估算

土壤是陆地生态系统的核心之一,土壤有机碳库是陆地碳库的主要组成部分,在陆地碳循环研究中有着重要的作用,因而了解土壤碳循环是研究中国陆地生态系统碳循环的基础,确定土壤有机碳的储量、空间分布、对土壤碳循环的研究具有重要意义。根据中国和线次土壤普查得到的土壤各类型分布面积,采样数据、土壤有机质含量,运用ＧＩＳ技术,来估算土壤碳库。经过计算,中国陆地生态系统土壤有机碳总量为１００１．８×１０＾８ｔ,平均碳     

气候变化情景下中国陆地生态系统碳吸收功能风险评价

气候变化会对陆地生态系统的碳吸收产生影响,从而改变其碳的源汇功能.因此,评估未来气候变化下陆地生态系统碳吸收功能面临的风险,可以为中国应对气候变化措施的制定和国际碳排放谈判提供科学依据.本文采用大气-植被相互作用模型对气候变化情景下净生态系统生产力进行模拟,运用线性倾向估计方法确定碳吸收功能风险评估标准,对中国陆地生态...     

1980-2010年安徽省土壤有机碳密度及储量时空变化分析

利用安徽省第二次土壤普查资料和2010-2011年土壤调查数据,运用GIS技术,研究1980-2010年安徽省表层（0~20 cm）和1 m土体中土壤有机碳（SOC）密度和储量的时空变化,并探讨土地利用变化对SOC储量变化的影响。研究表明：① 1980-2010年安徽省表层和1 m土体中SOC密度平均减少0.37 kg/m²和1.63 kg/m²,但耕地的SOC密度增加。② 1980-2010年,全省SOC密度空间变化呈现北增南减的趋势,且增加幅度由北向南依次减小。表层和1 m土体的SOC密度增加的面积为56.97%和58.21%。③ 1980-2010年,全省表层SOC储量减少34.23×10⁹ kg,1 m土体中SOC储量减少197.26×10⁹ kg。淮北平原、江淮丘陵岗地和沿江平原的SOC储量增加,皖西大别山区和皖南丘陵山区减少。④ 非耕地转换为耕地,比保持用地类型不变或变为其他非耕地类型,SOC密度和储量减少较慢。耕地类型内部转换（水田和旱地间转换）比保持类型不变的SOC密度和储量增加较多。研究成果为区域土壤固碳潜力、土壤肥力变化等研究提供科学依据。     

中国区域土地利用/覆被变化对陆地碳收支的影响

准确估计土地利用/覆被变化（LUCC）对陆地生态系统碳收支的影响已成为当前全球变化和全球碳循环研究的重点内容。本文通过文献调研和数据的整合分析方法总结讨论了近年来中国区域LUCC时空特征及其对陆地碳收支影响,为合理评价中国区域陆地碳平衡以及确定未来研究发展方向提供参考。已有大量研究对近年来中国区域LUCC主要特征进行了探讨,并分别利用卫星遥感方法和IPCC清单法对中国区域陆地碳源汇影响进行了评估。结果表明,目前全国土地利用活动,特别是农林活动正对陆地生态系统碳收支产生了比较显著的积极作用,但基于以上两种方法的研究结论之间差异很大,反映出中国LUCC导致陆地碳收支变化的评估结果仍存在着较大的不确定性。通过分析认为,中国未来的研究工作应着重于发展和利用基于土地利用相互转化面积的计量方法,以提高对中国区域LUCC导致陆地碳收支变化评估的准确性。     

Increased soil organic carbon storage in Chinese terrestrial ecosystems from the 1980s to the 2010s

Journal of Geographical Sciences - Soil stores a large amount of the terrestrial ecosystem carbon (C) and plays an important role in maintaining global C balance. However, very few studies have...     

Detecting the storage and change on topsoil organic carbon in grasslands of Inner Mongolia from 1980s to 2010s

Soil carbon sequestration and potential has been a focal issue in global carbon research. Under the background of global change, the estimation of the size as well as its change of soil organic carbon（SOC） storage is of great importance. Based on soil data from the second national soil survey and field survey during 2011–2012, by using the regression method between sampling soil data and remote sensing data, this paper aimed to investigate spatial distribution and changes of topsoil（0–20 cm） organic carbon storage in grasslands of Inner Mongolia between the 1980 s and 2010 s. The results showed that：（1） the SOC storage in grasslands of Inner Mongolia between the 1980 s and 2010 s was estimated to be 2.05 and 2.17 Pg C, with an average density of 3.48 and 3.69 kg C·m–2, respectively. The SOC storage was mainly distributed in the typical steppe and meadow steppe, which accounted for over 98% of the total SOC storage. The spatial distribution showed a decreased trend from the meadow steppe, typical steppe to the desert steppe, corresponding to the temperature and precipitation gradient.（2） SOC changes during 1982–2012 were estimated to be 0.12 Pg C, at 7.00 g C·m–2·yr–1, which didn＇t show a significant change, indicating that SOC storage in grasslands of Inner Mongolia remained relatively stable over this period. However, topsoil organic carbon showed different trends of carbon source/sink during the past three decades. Meadow steppe and typical steppe had sequestered 0.15 and 0.03 Pg C, respectively, served as a carbon sink; while desert steppe lost 0.06 Pg C, served as a carbon source. It appears that SOC storage in grassland ecosystem may respond differently to climate change, related to vegetation type, regional climate type and grazing intensity. These results might give advice to decision makers on adopting suitable countermeasures for sustainable grassland utilization and protection.     

