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1.
基于森林资源清查的江西省森林贮碳功能研究 总被引:2,自引:0,他引:2
利用江西省1999--2003年森林资源二类清查资料,结合大岗山森林生态站的实测数据以及已公布的调查资料,运用材积源生物量法对江西省森林的碳储量和碳密度进行了估算和评价。结果表明,江西省不同类型森林乔木层碳密度,由大到小依次为硬阔林、针阔混交林、毛竹林、国外松林、杉木林、软阔林、灌木林、马尾松林和经济林,且碳密度随着林龄的增大而增大,随人口密度的增大而减小。森林碳密度土壤层最大,植被层次之,枯落物层最小。不同森林类型乔木层碳储量,由大到小依次为杉木林、硬阔林、马尾松林、毛竹林、灌木林、国外松林、经济林、针阔混交林、软阔林。从森林类型分布看,除杉木和国外松林外,其他森林类型天然林乔木层碳储量远大于人工林;从地理分布看,除南昌、萍乡、新余三市外,其余各市均是天然林乔木层碳储量远大于人工林。不同年龄森林乔木层碳储量,由大到小依次为中龄林、幼龄林、近熟林、成熟林、过熟林。不同森林碳储量由大到小依次为杉木林、马尾松林、硬阔林、灌木林、经济林、毛竹林、针阔混交林、国外松林和软阔林,南部和中西部要高于中东部和北部。江西省森林总碳储量为1.5Gt,占全国森林总碳储量的5.33%。 相似文献
2.
基于陕西省第1次至第7次森林资源清查资料,采用IPCC(政府间气候变化专门委员会)推荐的碳储量计算方法,研究陕西省近30年森林碳储量、碳密度的时空变化特征,结果表明:近30年陕西省森林碳储量显著增加,由1987年1.21×10~8 t增加到2014年2.38×10~8 t,净增1.17×10~8 t;森林碳储量具有明显的地带性分布特点,呈现出陕南秦巴山地高,陕北高原和关中平原低的特征;森林碳储量主要分布在秦巴山林区、关山林区、黄龙山林区和桥山林区,其中汉中森林碳储量最大,其次为延安,榆林最小。各地区的森林碳储量均呈现逐渐增加趋势。 相似文献
3.
江西生态优势明显,森林覆盖率居全国前列,研究植被生态系统碳汇价值是应对气候变化和生态文明建设的具体体现。基于森林资源清查资料,研究了2001—2016年江西省森林碳汇价值;基于卫星遥感数据反演获取植被生态系统净初级生产力(NPP),评估了2000—2016年江西各设区市(县)植被碳汇分布特征。结果表明:1)2016年江西省森林碳储量价值为980.30亿元,植被和森林碳汇价值均呈上升趋势。2)江西省植被碳汇价值增加率为4.55亿元/a,2016年约为823.53亿元,每公顷所创造的碳汇经济价值为4930.67元,比2000年增加了11%。3)2016年各设区市植被碳汇价值排名前三位的分别是赣州、吉安和上饶,排名后三位的是新余、鹰潭和萍乡,单位面积固碳价值排名前三位的为赣州、吉安和抚州,排名后三位的是南昌、九江和鹰潭,其排名与森林面积和森林覆盖率有较大关系。 相似文献
4.
《青海气象》2014,(2)
青海作为草地大省,草地碳汇潜力巨大。在全球气候暖干化的强(A2a)、弱(B2a)情景下,青海省气候呈现暖湿化趋势;青海省潜在草地的主体是冻原高山草地大类,占青海省潜在草地总面积的75.69%,其潜在碳汇占全省草地潜在碳汇的87.22%。与近50年(1950-2000)相比,未来(2001-2050)A2a、B2a情景下青海省将呈现草地面积减少,林地面积增加的态势,草地面积将分别减少30.71%和28.5%;草地潜在碳汇将分别降低25.55%和20.82%,气候暖湿化趋势有利于植被总碳汇的增加,主体上是以冻原高山草地大类碳汇大幅减少,温带森林(在青海具体为寒温性针叶林类)碳汇增加为特征。 相似文献
5.
