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81.
湖南会同连作杉木林凋落物量20年动态特征 总被引:8,自引:3,他引:8
在湖南会同杉木林生态系统国家野外科学观测研究站试验基地的第Ⅲ集水区,对连作杉木林的凋落物量进行连续20a的定位观测,研究凋落物的组成特征、季节和长期动态变化格局.结果表明:连作杉木林从第8年起开始收集到凋落物,第8~20年间,凋落物量总体呈上升趋势,年平均生物量为(1109.86±117.27)kg·hm-2.凋落物中针叶、小枝、落果和碎屑所占比例分别为63.75%,25.87%,5.11%和2.19%.会同杉木人工林有明显的季节性凋落节律,1月至6月份,凋落物量总体上呈现上升趋势,从6月份至12月份总体上呈下降趋势,凋落物量的峰值出现在6月份,11月份则全年最低.凋落物与林龄呈显著的二次曲线相关,模拟凋落物量与林龄的关系,得到二次曲线方程关系:y=-10.06x2+361.1x-1747,R2=0.920, p<0.001.凋落物中的小枝、针叶、落果与林龄呈显著二次曲线方程关系(p<0.05),而碎屑与林龄的相关性不显著. 相似文献
82.
对韶关市公益林乔木层的优势树种和龄组的碳储量、碳密度和碳汇量进行分析。结果表明,韶关公益林乔木林碳储量为190.06 Tg,固碳总量优势树种以阔叶林为主,龄组以中幼林为主;平均碳密度为34.73 t·hm–2,随着龄组增加,树种的碳密度普遍呈增加趋势;公益林乔木林碳汇量为23.90万t·a–1,以中幼林的碳汇为主。提高阔叶林和中幼龄树种的单位面积蓄积量,是增加公益林有机碳储量和碳汇功能的主要途径。 相似文献
83.
研究新疆伊犁不同林龄野苹果林下的土壤碳、氮、磷含量变化特征及生态化学计量学特征变化规律,阐述不同林龄、不同土层野苹果林地土壤生态化学计量特征,为伊犁野果林资源保护提供理论依据。在伊犁巩留野苹果林内选取土母岩、海拔、立地条件较为一致的野苹果幼龄林(10 a)、中龄林(23 a)、成熟林(33 a),每个林龄林中分别设置三个20 m×20 m采样点样方,按0—15 cm, 15—30 cm, 30—45 cm, 45—60 cm土层深度取样,测定土壤SOC、TN和TP含量,选用单因素方差分析Duncan来进行显著性检验。分析表明,土壤SOC、TN含量随土层深度的增加趋于下降,而TP含量在土层间无显著变化;SOC、TN含量随林龄先上升后下降,TP含量逐渐上升。3个林龄野苹果林0—60cm土层土壤C:N为5.24—13.11、C:P为15.03—98.44、N:P为2.69—9.96。由冗余分析(RDA)可知,伊犁河谷不同林龄野苹果林下土壤有机碳对化学计量比的影响最大,全氮对化学计量比的影响最小。 相似文献
84.
黄土高原子午岭地区人工油松林碳氮磷生态化学计量特征 总被引:13,自引:8,他引:5
分析人工植被重建背景下,森林植物、枯落物与土壤的碳(C)、氮(N)、磷(P)化学计量特征有助于深入理解森林生态系统养分循环规律和系统稳定机制。以黄土高原子午岭地区的3个林龄(10、25 a和40 a)的人工油松林为对象,通过测定油松林叶片、枯落物和土壤的碳(C)、氮(N)、磷(P)含量,研究人工油松林不同林龄叶片、枯落物和土壤的化学计量学特征。结果表明,不同林龄油松叶片C、N、P含量分别为538.85—560.54 g/kg、9.00—10.47 g/kg和1.04—1.13 g/kg。在3个林龄油松林中,除叶片C含量外,叶片N、P含量存在显著差异(P0.05);枯落物层以及土壤层的C、N、P含量均存在显著差异(P0.05),且枯落物层含量大于土壤层。随着林龄的增加,叶片C∶N比呈现先减小后增大的变化,N∶P和C∶P比呈显著增加趋势,而枯落物层C∶N、C∶P和N∶P比无显著差异。同时,随着林龄的增加,除10—20 cm土层的C∶N比外,土壤的C∶N比在0—10 cm土层和C∶P和N∶P比在0—10和10—20 cm皆呈显著增加趋势。研究区油松林叶片N∶P比平均值为9.13,低于14,表明油松林生长主要受氮的限制。土壤的N含量与叶片和枯落物层的N含量、以及三者间N∶P比呈显著线性相关(P0.05),充分体现了油松林植物、枯落物与土壤之间的互动关系。研究结果可为我国黄土高原脆弱生态区的生态功能恢复与植被重建提供科学依据。 相似文献
85.
