[1]张娜,巩在武.西双版纳热带季雨林林冠层CO2浓度特征及其影响因素[J].水土保持研究,2018,25(04):181-188.
 ZHANG Na,GONG Zaiwu.Characteristic of CO2 Concentration of Canopy and Its Influencing Factors in Tropical Seasonal Rainforest in Xishuangbanna, China[J].Research of Soil and Water Conservation,2018,25(04):181-188.
点击复制

西双版纳热带季雨林林冠层CO2浓度特征及其影响因素

《水土保持研究》[ISSN:1005-3409/CN:61-1272/P] 卷: 25 期数: 2018年04期 页码: 181-188 栏目: 出版日期: 2018-06-13
Title:
Characteristic of CO2 Concentration of Canopy and Its Influencing Factors in Tropical Seasonal Rainforest in Xishuangbanna, China
作者:
张娜1,2, 巩在武1
1. 南京信息工程大学 法政学院, 南京 210044;
2. 山西省阳泉市气象局, 山西 阳泉 045000
Author(s):
ZHANG Na1,2, GONG Zaiwu1
1. School of Low & Public AFFairs, Nanjing University of Information Science & Technology, Nanjing 210044, China;
2. Meteorological Bureau of Yangquan City, Shanxi Province, Yangquan, Shanxi 045000, China
关键词:
热带季雨林林冠层CO2浓度影响因素
Keywords:
tropical seasonal rainforestcanopyCO2 concentrationinfluencing factors
分类号:
S718
摘要:
根据2015年西双版纳热带季节雨林群落冠层植物表面温度以及林冠上、林冠下的气温资料,对热带季节雨林林冠层CO2浓度特征及其影响因素进行了分析。结果表明:(1)近地层地温呈现正弦变化趋势;深层地温相对稳定,随深度增加地温日变幅减小;地温峰值出现时刻随深度增加而呈现滞后现象;地温季节差异明显,平均地温在雨季较高,雾凉季较低,干热季居中。(2)西双版纳热带季节雨林CO2浓度表现出明显的日变化、季节变化和林冠上下差异。在日尺度上,林冠上方的CO2浓度时间变化曲线为“单峰型”,林内近地层CO2浓度时间变化曲线为“双峰型”;在季节尺度上,林冠上方和林内近地层CO2浓度均呈现雨季低、干季高的特点,并且林冠上方CO2浓度低于林内近地层CO2浓度。(3)热带季节雨林土壤呼吸存在明显的日变化规律,随时间变化表现为单峰型,且峰值出现的时间在14:00左右,对于季节变化规律,在7—8月份达到峰值,8月份以后,土壤呼吸急剧下降,在12月份最低。(4)不同季节热带季节雨林土壤呼吸、CO2浓度均与林冠温度的指数关系达到了极显著水平(p<0.01),且指数模型的决定系数最大,故指数模型的拟合效果最好。(5)林冠上方CO2浓度与光合有效辐射之间皆表现出正相关,随着光合有效辐射的增强,CO2浓度相应地升高;林内近地层CO2浓度与光合有效辐射之间的正相关关系较林冠上方强,地温与林冠上方CO2浓度和林内近地层CO2浓度均没有显著的相关性(p>0.05)。林内近地层CO2浓度与土壤温度以及土壤呼吸的相关系数为正,土壤呼吸可以认为是影响和控制近地层CO2浓度的主要因子。
Abstract:
Based on the observation data in 2015, we analyzed the influencing factors of CO2 concentration of canopy in tropical seasonal rainforest in Xishuangbanna, China. The results showed that: (1) the diurnal variation of soil temperature in near-surface soil layer demonstrated a sine trend, while it was relatively stable in the deeper soil layers; diurnal change rate of soil temperature decreased with the increase of soil depth, the occurrence time of the peak of soil temperature presented the hysteresis with the increase of soil depth, seasonal difference of soil temperature was significant, the mean soil temperature was higher in the rain season, it was lower in the cold season, it was the medium in the dry and hot season; (2) daily and seasonal CO2 concentrations in tropical seasonal rainforest showed the significant difference in canopy, on the daily scale, CO2 concentration above the canopy showed the unimodal type, and CO2 concentration beneath the canopy showed the bimodal pattern; on seasonal scale, CO2 concentration above canopy was higher than that beneath the canopy; (3) the daily soil respiration showed the unimodal type, and the peak occurred at 14:00; the soil respiration reached to the peak in July, it sharply declined after July, and it was lowest in December; (4) the exponential model can be used to describe the relationship between soil respiration, CO2 concentration and canopy temperature (p<0.01); (5) CO2 concentrations above and beneath the canopy were positively related to photosynthetically active radiation, and the related coefficients beneath the canopy were higher than those above canopy. There was a positive correction between CO2 concentration and soil respiration, thus, soil respiration can be regarded as the mainly influencing factor on CO2 concentration in Xishuangbanna, China.