青藏高原及周边地区被称为“世界第三极”,是除南、北两极地区之外全球最重要的冰川资源富集地,冰川面积49873.33千米2,冰储量约4561.39千米3,分别占中国冰川总面积的84%和冰储量的81.6%。在全球变暖背景下,尤其是20世纪80年代以来. 相似文献
6.
林业行业应对气候变化的措施和成效 总被引:1,自引:0,他引:1
从植树造林,发挥森林吸碳和固碳作用,加强天然林保护,提高森林的碳汇潜力两大方面,陈述了林业对减缓全球气候变化的贡献。同时介绍了国家林业局在气候变化的基础科学和应用科学研究领域,开展的卓有成效的工作;介绍了国家林业局陆地生态系统定位研究网络的基础建设、与气候变化有关的科学研究的立项与课题开展情况。最后,从探讨提高森林碳汇的方法、推进加强森林碳保护的措施、寻找林产品碳替代的途径等三方面,论述了今后一段时期林业行业在减缓气候变化中的重要任务,分析中国林业在继续增加森林面积和碳汇能力方面具有的潜力。 相似文献
7.
中国湿地土壤碳库保护与气候变化问题 总被引:10,自引:0,他引:10
中国湿地分布广, 类型丰富, 但存在着垦殖率高、碳密度较低、围垦损失严重等问题。估计我国湿地土壤碳库达8~10 Pg, 占全国陆地土壤总有机碳库的约1/10~1/8, 过去50 a间的损失可能达1.5 Pg。围垦和过度放牧是我国湿地土壤退化和碳库损失的主要驱动因子。目前,湿地土壤碳库保护面临严峻的挑战,从应对气候变化和保护人类生存环境的战略高度切实加强湿地资源保护,可以为增强陆地生态系统碳汇、探寻温室气体减排的潜在途径提供技术支持。 相似文献
8.
中国湿地土壤碳库保护与气候变化问题 总被引:3,自引:0,他引:3
中国湿地分布广, 类型丰富, 但存在着垦殖率高、碳密度较低、围垦损失严重等问题。估计我国湿地土壤碳库达8~10 Pg, 占全国陆地土壤总有机碳库的约1/10~1/8, 过去50 a间的损失可能达1.5 Pg。围垦和过度放牧是我国湿地土壤退化和碳库损失的主要驱动因子。目前,湿地土壤碳库保护面临严峻的挑战,从应对气候变化和保护人类生存环境的战略高度切实加强湿地资源保护,可以为增强陆地生态系统碳汇、探寻温室气体减排的潜在途径提供技术支持。 相似文献
9.
中国土壤有机碳库及其演变与应对气候变化 总被引:1,自引:0,他引:1
潘根兴 《气候变化研究进展》2008,4(05):282-289
通过综述和评价中国土壤,特别是农田土壤有机碳库(以下简称碳库)的现状与演变态势, 讨论其对我国应对气候变化的意义, 提出了我国土壤碳库及其演变与应对气候变化的基本国情是:1) 我国土壤背景碳储量较低且区域分布不均衡;2) 我国土壤固碳效应明显,未来固碳减排潜力显著;3) 技术和政策是实现和提高我国土壤碳汇、促进我国应对气候变化能力建设的重要途径。建议进一步加强对我国农田土壤固碳减排的研发投入, 完善农业应对气候变化的相关政策和鼓励措施体系,研究构建气候友好的新型农业,以期在提高和稳定农业生产力与应对气候变化能力上获得双赢。 相似文献
10.
中国土壤有机碳库及其演变与应对气候变化 总被引:33,自引:0,他引:33
潘根兴 《气候变化研究进展》2008,4(5):282-289
通过综述和评价中国土壤,特别是农田土壤有机碳库(以下简称碳库)的现状与演变态势, 讨论其对我国应对气候变化的意义, 提出了我国土壤碳库及其演变与应对气候变化的基本国情是:1) 我国土壤背景碳储量较低且区域分布不均衡;2) 我国土壤固碳效应明显,未来固碳减排潜力显著;3) 技术和政策是实现和提高我国土壤碳汇、促进我国应对气候变化能力建设的重要途径。建议进一步加强对我国农田土壤固碳减排的研发投入, 完善农业应对气候变化的相关政策和鼓励措施体系,研究构建气候友好的新型农业,以期在提高和稳定农业生产力与应对气候变化能力上获得双赢。 相似文献
11.
