Carbon accumulation and distribution in Pinus massoniana and Cunninghamia lanceolata mixed forest ecosystem in Daqingshan, Guangxi, China

Carbon accumulation and distribution were studied at three sampling plots in a 13-year-old mixed planatation of Pinus massoniana and Cunninghamia lanceolata in Daqingshan, Guangxi, China. The results showed that carbon content varied with tissues and tree species, but the total carbon content of Pinus massoniana was higher than that of Cunninghamia lanceolata. The average tissue carbon contents of Pinus massoniana were: wood (58.6%) > root (56.3%) > branch (51.2%) > bark (49.8%) > leaf (46.8%), while those of Cunninghamia lanceolata were: bark (52.2%) > leaf (51.8%) > wood (50.2%) > root (47.5%) > branch (46.7%). The carbon contents of the soil (at a depth of 60cm) ranged from 1.45% to 1.84% with an average of 1.70%. Carbon contents were higher in the surface soil (0–20cm) than in the deep layer (below 20cm). The average carbon contents were the highest for trees (51.1%), followed by litter (48.3%), shrubs (44.1%), and herbs (33.0%). The biomass of the trees in the three plots ranged from 85.35 t hm^-2 to 101.35 t hm^-2 with an average of 93.83 t hm^-2, in which 75.7%–82.6% was Pinus massoniana. The biomass of the understory was 2.10–3.95 t hm^-2 with an average of 2.72 t hm^-2, while the standing stock of ground litter was 5.49–7.91 t hm^-2 with an average of 6.75 t hm^-2. The carbon storage in the mixed plantation reached the maximum in the soil layer (69.02%), followed by vegetation (29.03%), and standing litter (1.82%). The carbon storage in the tree layer occupied 23.90% of the total ecosystem and 97.7% of the vegetation layer. Pinus massoniana accounted for 65.39% of the total carbon storage in the tree layer. Tissue carbon storage was directly related to the corresponding amount of biomass. Trunks had the highest carbon storage, accounting for 53.23% of the trees in Pinus massoniana and 55.57% in Cunninghamia lanceolata, respectively. Roots accounted for about 19.22% of the total tree carbon. The annual net productivity of the mixed plantation was 11.46 t hm^-2a^-1, and that of sequestered carbon was 5.96 t hm^-2a^-1, which was equivalent to fixing CO₂ of 21.88 t hm^-2a^-1. The plantation was found to be an important sink of atmospheric CO₂.     

Litterfall Production Along Successional and Altitudinal Gradients of Subtropical Monsoon Evergreen Broadleaved Forests in Guangdong, China

Evaluation of litterfall production is important for understanding nutrient cycling, forest growth, successional pathways, and interactions with environmental variables in forest ecosystems. Litterfall was intensively studied during the period of 1982–2001 in two subtropical monsoon vegetation gradients in the Dinghushan Biosphere Reserve, Guangdong Province, China. The two gradients include: (1) a successional gradient composed of pine forest (PF), mixed pine and broadleaved forest (MF) and monsoon evergreen broadleaved forest (BF), and (2) an altitudinal gradient composed of Baiyunci ravine rain forest (BRF), Qingyunci ravine rain forest (QRF), BF and mountainous evergreen broadleaved forest (MMF). Mean annual litterfall production was 356, 861 and 849 g m⁻² for PF, MF and BF of the successional gradient, and 1016, 1061, 849 and 489 g m⁻² for BRF, QRF, BF and MMF of the altitudinal gradient, respectively. As expected, mean annual litterfall of the pioneer forest PF was the lowest, but rapidly increased over the observation period while those in other forests were relatively stable, confirming that forest litterfall production is closely related to successional stages and growth patterns. Leaf proportions of total litterfall in PF, MF, BF, BRF, QRF and MMF were 76.4%, 68.4%, 56.8%, 55.7%, 57.6% and 69.2%, respectively, which were consistent with the results from studies in other evergreen broadleaved forests. Our analysis on litterfall monthly distributions indicated that litterfall production was much higher during the period of April to September compared to other months for all studied forest types. Although there were significant impacts of some climate variables (maximum and effective temperatures) on litterfall production in some of the studied forests, the mechanisms of how climate factors (temperature and rainfall) interactively affect litterfall await further study.     

