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1.
近年来,我国人工林面积不断增加,人工林在我国陆地森林生态系统碳收支中的作用越来越大。以克拉玛依人工杨树林和荒漠灌木林为研究对象,通过样地调查,对生物量及碳储量、碳密度、碳汇功能等进行了估算。通过实测数据及模型分析,得出以下基本结论:1该人工杨树林单位面积生物量平均为51.30 t·hm-2;碳密度平均为24.59 t·hm-2,碳储量为73 715.41 t,说明其发挥着一定的碳汇作用。2与荒漠环境下灌木林对比结果表明,克拉玛依人工杨树林单位面积生物量增加了50.56 t·hm-2,碳密度增加了24.26 t·hm-2,碳储量增加了72 726.14 t,表明在干旱区荒漠环境下通过造林来增加区域陆地植被碳汇,进而达到碳减排的目的是可行的。 相似文献
2.
通过造林和再造林,增加森林碳汇量是目前公认最经济有效地解决CO2浓度上升的方法之一,人工林的碳汇作用也被认为是减缓全球气候变化的一种可能机制和最有希望的选择。根据国内外植树减排的计算规则,结合干旱区自然环境特征,提出了干旱区规模化植树CO2减排效果的计算方法,对植树减排计算因子的获取方法进行了探讨,指出应从政策、技术、市场等各个方面加强对林业碳汇的系统研究,明确和量化我国干旱区人工林造林再造林对全球气候变暖所作出的贡献。研究可为干旱区林业碳汇项目开发和管理提供方法上的参考依据。 相似文献
3.
随着我国造林碳汇项目工作的开展,对造林碳汇项目综合效益的评估显得愈加重要。采用综合指标体系法,立足于干旱区特殊的自然地理环境,根据造林碳汇项目本身具有的特点和功能,从生态、社会和经济效益3方面选取代表性指标,建立了干旱区造林碳汇项目综合效益评估指标体系,这个评估系统不同于其他评价系统的是引入了温室气体排放指标,讨论了温室气体排放指标与传统固碳指标的差异,并给出了各个指标的计算方法。为干旱区造林碳汇项目开发和管理提供了参考依据。 相似文献
4.
干旱区荒漠新垦土地土壤有机碳含量特征 总被引:6,自引:1,他引:5
以克拉玛依生态农业开发区为例,研究了干旱区荒漠新垦土地不同土地利用方式下的土壤有机碳与活性有机碳含量差异及其剖面分布特征,并讨论了干旱区荒漠开垦利用对荒漠"碳汇"功能的促进作用,以及土地利用方式对土壤有机碳与活性有机碳剖面分布特征的影响。结果表明:克拉玛依生态农业开发区土壤有机碳含量普遍较低。在0~20cm深度内,速生杨林地与苜蓿地土壤有机碳含量随土层加深而降低,棉花地、打瓜-棉花地耕作类土壤有机碳垂直分布相对较均匀,但是表层0~5cm土壤有机碳略低于下层,土壤活性有机碳剖面分布特征与有机碳类似。农田与林地的土壤有机碳与活性有机碳含量均明显高于荒漠,农田对土壤有机碳的汇聚作用优于人工林地。 相似文献
5.
探讨华山松人工林土壤有机碳含量和有机碳密度以及土壤有机碳密度的主要影响因子,为科学评估华山松人工林固碳能力提供依据。在云南玉溪磨盘山森林公园内选择处于中林龄、近成熟林和成熟林的华山松人工林,设置样地并记录样地信息,并取0-60cm土层土样,在实验室测定不同土层的有机碳含量及碳密度。运用主成分分析对华山松林地内的植被因子、地形因子和土壤理化因子进行评价。华山松人工林由中龄林-近熟林-成熟林的发育进程中,土壤有机碳含量和有机碳密度都表现为近成熟林(28.76g·kg-1,128.87t·hm-2)>中林龄(25.70g·kg-1,124.34t·hm-2)>成熟林(25.61g·kg-1,117.49 t·hm-2)。3种林分土壤有机碳含量和有机碳密度都是随土壤深度的增加而逐渐降低。主成分分析表明林木的平均胸径、平均树高、海拔、碳氮比和全氮含量是影响土壤有机碳密度的主导因子。华山松人工林土壤有机碳具有明显的表聚现象,减少人为的不必要干扰,在一定程度上有利于土壤固定更多的碳。 相似文献
6.
