杉木幼林土壤垂直剖面CO2通量对土壤增温的响应

研究土壤垂直剖面CO_2通量的分布是了解生态系统碳循环的重要环节.本研究以亚热带杉木幼林为研究对象,于2014年5月至2015年5月,采用气井法结合Fick扩散法则和扩散系数模型计算15、30、60 cm各层土壤的CO_2通量,探讨增温对其影响.结果表明:杉木幼林土壤增温影响可至60 cm土层,增温显著降低了各层土壤含水量(p0.05).增温显著增加了杉木幼林土壤CO_2通量(p0.05),深层尤为显著;增温处理(W)后15、30、60 cm土层的土壤CO_2通量年均值分别为1.35、0.73和0.36μmol·m-2·s-1,比对照(CT)相应增加了36%、180%和192%,并且增温显著影响了土壤基础呼吸速率F10和土壤温度敏感性指数Q10(p0.05).土壤温度和含水量能够共同解释各层土壤CO_2通量季节变异的62%~87%,且增温处理后其R2增大.双因子模型拟合结果优于单因子模型.增温能够增加土壤呼吸,对全球大气CO_2浓度升高具有正反馈作用.     

Effects of two forest types on the dynamics of four base cations along with rainfall partitioning in middle subtropical forests北大核心CSCD

盐基离子随穿透雨和树干茎流的迁移成为森林元素输入的重要组成部分.在迁移过程中,冠层淋溶、树干冲刷等改变了盐基离子含量,而不同林型的林冠特征、树皮性质等存在差异,因此盐基离子含量在不同林型中可能存在差异对米槠次生林和杉木人工林穿透雨、树干茎流进行为期4年的监测,对比研究4种盐基离子(K+、Ca2+、Na+、Mg2+)浓度和输入量的动态特征.结果显示:(1)米槠次生林树干茎流Ca2+、Mg2+浓度显著低于杉木人工林而K+浓度显著高于杉木人工林;穿透雨除Na+浓度外均为米槠次生林显著高于杉木人工林.穿透雨和树干茎流Na+浓度林型差异不显著.(2)两种林型盐基离子季节动态变化基本一致,在雨季旱季各有一个峰值,雨季浓度普遍低于旱季.米槠次生林盐基离子浓度稳定性普遍高于杉木人工林.(3)分析盐基离子浓度与降雨强度的关系发现:Ca2+、K+、Mg2+浓度随雨量级的增加而降低,Na+浓度随雨量级的增加而增加.(4)观测期间米槠次生林穿透雨累计输入Ca2+、K+、Mg2+和Na+总量分别为47.97、35.17、7.15和12.94 kg/hm2,树干茎流累计输入Ca2+、K+、Mg2+和Na+总量分别为11.38、6.21、1.54和3.00 kg/hm2;杉木人工林穿透雨累计输入Ca2+、K+、Mg2+和Na+总量分别为47.24、26.63、6.43和11.55 kg/hm2,树干茎流累计输入Ca2+、K+、Mg2+和Na+总量分别为4.11、1.20、0.50和0.83 kg/hm2.米槠次生林的林内雨盐基离子输入量大于杉木人工林.总体而言,米槠次生林比杉木人工林有更高的养分输入,能更好地维持生态系统养分的供应;上述结果有助于进一步认识森林物质随水文过程的流动,可为人工林经营管理提供一定科学基础数据.(图6表1参36)     

湿润亚热带森林锰、铜、锌随降雨分配的迁移动态特征

为探究森林生态系统中重金属随降雨分配迁移的特征,连续观测两年降雨,对比分析Mn、Cu、Zn在穿透雨、树干茎流、地表径流中浓度、输出量、变异情况的差异,并讨论了重金属迁移规律的产生机制.结果表明,林型对雨水的再分配有较大影响.米槠次生林树干茎流水量极显著大于杉木人工成熟林,故前者树干茎流的重金属浓度低于后者;对于林内雨,穿透雨中重金属浓度在米槠次生林（阔叶林）更高,树干茎流中重金属浓度则在杉木人工成熟林（针叶林）更高.整体而言,林内雨的重金属浓度在旱季高于雨季,表现出明显的季节变化;林型对地表径流的影响较复杂,体现在植被类型、林龄、土壤理化性质等方面.本研究中,Mn随地表径流的输出量在米槠次生林显著大于其它3种林型;Zn在较大林龄的米槠次生林和杉木人工成熟林有更大的输出量;降雨分配过程中3种元素的浓度变异情况有所不同,表现为Mn变异最大,Zn次之,Cu最稳定.本研究结果对进一步了解森林生态系统中重金属的迁移特征提供了依据.     

