Contents and output characteristics of dissolved carbon in water body of alpine forest headwater streams in rainfall season

doi:10.7523/j.issn.2095-6134.2017.04.014

Abstract

Abstract: Dissolved carbon flow from water in the alpine forest headwater streams is one of the essential components of carbon flux. A study on dissolved carbon output with water flow in the alpine headwater streams was carried out in a typical alpine forest in the eastern Qinghai-Tibet Plateau in July 2015. The output characteristics of dissolved carbon with water flow were investigated in the catchment covering an area of 4.31 km². The results are given as follows. The maximum annual output rate of dissolved carbon in unit area catchment was 12.99×10³ kg·km^-2. The output rates of the unit area of catchment were 3.56×10^-2 g·m^-2·d^-1 for total carbon, 2.12×10^-2 g·m^-2·d^-1 for inorganic carbon, and 1.43×10^-2 g·m^-2·d^-1 for organic carbon in the alpine forest headwater streams. In contrast, the output rates of the unit area of stream were 2.01×10³ kg·m^-2·d^-1 for total carbon, 1.20×10³ kg·m^-2·d^-1 for inorganic carbon, and 0.81×10³ kg·m^-2·d^-1 for organic carbon. For streams with length greater than 30 m, total carbon and inorganic carbon concentrations were higher in stream source than at stream end, but organic carbon concentration showed the opposite. Contrarily, for streams with length less than 30 m, the concentrations of total carbon, inorganic carbon, and organic carbon had larger values at stream end than in stream source. These results suggest that the water flow in the alpine forest headwater streams leads to a large amount loss of dissolved carbon. This study provides a new idea for further studies on the ecological linkage between the land system and water body under the climate change.

Key words: forest headwater streams, dissolved carbon loss, catchment, carbon source and sink

CLC Number:

S715-3

ZHANG Yu, YANG Wanqin, TAN Bo, LIANG Ziyi, WU Fuzhong. Contents and output characteristics of dissolved carbon in water body of alpine forest headwater streams in rainfall season[J]. , 2017, 34(4): 515-520.