选取内蒙古西部的温带森林、温带草原、温带灌丛、温带荒漠和草甸共70个样地,对其土壤有机碳进行研究。结果表明,内蒙古西部不同植被类型的土壤有机碳含量不同,温带森林的固碳效果最好,其次为温带灌丛和草原,再次之为草甸和荒漠。内蒙古西部20cm土壤有机碳储量为11.034×10~8t,100cm土壤有机碳储量为22.062×10~8t,温带草原和荒漠碳储量最高。气候因素对内蒙古西部土壤有机碳含量的影响显著,偏相关分析结果表明气温是主要的影响因子。土壤全氮含量与土壤有机碳含量有明显的线性正相关关系。 相似文献
7.
陕西省森林植被碳储量、碳密度及其空间分布格局 总被引:4,自引:0,他引:4
采用森林植被生物量换算因子连续法,估算了2009年陕西省森林植被碳贮量和碳密度及其地理分布特征。结果表明:陕西省森林植被碳储量为19942.20万t,以栎类最大,占全省碳储量的58.13%。天然林是森林植被碳储量的主体,占全省碳储量的95.30%。陕西省森林植被碳密度为31.20t/hm2,以桦木最高,为45.92t/hm2。天然林的碳密度为36.23t/hm2,是人工林的4.57倍。陕西省森林植被碳储量主要分布在管辖区内涉及黄龙山、桥山、关山、秦岭和巴山林区的行政区,其中以汉中最大,占全省碳储量的26.16%。森林植被碳密度以西安最高,为45.58t/hm2,而处于陕西省最北部榆林的碳储量和碳密度最低。根据碳储量与碳密度的空间差异,陕西省应采取分区森林经营与管理措施,一方面通过科学抚育和管理提高现有自然林的碳汇能力,另一方面加强重点造林工程,扩大人工林覆盖面积,增加森林碳汇潜力,使陕西省森林在全球碳汇中发挥重要作用。 相似文献
8.
人工林生态系统的固碳作用对缓解全球气候变化发挥着重大的作用.以山西太岳山31年生落叶松人工林为研究对象,通过野外调查和室内分析,对其生物量、各组分碳含量、碳储量及空间分布进行了测定.结果表明:1)华北落叶松单木生物量和胸径、树高之间存在紧密的相关关系.林分平均生物量为166.82t·hm-2.各层次按大小排列为:乔木层(111.95t·hm-2)>枯落物层(36.67t·hm-2)>草本层(17.85t·hm-2)>灌木层(0.35t·hm-2).2)华北落叶松人工林生态系统各组分平均碳含量为(单位:gC·g-1):树干0.4846、树皮0.5030、树枝0.4753、树叶0.4732、根系0.4563、灌木层0.4161、草本层0.2898、土壤层(0~60cm)0.0176,随着土壤深度增加碳含量逐渐降低.3)华北落叶松人工林生态系统总碳储量为178.3t· hm-2,其中土壤层为最大碳库,储量为112.97t·hm-2,占总碳储量的63.36%.植被层总碳储量为59.06t·hm-2,占总碳储量的33.13%.按大小顺序排列为乔木层54.06t·hm-2、草本层4.85t· hm-2、灌木层0.15t· hm-2.枯落物层碳储量为6.26t·hm-2,占总储量的3.51%.4)华北落叶松人工林乔木层年净生产力为9.21t·hm-2·a-1,碳素年平均固定量为4.38t·hm-2·a-1. 相似文献
9.
利用NPP实测法对通辽市杨树人工林各层次、林木各器官的含碳率以及碳密度进行了研究。结果表明:林木各器官含碳率的变化范围在35.96%~52.39%之间,排序为叶皮枝干根;草本层含碳率的变化范围在34.93%~44.24%之间;枯落物层含碳率的变化范围在34.19%~39.44%之间;土壤各层有机碳含量(土壤含碳率)的变化范围在0.41~21.14g·kg-1之间。杨树人工林碳密度为100.44t·hm-2,其中林木为27.27t·hm-2;草本层为0.13t·hm-2;枯落物层为0.65t·hm-2;土壤碳密度为72.38t·hm-2,土壤有机碳含量和碳密度均呈现随着土层深度的增加而逐渐下降的变化规律。文中对于杨树人工林含碳率的研究为今后更精确的测算当地杨树人工林碳储量提供数据基础及理论依据,也将为今后通辽市林业发展及碳汇造林提供科学依据。 相似文献
10.