参考文献/References:

[1] 周玉荣,于振良,赵士洞.我国主要森林生态系统碳贮量和碳平衡[J].植物生态学报,2000,24(5):518-522.
[2] Pausch J, Kuzyakov Y. Carbon input by roots into the soil:Quantification of rhizodeposition from root to ecosystem scale.[J]. Global Change Biology,2018,24(1):1-12.
[3] Walker A P, Zaehle S, Medlyn B E, et al. Predicting long-term carbon sequestration in response to CO2 enrichment:How and why do current ecosystem models differ[J]. Global Biogeochemical Cycles, 2015,29(4):476-495.
[4] 肖强,肖洋,欧阳志云,等.重庆市森林生态系统服务功能价值评估[J].生态学报,2014,34(1):216-223.
[5] Yue K, Peng Y, Peng C, et al. Stimulation of terrestrial ecosystem carbon storage by nitrogen addition:a meta-analysis[J]. Scientific Reports, 2016,6:19895.
[6] 吴雅琼,刘国华,傅伯杰,等.森林生态系统土壤CO2释放随海拔梯度的变化及其影响因子[J].生态学报,2015,35(11):306-313.
[7] Walker T N, Garnett M H, Ward S E, et al. Vascular plants promote ancient peatland carbon loss with climate warming[J]. Global Change Biology, 2016,22(5):1880-1889.
[8] 李贵才,韩兴国,黄建辉,等.森林生态系统土壤氮矿化影响因素研究进展[J].生态学报,2015(7):148-156.
[9] Pries C E H, Schuur E A G, Natali S M, et al. Old soil carbon losses increase with ecosystem respiration in experimentally thawed tundra[J]. Nature Climate Change, 2016,6(2):214-218.
[10] Qin Y, Chen J, Yi S. Plateau pikas burrowing activity accelerates ecosystem carbon emission from alpine grassland on the Qinghai-Tibetan Plateau[J]. Ecological Engineering, 2015,84:287-291.
[11] 陈全胜,李凌浩,韩兴国,等.典型温带草原群落土壤呼吸温度敏感性与土壤水分的关系[J].生态学报,2015(4):175-180.
[12] 杨玉盛,陈光水,王小国,等.中国亚热带森林转换对土壤呼吸动态及通量的影响[J].生态学报,2015(7):156-162.
[13] 张红星,王效科,冯宗炜,等.黄土高原小麦田土壤呼吸对强降雨的响应[J].生态学报,2015(12):408-415.
[14] 王小国,朱波,王艳强,等.不同土地利用方式下土壤呼吸及其温度敏感性[J].生态学报,2015(5):290-298.
[15] Nagelkerken I, Connell S D. Global alteration of ocean ecosystem functioning due to increasing human CO2 emissions[J]. Proceedings of The National Academy of Sciences, 2015,112(43):13272-13277.
[16] 张方月,王清奎,于小军. CO2浓度升高和N沉降对中亚热带森林土壤呼吸的短期影响[J].生态学杂志,2015,34(6):1638-1643.
[17] 阿力木,阿巴斯,何清,等.肖塘地区夏季土壤CO2浓度日变化特征及影响因素[J].沙漠与绿洲气象,2016(2):63-69.