Estimation of soil organic carbon reservoir in China

The paper respectively adopted physio-chemical properties of every soil stratum from 2473 soil profiles of the second national soil survey. The corresponding carbon content of soils is estimated by utilizing conversion coefficient 0.58. In the second soil survey, the total amount of soil organic carbon is about 924.18×108t and carbon density is about 10.53 kgC/m2 in China according to the area of 877.63×106 hm2 surveyed throughout the country. The spatial distribution characteristics of soil organic carbon in China is that the carbon storage increases when latitude increases in eastern China and the carbon storage decreases when longitude reduces in northern China. A transitional zone with great variation in carbon storage exists. Moreover, there is an increasing tendency of carbon density with decrease of latitude in western China. Soil circle is of great significance to global change, but with substantial difference in soil spatial distribution throughout the country. Because the structure of soil is inhomogeneous, it could bring some mistakes in estimating soil carbon reservoirs. It is necessary to farther resolve soil respiration and organic matter conversion and other questions by developing uniform and normal methods of measurement and sampling.     

Estimation of soil organic carbon reservoir in China

1 IntroductionResearch on global change has aroused many scientists' attention to the balance, storage and spatial distribution of carbon in the terrestrial ecosystem. The carbon stored in soil is 2.5-3 times as much as that stored in plants[1,2], so the distribution and conversion of carbon in humus has become one of the global research foci on organic carbon at present[3]. Organic carbon and nitrogen contents in soils are not only important components of soils but also the most important eco…     

近40年甘肃省耕层土壤有机碳时空分异及影响因素

区域耕层土壤有机碳(Soil Organic Carbon,SOC)调查是明确全球土壤碳储量和认识土壤碳循环的重要任务。利用甘肃省1980s、2000s、2020s等3个时期的耕层土壤调查数据,通过计算耕层土壤有机碳密度(Soil Organic Carbon Density,SOCD),估算了甘肃省耕层有机碳储量。结果显示:(1)1980s、2000s、2020s甘肃省耕层SOC储量分别为97.68、109.14、123.13 Tg,近40年固碳总量约为25.45 Tg,固碳速率为0.012±0.01 kg·m^-2·a^-1,说明当前的农田管理措施有利于研究区耕地土壤长期固碳;40年间河西绿洲灌区、黄土高原区和陇南山地区耕层SOC储量呈增加趋势,甘南高原呈下降趋势。(2)从不同土壤类型来看,黄棕壤固碳速率最大,栗钙土最小。(3)近40年间甘肃省耕层SOC储量总体呈递增趋势,化肥、有机肥施用量以及秸秆还田量的持续增加,提高了作物归还量,进而增加了耕层有机物质含量,最终促进了耕层SOC的累积。     

Three-dimensional modelling of soil organic carbon density and carbon sequestration potential estimation in a dryland farming region of China

Soil organic carbon density(SOCD) and soil organic carbon sequestration potential(SOCP) play an important role in carbon cycle and mitigation of greenhouse gas emissions. However, the majority of studies focused on a two-dimensional scale, especially lacking of field measured data. We employed the interpolation method with gradient plane nodal function(GPNF) and Shepard(SPD) across a range of parameters to simulate SOCD with a 40 cm soil layer depth in a dryland farming region(DFR) of China. The SOCP was estimated using a carbon saturation model. Results demonstrated the GPNF method was proved to be more effective in simulating the spatial distribution of SOCD at the vertical magnification multiple and search point values of 3.0×10~6 and 25, respectively. The soil organic carbon storage(SOCS) of 40 cm and 20 cm soil layers were estimated as 22.28×10~(11) kg and 13.12×10~(11) kg simulated by GPNF method in DFR. The SOCP was estimated as 0.95×10~(11) kg considered as a carbon sink at the 20–40 cm soil layer. Furthermore, the SOCP was estimated as –2.49×10~(11) kg considered as a carbon source at the 0–20 cm soil layer. This research has important values for the scientific use of soil resources and the mitigation of greenhouse gas emissions.