Fengxiang X. Han M. John Plodinec Yi Su David L. Monts Zhongpei Li 《Climatic change》2007,84(2):191-202
Analyses of regional carbon sources and sinks are essential to assess the economical feasibility of various carbon sequestration
technologies for mitigating atmospheric CO2 accumulation and for preventing global warming. Such an inventory is a prerequisite for regional trading of CO2 emissions. As a U.S. Department of Energy Southeast Regional Carbon Sequestration Partner, we have estimated the state-level
terrestrial carbon pools in the southeast and south-central US. This region includes: Alabama, Arkansas, Florida, Georgia,
Louisiana, Mississippi, North Carolina, South Carolina, Tennessee, Texas, and Virginia. We have also projected the potential
for terrestrial carbon sequestration in the region. Texas is the largest contributor (34%) to greenhouse gas emission in the
region. The total terrestrial carbon storage (forest biomass and soils) in the southeast and south-central US is estimated
to be 130 Tg C/year. An annual forest carbon sink (estimated as 76 Tg C/year) could compensate for 13% of the regional total
annual greenhouse gas emission (505 Tg C, 1990 estimate). Through proper policies and the best land management practices,
54 Tg C/year could be sequestered in soils. Thus, terrestrial sinks can capture 23% of the regional total greenhouse emission
and hence are one of the most cost-effective options for mitigating greenhouse emission in the region. 相似文献
12.
Terrestrial biological atmospheric carbon dioxide removal (BCDR) through bioenergy with carbon capture and storage (BECS), afforestation/reforestation, and forest and soil management is a family of proposed climate change mitigation strategies. Very high sequestration potentials for these strategies have been reported, but there has been no systematic analysis of the potential ecological limits to and environmental impacts of implementation at the scale relevant to climate change mitigation. In this analysis, we identified site-specific aspects of land, water, nutrients, and habitat that will affect local project-scale carbon sequestration and ecological impacts. Using this framework, we estimated global-scale land and resource requirements for BCDR, implemented at a rate of 1 Pg C y?1. We estimate that removing 1 Pg C y?1 via tropical afforestation would require at least 7?×?106 ha y?1 of land, 0.09 Tg y?1 of nitrogen, and 0.2 Tg y?1 of phosphorous, and would increase evapotranspiration from those lands by almost 50 %. Switchgrass BECS would require at least 2?×?108 ha of land (20 times U.S. area currently under bioethanol production) and 20 Tg y?1 of nitrogen (20 % of global fertilizer nitrogen production), consuming 4?×?1012?m3 y?1 of water. While BCDR promises some direct (climate) and ancillary (restoration, habitat protection) benefits, Pg C-scale implementation may be constrained by ecological factors, and may compromise the ultimate goals of climate change mitigation. 相似文献
13.
Carbon Storage of Forest Vegetation in China and its Relationship with Climatic Factors 总被引:6,自引:0,他引:6
Estimates of forest vegetation carbon storage in China varied due to different methods used in the assessments. In this paper, we estimated the forest vegetation carbon storage from the Fourth Forest Inventory Data (FFID) in China using a modified volume-derived method. Results showed that total carbon storage and mean carbon density of forest vegetation in China were 3.8 Pg C (about 1.1% of the global vegetation carbon stock) and 41.32 Mg/ha, respectively. In addition, based on linear multiple regression equation and factor analysis method, we analyzed contributions of biotic and abiotic factors (including mean forest age, mean annual temperature, annual precipitation, and altitude) to forest carbon storage. Our results indicated that forest vegetation carbon storage was more sensitive to changes of mean annual temperature than other factors, suggesting that global warming would seriously affect the forest carbon storage. 相似文献
14.