[18] Motte L G D L, Mamadou O, Beckers Y, et al. Rotational and continuous grazing does not affect the total net ecosystem exchange of a pasture grazed by cattle but modifies CO2, exchange dynamics[J]. Agriculture Ecosystems & Environment, 2018,253:157-165.
[19] 龙凤玲,李义勇,方熊,等.大气CO2浓度上升和氮添加对南亚热带模拟森林生态系统土壤碳稳定性的影响[J].植物生态学报,2014,38(10):1053-1063.
[20] 项文化,黄志宏,闫文德,等.森林生态系统碳氮循环功能耦合研究综述[J].生态学报,2015(7):307-314.
[21] 刘魏魏,王效科,逯非,等.全球森林生态系统碳储量,固碳能力估算及其区域特征[J].应用生态学报,2015,26(9):2881-2890.
[22] 周国逸,张德强,李跃林,等.长期监测与创新研究阐明森林生态系统功能形成过程与机理[J].中国科学院院刊,2017,32(9):1036-1046.
[23] 胡芳,杜虎,曾馥平,等.广西不同林龄喀斯特森林生态系统碳储量及其分配格局[J].应用生态学报,2017,28(3):721-729.
[24] Novick K A, Oishi A C, Ward E J, et al. On the difference in the net ecosystem exchange of CO2 between deciduous and evergreen forests in the southeastern United States[J]. Global Change Biology, 2015,21(2):827-842.
[25] 牛晓栋,江洪,张金梦,等.浙江天目山老龄森林生态系统CO2通量特征[J].应用生态学报,2016,27(1):1-8.
[26] 李银,陈国科,林敦梅,等.浙江省森林生态系统碳储量及其分布特征[J].植物生态学报,2016,40(4):354-363.
[27] Knauer J, Zaehle S, Reichstein M, et al. The response of ecosystem water-use efficiency to rising atmospheric CO2 concentrations:sensitivity and large-scale biogeochemical implications[J]. New Phytologist, 2017,213(4):1654-1666.
[28] 许文强,杨辽,陈曦,等.天山森林生态系统碳储量格局及其影响因素[J].植物生态学报,2016,40(4):364-373.
[29] 魏书精,罗碧珍,孙龙,等.森林生态系统土壤呼吸时空异质性及影响因子研究进展[J].生态环境学报,2013,22(4):689-704.
[30] García-Palacios P, Vandegehuchte M L, Shaw E A, et al. Are there links between responses of soil microbes and ecosystem functioning to elevated CO2, N deposition and warming:A global perspective[J]. Global Change Biology, 2015,21(4):1590-1600.

相似文献/References:

[1]王亚军,郁珊珊.西双版纳热带季雨林土壤呼吸变化规律及其影响因素[J].水土保持研究,2016,23(01):133.
 WANG Yajun,YU Shanshan.Soil Respiration and Impact Factors of Tropical Seasonal Rainforests in Xishuangbanna, Yunnan Province[J].Research of Soil and Water Conservation,2016,23(04):133.

备注/Memo

收稿日期:2018-01-10;改回日期:2018-01-29。
基金项目:国家自然科学基金资助项目:群体共识快速收敛:建模、实验及仿真分析研究(71571104)
作者简介:张娜(1987-),女,山西平定人,硕士研究生,工程师,主要从事大气气象学研究。E-mail:Zhang_nana1987@126.com
通讯作者:巩在武(1975-),男,教授,从事大气相互作用研究研究方向:群决策灾害管理。E-mail:zwgong26@163.com

更新日期/Last Update: 1900-01-01