论华北农牧交错带生态与经济建设的策略与途径 总被引:11,自引:0,他引:11
华北农牧交错带自成型农作至今的百余年内,农牧业长期封闭、耗竭式生产,导致土地资源呈现沙化、碱化与贫瘠化演替,生态退化直接威胁着京、津及华北地区的生态安全,发挥市场经济下区域间互补性合作生产优势,组织农牧产品有效交流,建立开放式农牧生产结构。成为促进华北农牧交错带生态环境与社会经济互依发展的重要策略,基于不同效益主体的建设目标差异性及生态与经济演进态势的矛盾性,提出了华北农牧交错带生态一经济建设的技术途径,通过乔灌围网、草地培育,实现立体与平面相结合的土地生态防护体系;通过集约生产喜凉蔬菜、组织实施南秸北饲,发展区域特色优势产业,实现农业经济的突破。 相似文献
86.
不同林龄白桦天然次生林土壤碳通量和有机碳储量 总被引:3,自引:0,他引:3
白桦天然次生林是中国东北地区地带性顶极植被类型——阔叶红松林遭到严重干扰破坏后恢复形成的主要天然次生林类型,测定了生长季内不同林龄白桦天然次生林(20、36、82a)的土壤呼吸速率及土壤碳含量。结果表明:土壤呼吸速率的季节变化呈单峰曲线,主要受土壤温度的驱动,土壤10cm处温度可以解释不同林龄白桦林之间土壤呼吸速率86%—92%的变异,土壤呼吸与土壤含水量关系不显著(P0.05)。随着林龄的增加,生长季内土壤表面CO2通量呈增加的趋势,依次分别为740(20a)、768(36a)和809(82a)g C m-2a-1。土壤呼吸的温度敏感性指数Q10亦随林龄的增加呈上升的趋势,依次分别为2.64、2.91和3.35。平均土壤有机碳含量(0—50cm土壤层)和碳密度均随林龄的增加而增加,随土壤深度的增加而减少;其中,随着林龄的增加土壤有机碳含量依次分别为43.75、47.72和55.96 g/kg,有机碳密度为14.7、18.1和18.7 kg/m2。不同林龄间土壤表面CO2年通量与土壤有机碳密度之间存在显著的正相关关系(P0.01),但其相关程度因土层而异,其中与0—10cm土层的有机碳密度相关最为密切(R2=0.908)。 相似文献
87.
Forest net primary productivity dynamics and driving forces in Jiangxi Province,China 总被引:1,自引:0,他引:1 
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下载免费PDF全文 《植物生态学报》2016,40(7):643
Aims Subtropical forest ecosystem has great carbon sequestration capacity. Net primary productivity (NPP) plays a critical role in forest carbon cycle and is affected by a number of factors, including climate change, atmospheric composition, forest disturbance intensity and frequency, and forest age, etc. However, the contribution of these factors to the temporal-spatial dynamics of NPP is still not clear. Quantifying the main driving forces on the temporal-spatial dynamics of NPP for subtropical forest ecosystems is a critical foundation for understanding their carbon cycle.
Methods We utilized multi-sources dataset, including observed meteorological data, inversed annual maximum leaf area index (LAI), referenced NPP (simulated by Boreal Ecosystem Productivity Simulator (BEPS) model), forest age and forest types, land cover, digital elevation model (DEM), soil texture, CO2 concentration and nitrogen deposition. We used the InTEC (integrated terrestrial ecosystem carbon-budget) model to simulate the NPP dynamics for forest ecosystems in Jiangxi Province during the period of 1901-2010. The effects of climate change, forest age, CO2 concentration and nitrogen (N) deposition on forest NPP from 1970 to 2010 were discussed through designed scenarios.
Important findings (1) Validations by flux measurements and forest inventory data indicated that the InTEC model was able to capture the interannual and spatial variations of forest NPP. (2) The average forest NPP was 47.7 Tg C·a-1 (± 4.2 Tg C·a-1) during 1901-2010. The NPP in the 1970s, 1980s, 1990s and 2000s was 50.7, 48.8, 45.4, and 55.2 Tg C·a-1, respectively. As forest regrows, NPP significantly increased for forests in Jiangxi Province in the 2000s, and exceed that in the 1970s for more than 60% of the forest area. (3) During 1970-2010, under the scenarios of disturbance and non-disturbance, the forest NPP were underestimated by 7.3 Tg C·a-1 (14.5%) and overestimated by 3.6 Tg C·a-1 (7.1%) compared to the scenarios of all disturbance and non-disturbance factors, respectively. Compared to the average NPP during 1970-2010, climate change decreased NPP by -2.0 Tg C·a-1 (-4.7%), N deposition increased NPP by 4.5 Tg C·a-1 (10.4%), CO2 concentration change, and the integrated fertilization of CO2 and N deposition increased NPP by 4.4 Tg C·a-1 (10.3%) and 9.4 Tg C·a-1 (21.8%), respectively. 相似文献
Methods We utilized multi-sources dataset, including observed meteorological data, inversed annual maximum leaf area index (LAI), referenced NPP (simulated by Boreal Ecosystem Productivity Simulator (BEPS) model), forest age and forest types, land cover, digital elevation model (DEM), soil texture, CO2 concentration and nitrogen deposition. We used the InTEC (integrated terrestrial ecosystem carbon-budget) model to simulate the NPP dynamics for forest ecosystems in Jiangxi Province during the period of 1901-2010. The effects of climate change, forest age, CO2 concentration and nitrogen (N) deposition on forest NPP from 1970 to 2010 were discussed through designed scenarios.