Offsetting China's CO2 Emissions by Soil Carbon Sequestration 总被引:4,自引:0,他引:4
R. Lal 《Climatic change》2004,65(3):263-275
Fossil fuel emissions of carbon (C) in China in 2000 was about 1 Pg/yr, which may surpass that of the U.S. (1.84 Pg C) by 2020. Terrestrial C pool of China comprises about 35 to 60 Pg in the forest and 120 to 186 Pg in soils. Soil degradation is a major issue affecting 145 Mha by different degradative processes, of which 126 Mha are prone to accelerated soil erosion. Similar to world soils, agricultural soils of China have also lost 30 to 50% or more of the antecedent soil organic carbon (SOC) pool.Some of the depleted SOC pool can be re-sequestered through restoration of degraded soils, and adoption of recommended management practices. The latter include conversion of upland crops to multiple cropping and rice paddies, adoption of integrated nutrient management (INM) strategies, incorporation of cover crops in the rotations cycle and adoption of conservation-effective systems including conservation tillage. A crude estimated potential of soil C sequestration in China is 119 to 226 Tg C/y of SOC and 7 to 138 Tg C/y for soil inorganic carbon (SIC) up to 50 years. The total potential of soil C sequestration is about 12 Pg, and this potential can offset about 25%of the annual fossil fuel emissions in China. 相似文献
15.
Effects of Land Use Change On the Storage of Soil Organic Carbon: A Case Study of the Qianyanzhou Forest Experimental Station in China 总被引:4,自引:0,他引:4
Wang Shaoqiang Liu Jiyuan Yu Guirui Pan Yuanyuan Chen Qingmei Li Kerang Li Jiayong 《Climatic change》2004,67(2-3):247-255
Forests play an important role in sequestrating carbon from the atmosphere. Since the 1980s, reforestation activities have been implemented in the area surrounding the Qianyanzhou Forest Experimental Station in Jiangxi Province, China. Farmland and heavily eroded waste land were replanted with fruit, orchards and forest plantations. The area surrounding the Qianyanzhou Forest Experimental Station was selected as research site to analyze the potential of reforestation in carbon sequestration. This study evaluates the variation of soil organic carbon storage under the different land use types. Soil organic carbon storage varied greatly with land use types. From 1984 to 2002, soil organic carbon storage increased 2.45 × 106 kg across eight land use types. This study demonstrates the potential for carbon sequestration in soils from reforestation. However, a complete understanding of soil carbon fluxes at the landscape scale will depend on the potential and retention period of soil organic carbon. 相似文献
16.
Carbon sequestration through ecological restoration programs is an increasingly important option to reduce the rise of atmospheric carbon dioxide concentration. China’s Grain for Green Program (GGP) is likely the largest centrally organized land-use change program in human history and yet its carbon sequestration benefit has yet to be systematically assessed. Here we used seven empirical/statistical equations of forest biomass carbon sequestration and five soil carbon change models to estimate the total and decadal carbon sequestration potentials of the GGP during 1999–2050, including changes in four carbon pools: aboveground biomass, roots, forest floor and soil organic carbon. The results showed that the total carbon stock in the GGP-affected areas was 682 Tg C in 2010 and the accumulative carbon sink estimates induced by the GGP would be 1697, 2635, 3438 and 4115 Tg C for 2020, 2030, 2040 and 2050, respectively. Overall, the carbon sequestration capacity of the GGP can offset about 3%–5% of China’s annual carbon emissions (calculated using 2010 emissions) and about 1% of the global carbon emissions. Afforestation by the GGP contributed about 25% of biomass carbon sinks in global carbon sequestration in 2000–2010. The results suggest that large-scale ecological restoration programs such as afforestation and reforestation could help to enhance global carbon sinks, which may shed new light on the carbon sequestration benefits of such programs in China and also in other regions. 相似文献
17.