鼎湖山南亚热带常绿阔叶林碳素积累和分配特征

研究了鼎湖山南亚热带常绿阔叶林 40 0多年林龄的锥栗 (Castanopsis chinensis)、黄果厚壳桂 (Crypto-carya concinna)和 50多年林龄的黄果厚壳桂、鼎湖钓樟 (Lindera chunii)两个群落碳素积累和分配特征。结果表明 ,两林分间植物碳素含量在不同器官和不同层中的分配格局均十分相似 ,总平均分别为 41 .980 %(锥栗、黄果厚壳桂群落 )和 40 .377% (黄果厚壳桂、鼎湖钓樟群落 )。锥栗、黄果厚壳桂群落生态系统碳总贮量为 2 4 4 .998t/ hm2 ,其中植被部分为 1 54.2 89t/ hm2 ,土壤为 89.1 2 8t/ hm2 ,地表凋落物层为 1 .581 t/ hm2。黄果厚壳桂、鼎湖钓樟群落植被碳总贮量为 84.1 51 t/ hm2。在两林分植被碳总贮量中 ,乔木层分别占了97.47% (锥栗、黄果厚壳桂群落 )和 98.0 4 % (黄果厚壳桂、鼎湖钓樟群落 ) ,而在乔木层碳总贮量中 ,干器官则分别占 47.93% (锥栗、黄果厚壳桂群落 )和 44.66% (黄果厚壳桂、鼎湖钓樟群落 )。锥栗、黄果厚壳桂群落植被碳年积累量为 3.1 4 9t/ (hm2· a) ,黄果厚壳桂、鼎湖钓樟群落植被碳年积累量则为 3.42 5 t/ (hm2· a)。     

中国天然林保护、生态恢复与可持续经营的理论与技术

全面总结了近年来中国在天然林保护与生态恢复的理论与技术实践方面所取得的研究进展。高度凝练出了天然林动态干扰与保育技术、典型退化天然林的生态恢复技术和天然林景观恢复与空间经营技术等三方面的创新成果,形成了天然林保护与生态恢复的理论与技术创新体系,对今后天然林保护、生态恢复与可持续经营进行了展望。     

不同生境三种杜鹃属植物花特征比较

生境影响植物花部特征的分化.为探究不同人为干扰强度生境是否影响杜鹃花特征分化和资源分配,以及不同颜色杜鹃花分布情况,该研究以百里杜鹃保护区高、中、低人为干扰强度生境的马缨杜鹃、迷人杜鹃和露珠杜鹃为实验材料,采用五点取样法统计不同生境杜鹃花的植株数量,游标卡尺测量花部特征,光学显微镜统计花粉数,海洋光谱仪测定花色的反射光...     

陆地生态系统植物多样性对矿质元素输入的响应

人类活动的加剧改变了陆地生态系统矿质元素(如氮、磷、钾等)循环的速度和方向,并且对生态系统的结构和功能也产生重要影响。如今,矿质元素输入量的改变及其产生的后续效应对陆地生态系统生物多样性的影响备受学者们的关注。从4个方面综述了全球氮沉降背景下主要矿质元素输入的改变对陆地植物多样性的影响及其机理:1)矿质营养元素限制的概念、确定方法以及与植物多样性的耦合关系;2)概述了氮、磷、钾等主要矿质元素输入对陆地植物多样性的影响:主要表现为负面效应;3)探讨了矿质元素输入影响植物多样性的可能机制,包括生态系统水平上的机制(如竞争排斥、酸化铝毒、物种入侵、同质性假说,间接诱导机制等)和植物个体水平上的机制(如元素失衡和环境敏感性增加等);4)根据目前研究现状,指出了已有研究的局限性,分析了未来可能的研究方向和重点。     

中华水韭对不同营养条件的生理生态响应

采用水培法,研究了不同营养条件对中华水韭叶片生理生化特性和光合荧光特性的影响。结果显示:随着营养液中氮、磷浓度的升高,中华水韭叶片的生理生化特性除叶绿素含量呈下降的变化趋势外,可溶性糖、丙二醛、脯氨酸含量、过氧化氢酶活性(CAT)均呈上升趋势,而过氧化物酶活性(POD)则呈先上升后下降的趋势;同时叶片光合荧光特性中除非光化学猝灭系数(qN)呈上升的趋势外,PSⅡ的最大量子产量(Fv/Fm)、有效量子产量(Yield)、光化学猝灭系数(qP)、最大潜在相对电子传递速率(Pm)以及快速光响应曲线初始斜率(α)和半饱和光强(Ik)均呈下降的趋势。研究表明,随着水体氮、磷浓度的升高,中华水韭在中度营养条件下(N 0.4mg·L~(-1)、P0.04mg·L~(-1))耐受性较好,但在高营养条件下(N 1.2mg·L~(-1)、P 0.12mg·L~(-1))耐受性较差,其渗透调节能力和抗氧化能力上升,但光合作用能力下降,抑制了中华水韭的正常光合生理活动,进而影响其生长,推测水体富营养化可能是造成中华水韭濒危的重要原因之一。     

Response of Litter Decomposition to Simulated N Deposition in Disturbed, Rehabilitated and Mature Forests in Subtropical China