克拉玛依人工林生物量与土壤理化性质 总被引:1,自引:0,他引:1
通过对人工林与其周围荒漠灌木群落生物量及其土壤的物理化学性质的变化分析,结果表明:1克拉玛依人工杨树林林下植被层和凋落物层生物量为5.87 t·hm-2,荒漠灌木群落生物量为0.74 t·hm-2,人工林明显高于其周围荒漠;2林地土壤养分在不同土壤层次中的含量较荒漠有不同程度的降低,容重增加,但土壤含水率有较大提高;3人工林地土壤有机质含量偏低,表层土壤有机质较荒漠降低8.83%,但林地10~30 cm和30~50 cm层土壤分别增加20.74%和33.13%;4林内各层土壤含水率与凋落物层生物量呈显著正相关,土壤养分与生物量相关性不大。 相似文献
11.
基于自然植被的延河流域农田生态系统土壤固碳潜力评估 总被引:3,自引:0,他引:3
以延河流域自然植被土壤有机碳为对照,对该区现有农田生态系统土壤固碳潜力进行评估。结果表明:影响自然植被土壤有机碳密度空间分布的环境因子有年均降雨季节变化、坡度和年均温度季节变化;而影响农田生态系统土壤有机碳密度分布的环境因素则包括年均蒸发量、年均最高温度与坡向;有机碳空间分布规律方面,延河流域南部土壤有机碳密度要明显高于北部,并且呈由北向南逐渐递增的趋势;情景模拟分析表明,延河流域坡度25°以上、15°~25°以及15°以下不同类型的耕地退耕后分别可以实现的固碳效益为90.41×104t、58.52×104t、57.55×104t,而整个延河流域的农田生态系统如果全部实行退耕还林(草),其固碳潜力在206.48×104t左右。可以看出,以土地利用调整为核心的区域固碳策略对环境改善具有重要意义。 相似文献
12.
森林固碳效益的经济核算——以甘肃小陇山林区为例 总被引:1,自引:0,他引:1
何栋材 《干旱区资源与环境》2009,(4)
小陇山林区位于甘肃东南部,全林区以锐齿栎、油松、栓皮栎、杨、桦树、落叶松、华山松、云、冷杉以及其他阔叶混交等8类林分为建群树种。森林的单木生物量(W)与胸高直径(D)、以及与胸径-树高双变量(D2H)之间均存在着紧密的相关关系。用标准地每木调查数据分别建立了8种林分的生物量回归分析模型,并以此计算了8种林分的碳储存密度,依各林分面积、生物量与二氧化碳实物量之间的转换系数、二氧化碳与纯碳量之间的折算系数分别计算了全林区乔木层的总生物量为2.85×107t、固定的二氧化碳实物量为4.65×107t,折算的纯碳量1.27×107t。用造林成本法估算了全林区乔木层固碳的经济效益为2.78×109元人民币。 相似文献
13.
使用LI-8100仪器实测了在生长季阿拉善的梭梭、沙冬青、红砂、华北驼绒藜、珍珠、白刺六种植物群落土壤呼吸速率,使用挖刨面法逐月测定了土壤温度和土壤含水量。结果表明:这六种荒漠植物群落土壤呼吸速率日动态均呈单峰型,最高值皆出现在12:00-14:00,最低值出现在早晨8:00,土壤呼吸速率最大值出现时间先于气温最高值出现的时间。六种植物群落土壤呼吸速率的月变化呈单峰曲线,与近地面气温的变化趋势一致。六种植物群落土壤呼吸速率的日变化与地表温度达到极显著正相关关系,与近地面气温、5cm、10cm温度具有显著相关性。六种植物群落与土壤含水量0-10cm、10-20cm、20-30cm都没有显著相关性。在源与汇的问题上,梭梭、沙冬青、红砂、珍珠、华北驼绒藜、白刺是汇。 相似文献
14.
LIU Bingxia 《干旱区科学》2016,8(1):47-59
Implementation of the Grain-for-Green project has led to rapid land cover changes and resulted in a significantly increased vegetation cover on the Loess Plateau of China during the past few decades. The main objective of this study was to examine the responses of soil water dynamics under four typical vegetation types against precipitation years. Soil water contents(SWCs) were measured in 0–4.0 m profiles on a hillslope under the four vegetation types of shrub, pasture, natural fallow and crop in a re-vegetated catchment area from April to October in normal(2010), dry(2011), wet(2014) and extremely wet(2013) years. The results indicated that precipitation and vegetation types jointly controlled the soil water temporal dynamics and profile characteristics in the study region. SWCs in 0–4.0 m profiles of the four vegetation types were ranked from high to low as cropfallowpastureshrub and this pattern displayed a temporal stability over the four years. In the extremely wet year, SWC changes occurred in the 0–2.0 m layer under shrub and pasture while the changes further extended to the depth of 4.0-m deep layers under fallow and crop. In the other three years, SWCs changes mainly occurred in the 0–1.0 m layer and kept relatively stable in the layers deeper than 1.0 m for all the four vegetation types. The interannual variation in soil depth of SWCs was about 0–2.0 m for shrub and pasture, about 0–3.4 m for fallow and about 0–4.0 m for crop, respectively. The dried soil layers formed at the depths of 1.0, 0.6, 1.6 and 0.7 m under shrub, and 1.0, 1.0, 2.0 and 0.9 m under pasture, respectively in 2010, 2011, 2013 and 2014. The infiltrated rainwater mostly stayed in the 0–1.0 m layer and hardly supplied to soil depth 1.0 m in normal, dry and wet years. Even in the extremely wet year of 2013, rainwater recharge depth did not exceed 2.0 m under shrub and pasture. This implied that soil desiccation was difficult to remove in normal, dry and wet years, and soil desiccation could be removed in 1.0–2.0 m soil layers even in the extremely wet year under shrub and pasture. The results indicated that the natural fallow was the best vegetation type for achieving sustainable utilization of soil water and preventing soil desiccation. 相似文献
15.