Effects of soil warming and nitrogen deposition on leaf and soil stoichiometric characteristics of Cunninghamia lanceolata saplings北大核心CSCD

Warming and nitrogen deposition directly or indirectly affect the plant-soil element cycle under global change. To examine the effects of warming and nitrogen deposition on leaf and soil carbon (C), nitrogen (N), phosphorus (P) contents, and their stoichiometric ratios in Cunninghamia lanceolata saplings, four types of treatments were assigned: control (CT), warming (W, + 4 ºC), nitrogen deposition (N, 40 kg ha-1 a-1), and warming + nitrogen deposition (WN) treatments. The results showed that: (1) compared with CT, W treatment significantly decreased leaf P content by 54.54% and increased leaf C/P and N/P by 85.26% and 83.39%, respectively; WN treatment significantly decreased leaf C content and P content by 1.99% and 51.03%, respectively, but increased the leaf C/P by 68.01% with no significant differences in leaf N content among treatments. The leaf N/P ratio of each treatment was less than 10, but that of the W and WN treatments were closer to 10 than that of the CT treatment. Meanwhile, W and WN treatments significantly increased tree height. (2) No significant differences were observed in soil total carbon (TC), total nitrogen (TN), and total phosphorus (TP) contents among treatments. Compared with CT, W treatment significantly decreased soil C/N by 4.09%, while neither W nor WN treatment affected soil C/P and N/P. W treatment increased the available soil content compared to CT treatment. (3) The correlation analysis showed that leaf N content was significantly negatively correlated with soil C/N in the CT treatment; in the W treatment leaf N content and N/P were significantly positively correlated with soil TN and TP content, respectively. Leaf N content was significantly negatively correlated with soil TC and TN in the N treatment, and leaf contents had no significant correlation with soil C, N, and P contents or their stoichiometric characteristics in the WN treatment. This study showed that N limitation still exists in C. lanceolata saplings. Warming and the interaction between warming and nitrogen deposition could alleviate N limitation and promote the growth of C. lanceolata. © 2022 Authors. All rights reserved.     

中亚热带不同森林类型对地表径流磷动态的影响

磷是亚热带森林生产力的主要限制因子之一，其随地表径流的输出是森林磷流失的重要途径，且可能受不同森林类型的显著调控，但缺乏必要关注.着眼于中亚热带不同类型森林的地表径流，分析米槠(Castanopsis carlesii)人工幼林、杉木(Cunninghamia lanceolata)人工幼林、米槠次生林及杉木人工成熟林对地表径流总磷浓度及输出的影响，为深入认识亚热带森林磷迁移过程及有效森林经营提供一定科学基础数据.结果显示：(1)不同森林类型的地表径流产流量大小为米槠人工幼林(1 506.06±5.18 m³/hm²)>杉木人工幼林(971.56±2.88 m³/hm²)>米槠次生林(552.85±2.45 m³/hm²)>杉木人工成熟林(468.83±1.81 m³/hm²);(2)不同森林类型地表径流总磷浓度之间存在显著差异，表现为米槠次生林(0.239±0.093 mg/L)>杉木人...     

Effects of warming on leaf non-structural carbohydrates and carbon and nitrogen isotopes of Cunninghamia lanceolata saplings during different seasons北大核心CSCD

To reveal the response of non-structural carbohydrates (NSC) and carbon and nitrogen isotopes in plant leaves to global warming, we conducted soil warming experiments in the Fujian Sanming Forest Ecosystem and Global Change National Observation and Research Station of China. We designed two treatments: control (CT) and warming (W; cable heating, +4 ℃). Heating cables were installed 20 cm from each other at a depth of 10 cm and were heated in March 2016. In this study, Cunninghamia lanceolata saplings were used to analyze seasonal changes in leaf non-structural carbohydrates, and carbon and nitrogen isotopes. The results showed that (1) warming significantly reduced the soluble sugar, starch, and NSC content of leaves in spring but without any significant difference during other seasons. (2) Leaf δ13C increased significantly in spring and winter after warming, whereas leaf δ15N did not change significantly. (3) No significant correlation was observed between leaf δ13C, δ15N, or NSC content during the warming treatment, but a negative correlation was observed between leaf δ15N, δ13C, and sugar to starch ratio. A positive correlation between leaf δ15N and starch content was identified. In summary, when temperature increases, plants adjust the NSC content during different seasons for osmotic regulation, change the characteristics of the nutrient cycle, and alter the plant water and nutrient use strategies to maintain plant growth. In the future, we should further study the seasonal variation characteristics of NSC content and isotopes and the relationship between NSC content and the carbon and nitrogen cycles in plants under the context of long-term warming. © 2022 Science Press. All rights reserved.