The response of decomposition of litter for the dominant tree species in disturbed (pine), rehabilitated (pine and broadleaf mixed) and mature (monsoon evergreen broadleaf) forests in subtropical China to simulated N deposition was studied to address the following hypothesis: (1) litter decomposition is faster in mature forest (high soil N availability) than in rehabilitated/disturbed forests (low soil N availability); (2) litter decomposition is stimulated by N addition in rehabilitated and disturbed forests due to their low soil N availability; (3) N addition has little effect on litter decomposition in mature forest due to its high soil N availability. The litterbag method (a total of 2880 litterbags) and N treatments: Control-no N addition, Low-N: −5 g N m⁻² y⁻¹, Medium-N: −10 g N m⁻² y⁻¹, and High-N: −15 g N m⁻² y⁻¹, were employed to evaluate decomposition_. Results indicated that mature forest, which has likely been N saturated due to both long-term high N deposition in the region and the age of the ecosystem, had the highest litter decomposition rate, and exhibited no significant positive and even some negative response to nitrogen additions. However, both disturbed and rehabilitated forests, which are still N limited due to previous land use history, exhibited slower litter decomposition rates with significant positive effects from nitrogen additions. These results suggest that litter decomposition and its responses to N addition in subtropical forests of China vary depending on the nitrogen status of the ecosystem.     

鼎湖山苗圃和主要森林土壤CO2排放和CH4吸收对模拟N沉降的短期响应

研究了鼎湖山生物圈保护区苗圃(幼苗)、马尾松、混交林和季风常绿阔叶林(季风林)土壤CO2排放和CH4吸收的一些特征及其对模拟N沉降增加的响应.结果表明,土壤CO2日(白天)平均排放量的大小顺序为(平均值±标准误)苗圃(258±62mg·m-2·h-1)＞季风林(177±42 mg·m-2·h-1)＞马尾松林(162±39 mg·m-2·h-1)＞混交林(126±30 mg·m-2·h-1).土壤CH4日(白天)平均吸收量的大小顺序为马尾松林(-0.15±0.02 mg·m-2·h-1)＞季风林(-0.08±0.01 mg·m-2·h-1)＞混交林(-0.07±0.01 mg·m-2·h-1)＞苗圃(-0.05±0.01 mg·m-2·h-1).低N(50 kg N·hm-2·a-1)和中N(100kg N·hm-2·a-1)处理对苗圃、马尾松林和混交林样地土壤CO2日平均排放量的影响均不明显,高N(150 kg N·hm-2·a-1)处理对苗圃土壤CO2的日平均排放量也无显著影响,但倍高N(300kg N·hm-2·a-1)处理显著促进苗圃样地土壤CO2的排放.然而,所有N(低N、中N和高N)处理均显著促进季风林土壤CO2日平均排放量,且这种促进作用随N处理水平的升高而增加.N处理显著促进季风林和马尾松林土壤对CH4吸收速率,但对混交林土壤CH4吸收则无明显的影响.在苗圃样地,除倍高N外,N处理对土壤CH4吸收速率也无显著作用,但倍高N处理使苗圃土壤发生功能转变,即从CH4汇转变为CH4源.     

林下层植物在退化马尾松林恢复初期养分循环中的作用

以鼎湖山退化马尾松 (Pinusmassoniana)林恢复过程中林下层植物凋落物、分解和养分动态为对象 ,研究了林下层植物在退化马尾松林恢复初期养分循环中的作用。结果表明 ,林下层年凋落物量除在第 5年有所下降外均随时间逐年上升 ,但其增加速率随年份不同而异 ,总平均年增长速率为 3 8%。第 4年凋落物量为 0 .2 0 t· hm- 2 · a- 1,第 1 1年为 1 .1 7t·hm- 2·a- 1。凋落物养分元素平均浓度为 (% ) :N0 .95 ,P0 .0 4,K0 .5 7,Ca0 .1 3和 Mg0 .0 8,基本上以夏季和秋季最高冬春交替月份最低。第 1 1年凋落物各元素养分归还量为 (kg· hm- 2·a- 1) :N1 1 .1 0 ,P0 .47,K6.65 ,Ca1 .48和 Mg 0 .91。凋落物在分解过程中失重率呈直线模型变化 ,第 1年的分解速率为 3 1 % ,至试验结束时凋落物的残存量占起始量的 66%。在凋落物分解过程中 ,N和 P浓度随时间逐渐上升 ,但 N增加的速度较 P快 ,其余元素浓度均下降 ,但 K下降的速度最快。在凋落物分解过程中 ,N是唯一表现残留量呈先上升然后下降变化的元素。P的残留量变化与凋落物的失重率变化几乎一致。各元素在分解试验结束时残留量占起始量的百分比分别为 :N 90 % ,P 67% ,K 9% ,Ca 3 0 %和Mg 1 4%。可见 ,林下层凋落物在退化马尾松林恢复初期碳及其它营养元素循