The impact of land use change on soil organic carbon and labile organic carbon stocks in the Longzhong region of Loess Plateau 总被引:3,自引:0,他引:3
LiHua ZHANG 《干旱区科学》2012,4(3):241-250
Land use change (LUC) is widely recognized as one of the most important driving forces of global carbon cycles. The soil organic carbon (SOC) and labile organic carbon (LOC) stores were investigated at arable land (AL), artificial grassland (AG), artificial woodland (AW), abandoned arable land (AAL) and desert steppe (DS) in the Longzhong region of the Loess Plateau in Northwest China. The results showed that conversions from DS to AL, AL to AG and AL to AAL led to an increase in SOC content, while the conversion from DS to AW led to a decline. The differences in SOC content were significant between DS and AW at the 20-40 cm depth and between AL and AG at the 0-10 cm depth. The SOC stock in DS at the 0-100 cm depth was 39.4 t/hm 2 , increased by 28.48% after cultivation and decreased by 19.12% after conversion to AW. The SOC stocks increased by 2.11% from AL to AG and 5.10% from AL to AAL. The LOC stocks changed by a larger magnitude than the SOC stocks, which suggests that it is a more sensitive index of carbon dynamics under a short-term LUC. The LOC stocks increased at 0-20 cm and 0-100 cm depths from DS to AW, which is opposite to that observed for SOC. The proportion of LOC to SOC ranged from 0.14 to 0.20 at the 0-20 cm depth for all the five land use types, indicating low SOC dynamics. The allocation proportion of LOC increased for four types of LUC conversion, and the change in magnitude was largest for DS to AW (40.91%). The afforestation, abandonment and forage planting on arable land led to sequestration of SOC; the carbon was lost initially after afforestation. However, the carbon sink effect after abandonment may not be sustainable in the study area. 相似文献
16.
林业碳汇核证减排量所有权归属的实践样态与应然思路 总被引:1,自引:0,他引:1
陈娟丽 《干旱区资源与环境》2021,35(4):1-9
林业碳汇核证减排量是应对气候变化领域的新生事物,其所有权归属是确保林业碳汇交易稳定的首要问题,但我国《民法典》物权编、自然资源法和碳排交易规范中均无明确规定,个别部门规章对其收益分配的规定有违上位法。实践中各类林业碳汇项目核证减排量所有权归属情形不尽一致的原因是多方面的:林业碳汇权利与采矿权、渔业权产生机理一致,依据土地和森林资源所有权这些"母权",核证减排量可归属的主体众多;我国森林资源用益物权体系结构复杂,搭建了多种归属路径;国际规则下林业碳汇项目参与主体多数涉外,加剧了归属随意化的趋势。在我国鼓励积极开展碳汇交易和推进法规制度建设的背景下,应尽快完善相关法律规范,将核证减排量"类型化"为自然资源性权利客体,圈定所有权归属主体范围,确定国家对核证减排量的管理者角色,确立同一项目核证减排量由多个参与主体共有的制度,遵循自愿公平原则合理分配转让收益,以及做好相关权属争议解决的法律准备。最终为拓宽放活经营权渠道,保障各方利益,乃至我国资源安全和气候安全提供法律支撑。 相似文献
17.