Important findings (1) Validations by flux measurements and forest inventory data indicated that the InTEC model was able to capture the interannual and spatial variations of forest NPP. (2) The average forest NPP was 47.7 Tg C·a-1 (± 4.2 Tg C·a-1) during 1901-2010. The NPP in the 1970s, 1980s, 1990s and 2000s was 50.7, 48.8, 45.4, and 55.2 Tg C·a-1, respectively. As forest regrows, NPP significantly increased for forests in Jiangxi Province in the 2000s, and exceed that in the 1970s for more than 60% of the forest area. (3) During 1970-2010, under the scenarios of disturbance and non-disturbance, the forest NPP were underestimated by 7.3 Tg C·a-1 (14.5%) and overestimated by 3.6 Tg C·a-1 (7.1%) compared to the scenarios of all disturbance and non-disturbance factors, respectively. Compared to the average NPP during 1970-2010, climate change decreased NPP by -2.0 Tg C·a-1 (-4.7%), N deposition increased NPP by 4.5 Tg C·a-1 (10.4%), CO2 concentration change, and the integrated fertilization of CO2 and N deposition increased NPP by 4.4 Tg C·a-1 (10.3%) and 9.4 Tg C·a-1 (21.8%), respectively. 相似文献
88.
森林生态系统是最重要的陆地生态系统碳库,人工林生态系统碳储量在森林碳储量中所占比重越来越大。本研究选取天津平原地区不同林龄杨树人工林,通过野外调查和室内分析,估算了杨树人工林乔木、草本、凋落物和土壤碳储量。结果表明:人工杨树幼龄林、中龄林和成熟林的乔木生物量分别为43.65、56.18和121.59 t·hm-2,乔木各组分生物量所占比例在幼龄林和中龄林中表现为干根枝叶,在成熟林中表现为干枝根叶。3个林龄段杨树人工林的草本层生物量分别为4.60、2.92和1.58 t·hm-2,凋落物生物量分别为0.46、0.35和0.66 t·hm-2。人工杨树幼龄林、中龄林和成熟林生态系统碳储量分别为84.34、121.03和121.72 t C·hm-2,其中群落碳储量分别占25.85%、22.25%和46.58%,土壤碳储量分别占74.15%、77.75%和53.42%。群落碳储量中乔木碳储量分别为20.04、25.78和55.95 t C·hm-2;草本碳储量分别为1.63、1.05和0.57 t C·hm-2;凋落物碳储量分别为0.14、0.10和0.19 t C·hm-2。3个林龄段杨树人工林土壤有机碳储量(0~100 cm)依次为62.53、94.10和65.03 t C·hm-2,其中0~30 cm土壤有机碳储量所占比例分别为33.91%、37.64%和44.16%,随林龄的增加而增加。结果表明,杨树人工林生态系统碳储量随林龄的增加显著增加,而目前天津杨树人工林以幼龄林为主,未来天津杨树人工林存在巨大的碳储存空间。 相似文献
89.
不同年龄杜香-兴安落叶松林粗木质残体贮量及特征 总被引:4,自引:0,他引:4
以大兴安岭杜香-兴安落叶松林为对象,采用2类标准分析不同年龄林分粗木质残体(CWD)的物种组成、径级结构及腐烂等级,揭示CWD特征及贮量的变化。结果表明:Harmon标准计算的密度、体积和生物量为350~659株·hm-2、2.64~38.27m3·hm-2和1.13~8.52t·hm-2,分别比LTER标准高出52.07%~92.38%、17.44%~63.13%和16.88%~22.11%。随着林分年龄的增加,Harmon标准计算的CWD密度呈"U"型分布,体积和生物量均呈近似正态分布;LTER标准计算的CWD密度从中龄林开始逐渐上升,体积和生物量则逐渐降低。随着林分年龄的增加,2类标准计算的腐烂等级高的CWD密度、体积和生物量比例均逐渐增加,其中幼中龄林以Ⅰ-Ⅱ级腐烂为主,近成熟林以Ⅱ-Ⅲ级为主。群落由兴安落叶松和白桦构成,兴安落叶松CWD在数量、体积和生物量上均占76%以上。 相似文献
90.