References

[1] 王云琦，王玉杰. 森林溪流水质的研究进展[J]. 水土保持研究，2003，10(4)：242-246.
[2] 张川，杨万勤，岳楷，等. 高山森林溪流冬季不同时期凋落物分解中水溶性氮和磷的动态特征[J]. 应用生态学报，2015，26(6)：1 601-1 608.
[3] Mwndoza-lera C, Larranga A, Perez J, et al. Headwater reservoirs weaken terrestrial-aquatic linkage by slowing leaf-litter processing in downstream regulated reaches[J]. River Research and Applications, 2012, 28(1): 13-22.
[4] 石福臣，李凤英，蔡体久，等. 不同森林溪流群落类型溪流水化学特征的季节动态[J]. 应用生态学报，2008，19(4)：717-722.
[5] 邓红兵，肖宝英，代力民，等. 溪流粗木质残体的生态学研究进展[J]. 生态学报，2002，22(1)：87-93.
[6] 马晓哲，王铮. 土地利用变化对区域碳源汇的影响研究进展[J]. 生态学报，2015，35(17)：5 898-5 907.
[7] 黄麟，邵全琴，刘纪远. 江西省森林碳蓄积过程及碳源/汇的时空格局[J]. 生态学报，2012，32(10)：3 010-3 020.
[8] 张修玉，许振成，宋巍巍，等. 森林碳循环研究方法及其存在问题分析[J]. 环境科学与技术，2010，33(6)：225-230.
[9] 刘帅，陈玥希，孙辉，等. 西南亚高山-高山海拔梯度上森林土壤水溶性有机碳时间动态[J]. 西北林学院学报，2015，30(1)：33-38.
[10] 杨丽丽，王彦辉，杜敏，等. 六盘山典型森林伴随降水的总有机碳(TOC)通量变化特征[J]. 生态学报，2014，34(21)：6 297-6 308.
[11] 张慧玲，杨万勤，汪明，等. 岷江上游高山森林溪流木质残体碳、氮和磷贮量特征[J]. 生态学报，2016，36(7)：1 967-1 974.
[12] 张川，杨万勤，张慧玲，等. 岷江上游高山森林溪流非木质残体现存量与碳储量及其分配特征[J]. 生态环境学报，2014，23(9)：1 509-1 514.
[13] Hansell D A, Kadko D, Bates N R. Degradation of terrigenous dissolved organic carbon in the western Arctic Ocean[J]. Science, 2004, 304(5 672): 858-861.
[14] 熊浩仲，王开运，杨万勤. 川西亚高山冷杉林和白桦林土壤酶活性季节动态[J]. 应用与环境生物学报，2004，10(4)：416-420.
[15] 何伟，吴福忠，杨万勤，等. 雪被斑块对高山森林两种灌木凋落叶质量损失的影响[J]. 植物生态学报，2013，37(4)：306-316.
[16] 李俊，杨万勤，李晗，等. 长江上游高山森林小溪流磷输出及其汇流特征[J]. 环境科学学报，2015，35(4)：1 136-1 142.
[17] 徐李亚，杨万勤，李晗，等. 长江上游高山森林林窗对凋落物分解过程中可溶性碳的影响[J]. 长江流域资源与环境，2015，24(5)：882-891.
[18] Battin Y J, Luyssaert S, Kaplan L A, et al. The boundless carbon cycle[J]. Nature Geoscience, 2009, 2(9): 598-600
[19] Zhou W J, Zhang Y P, Schaefer D A, et al. The role of stream water carbon dynamics and export in the carbon balance of a tropical seasonal rainforest, Absorption in an Aquatic Plant [J]. Doboku Gakkai Ronbunshuu G, 2005, 42: 469-474.
[20] 魏秀国. 珠江流域河流碳通量与流域侵蚀研究[D]. 广州：中国科学院广州地球化学研究所，2003.
[21] 张连凯，覃小群，杨慧，等. 珠江流域河流碳输出通量及变化特征[J]. 环境科学，2013，34(8)：3 025-3 034.
[22] Enari K, Kohama A, Tamaoki S, et al. Evaluation of annual amount of nitrogen and phosphorus absorption in an aquatic plant (zizania latifolia)[J]. Doboku Gakkai Ronbunshuu G, 2011, 42: 469-474.
[23] 张永领. 河流有机碳循环研究综述[J]. 河南理工大学学报，2012，31(3)：344-351.
[24] 叶琳琳，孔繁翔，史小丽，等. 富营养化湖泊溶解性有机碳生物可利用性研究进展[J]. 生态学报，2014，34(4)：779-788.
[25] Patel N, Mounier S, Guyot JL, et al. Fluxes of dissolved and colloidal organic carbon, along the Purus and Amazonas rivers (Brazil)[J]. Science of the Total Environment, 1999, 229(1/2): 53-64.
[26] 高全洲，陶贞. 河流有机碳的输出通量及性质研究进展[J]. 应用生态学报，2003，14(6)：1 000-1 002.
[27] Lloret E, Dessert C, Gaillardet J, et al. Comparison of dissolved inorganic and organic carbon yields and fluxes in the watersheds of tropical volcanic islands, examples from Guadeloupe (French West Indies)[J]. Chemical Geology, 2011, 280(1/2): 65-78.
[28] Rantakari M, Mattsson T, Kortelainen P, et al. Organic and inorganic carbon concentrations and fluxes from managed and unmanaged boreal first-order catchments[J]. Science of the Total Environment, 2010, 408: 1 649-1 658.
[29] 张川，杨万勤，岳楷，等. 高山森林溪流凋落叶冬季水溶性碳含量动态[J]. 环境科学学报，2016，36(3)：792-801.