Jian Ni 《Climatic change》2002,55(1-2):61-75
The BIOME3 model was used to simulate the distribution patterns and carbon storage of the horizontal, zonal boreal forests in northeast and northwest China using a mapping system for vegetation patterns combined with carbon density estimates from vegetation and soils. The BIOME3 prediction is in reasonable good agreement with the potential distribution of Chinese boreal forests. The effects of changing atmospheric CO2 concentration had a nonlinear effect on boreal forest distribution, with 3.5–10.8% reduced areas for both increasing and decreasing CO2. In contrast, the increased climate together with and without changing CO2 concentration showed dramatic changes in geographic patterns, with 70% reduction in area and disappearance of almost boreal forests in northeast China. The baseline carbon storage in boreal forests of China is 4.60 PgC (median estimate) based on the vegetation area of actual boreal forest distribution. If taking the large area of agricultural crops into account, the median value of potential carbon storage is 6.92 PgC. The increasing (340–500 ppmv) and decreasing CO2 concentration (340–200 ppmv) led to decrease of carbon storage, 0.33 PgC and 1.01 PgC respectively compared to BIOME3 potential prediction under present climate and CO2 conditions. Both climate change alone and climate change with CO2 enrichment (340–500 ppmv) reduced largely the carbon stored in vegetation and soils by ca. 6.5 PgC. The effect of climate change is more significant than the direct physiological effect of CO2 concentration on the boreal forests of China, showing a large reduction in both distribution area and carbon storage. 相似文献
18.
Ning Zeng Anthony W. King Ben Zaitchik Stan D. Wullschleger Jay Gregg Shaoqiang Wang Dan Kirk-Davidoff 《Climatic change》2013,118(2):245-257
A carbon sequestration strategy has recently been proposed in which a forest is actively managed, and a fraction of the wood is selectively harvested and stored to prevent decomposition. The forest serves as a ‘carbon scrubber’ or ‘carbon remover’ that provides continuous sequestration (negative emissions). Earlier estimates of the theoretical potential of wood harvest and storage (WHS) based on coarse wood production rates were 10?±?5 GtC y?1. Starting from this physical limit, here we apply a number of practical constraints: (1) land not available due to agriculture; (2) forest set aside as protected areas, assuming 50 % in the tropics and 20 % in temperate and boreal forests; (3) forests difficult to access due to steep terrain; (4) wood use for other purposes such as timber and paper. This ‘top-down’ approach yields a WHS potential 2.8 GtC y?1. Alternatively, a ‘bottom-up’ approach, assuming more efficient wood use without increasing harvest, finds 0.1–0.5 GtC y?1 available for carbon sequestration. We suggest a range of 1–3 GtC y?1 carbon sequestration potential if major effort is made to expand managed forests and/or to increase harvest intensity. The implementation of such a scheme at our estimated lower value of 1 GtC y?1 would imply a doubling of the current world wood harvest rate. This can be achieved by harvesting wood at a moderate harvesting intensity of 1.2 tC ha?1 y?1, over a forest area of 8 Mkm2 (800 Mha). To achieve the higher value of 3 GtC y?1, forests need to be managed this way on half of the world’s forested land, or on a smaller area but with higher harvest intensity. We recommend WHS be considered part of the portfolio of climate mitigation and adaptation options that needs further research. 相似文献
19.
Forage Yield-Based Carbon Storage in Grasslands of China 总被引:7,自引:0,他引:7
Jian Ni 《Climatic change》2004,67(2-3):237-246
Forage yield-based carbon storage in 18 grasslands of China was estimated according to the detailed investigation of grassland area and forage yield (standing crop), which were derived from a 10-year national grassland survey. The total forage yield carbon in Chinese grasslands is 134.09 Tg C for ca. 299 × 106 ha of grassland area and 1232 kg/ha of mean forage yield. The carbon storage is different depending on grassland types and climatic regions. Meadow, steppe and tussock occupy 93.3% (125.14 Tg C), and desert and swamp only accounts for 6.7% (8.95 Tg C) of total forage yield carbon. Forage yield carbon is stored largely in temperate (38.4%, 51.54 Tg C) and alpine regions (30.4%, 40.78 Tg C), and to less extent in tropical regions (22.1%, 29.66 Tg C). These three regions take 91% of the forage yield carbon in grasslands of China. The warm-temperate region accounts for only 9% (12.1 Tg C) of forage yields carbon. The forage yield-based carbon in grasslands of China is more accurate than the site biomass-based carbon estimate and the carbon density-based estimate. Although, forage yield carbon storage is small compared with the total carbon storage in China, carbon budgets of grasslands are often a dominant component in many regions and provide an important management opportunity to enhance terrestrial carbon sinks in vast areas of China. 相似文献