选取陕北毛乌素沙地从半固定沙地到恢复2354a的灌木和乔木固沙林地,采用密度分组法分析表层土壤轻、重组分碳氮含量、C/N的演变及累积速率、固定碳氮贡献率特征。结果表明:固沙林从恢复2354a,乔木和灌木林土壤轻组碳分别增加了14.040.6倍和8.819.2倍,显著高于对应重组碳3.27.7倍和3.58.1倍的增幅;对应轻组氮分别增加了14.540.9倍和11.829.1倍,也显著高于重组氮4.68.5倍和4.412.6倍的增幅,说明轻组碳氮相对重组碳氮对固沙林恢复更加敏感。土壤轻重组碳氮含量增加使得乔木和灌木林轻组碳密度增速分别达0.57mg·hm^-2·a^-1和0.26mg·hm^-2·a^-1,重组碳密度增速则仅为0.18mg·hm^-2·a^-1和0.20mg·hm^-2·a^-1;同时,轻组氮密度增速分别达0.03mg·hm^-2·a^-1和0.02mg·hm^-2·a^-1,重组氮密度增速则分别达0.02mg·hm^-2·a^-1和0.04mg·hm^-2·a^-1。按此碳氮组分增速,到固沙林恢复54a时,乔木林和灌木林土壤轻组碳可分别贡献75.9%和59.4%的全有机碳增量;土壤重组氮则可贡献44.6%和63.9%的全氮增量。另外,恢复54a两种林地土壤重组C/N分别比半固定沙地降低11.4%和38.5%。但轻组C/N在乔木林并无显著变化,在灌木林恢复2354a土壤轻组C/N降低了21.7%31.0%,显著改变了土壤碳库性质。表明陕北固沙林恢复土壤表现出显著的固定碳氮效应,并且乔木林有更好的固碳能力,灌木林则有较好的固氮效应。 相似文献
18.
Carbon(C) storage has received significant attention for its relevance to agricultural security and climate change. Afforestation can increase C storage in terrestrial ecosystems, and has been recognized as an important measure to offset CO_2 emissions. In order to analyze the C benefits of planting wolfberry(Lycium barbarum L.) on the secondary saline lands in arid areas, we conducted a case study on the dynamics of biomass carbon(BC) storage and soil organic carbon(SOC) storage in different-aged wolfberry plantations(4-, 7-and 11-year-old) established on a secondary saline land as well as on the influence of wolfberry plantations on C storage in the plant-soil system in an arid irrigated area(Jingtai County) of Gansu Province, China. The C sequestration and its potential in the wolfberry plantations of Gansu Province were also evaluated. An intact secondary saline land was selected as control. Results show that wolfberry planting could decrease soil salinity, and increase BC, SOC and litter C storage of the secondary saline land significantly, especially in the first 4 years after planting. The aboveground and belowground BC storage values in the intact secondary saline land(control) accounted for only 1.0% and 1.2% of those in the wolfberry plantations, respectively. Compared to the intact secondary saline land, the SOC storage values in the 4-, 7-and 11-year-old wolfberry plantations increased by 36.4%, 37.3% and 43.3%, respectively, and the SOC storage in the wolfberry plantations occupied more than 92% of the ecosystem C storage. The average BC and SOC sequestration rates of the wolfberry plantations for the age group of 0–11 years were 0.73 and 3.30 Mg C/(hm~2·a), respectively. There were no significant difference in BC and SOC storage between the 7-year-old and 11-year-old wolfberry plantations, which may be due in part to the large amounts of C offtakes in new branches and fruits. In Gansu Province, the C storage in the wolfberry plantations has reached up to 3.574 Tg in 2013, and the C sequestration potential of the existing wolfberry plantations was 0.134 Tg C/a. These results indicate that wolfberry planting is an ideal agricultural model to restore the degraded saline lands and increase the C sequestration capacity of agricultural lands in arid areas. 相似文献
19.
宁夏旱区湿地生态系统碳汇功能研究 总被引:3,自引:0,他引:3
采用3S技术对2012年宁夏旱区TM卫星假彩色数字影像进行解译,并利用GPS仪进行了野外考察验证,实地调查了宁夏湿地典型植被,获取了较为全面、完整和系统的宁夏湿地资源数据,在此基础上研究了不同湿地类型碳汇功能。结果表明:宁夏湿地总面积为19.65万hm2,占国土面积的3.1%,位居我国西部干旱半干旱地区之首。其中自然湿地面积(包括河流湿地、湖泊湿地、沼泽湿地)为17.03万hm2,占宁夏湿地面积的82.38%,主要分布在宁夏沿黄经济区。宁夏湿地总碳储量为1502.80万t,约占宁夏旱区五种主要生态系统(林地、灌木、草地、湿地、特色经果林)碳汇的45.03%,比全球湿地总碳储量占全球陆地生态系统碳库的百分比(10%-35%)高出10多个百分点。预测了2015年的碳汇潜力为1593.48万t,与2012年相比,2015年湿地面积增加0.34万hm2,碳汇量增加90.68万t。 相似文献