干旱区不同土壤和作物灌溉量的无机碳淋溶特征实验研究

干旱区地理 ›› 2013, Vol. 36 ›› Issue (3): 450-456.

干旱区不同土壤和作物灌溉量的无机碳淋溶特征实验研究

陆晴^1,2，王玉刚¹，李彦¹，唐立松¹

（1 中国科学院新疆生态与地理研究所，荒漠与绿洲生态国家重点实验室，新疆乌鲁木齐 830011；2 中国科学院大学，北京 100049）

收稿日期:2012-09-01 修回日期:2012-11-19 出版日期:2013-05-25
通讯作者: 王玉刚，副研究员，硕士生导师. Email：wangyg@ms.xjb.ac.cn
作者简介:陆晴（1986-），女，江西高安人，硕士研究生，主要从事土壤无机碳淋溶研究. Email：luqing_0920@126.com
基金资助:
国家重点基础研究发展计划973项目资助（2009CB825102）；中科院知识创新工程重要方向项目（KZCX2-EW-QN-316）资助

A leaching experiment on inorganic carbon characteristics in the different soil salinity and irrigation in arid area

LU Qing^1,2，WANG Yu-gang¹，LI Yan¹，TANG Li-song¹

（1 State Key Laboratory of Desert and Oasis Ecology, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi 830011,Xinjiang, China; 2 Graduate University of Chinese Academy of Sciences, Beijing 100049, China）

Received:2012-09-01 Revised:2012-11-19 Online:2013-05-25

摘要/Abstract

摘要： 为探讨干旱区作物灌溉对盐碱土无机碳传输的影响，通过选择不同含盐量的土壤，即耕地土（F）、混合土（C）和原生荒漠土（D），分别种植水稻（R）和棉花（C），进行了一个生长季的淋溶实验，并定期收取且分析土壤淋溶液中的可溶性无机碳（DIC）含量。结果表明：（1）水稻处理无机碳的淋溶主要集中在秧苗分蘖期和幼穗发育期，而棉花处理则集中在花铃期和吐絮期；（2）不同含盐量土壤在同一灌溉量下，土壤含盐量越高，其淋溶过程得到的无机碳总量越大，最高约为8.4 g·m^-2·a^-1，最低仅约0.7 g·m^-2·a^-1；（3）同种土壤不同灌溉量，其水稻高于棉花，高出值范围为2.9～4.1 g·m^-2·a^-1；种植作物处理得到的无机碳总量均大于其相应对照处理的量（p＜0.05）。研究结果表明，土壤的盐含量及作物灌溉量对土壤无机碳淋溶有重要影响。

关键词: 无机碳, 淋溶, 耕地土, 混合土, 原生荒漠土

Abstract: Soil inorganic carbon is the most common form of C in arid and semiarid climate aras，transfer of dissolved inorganic carbon in soil through the hydrologic cycle is an important component of global carbon budgets，understanding the significance of soil dissolved inorganic carbon processes can enhance development of strategies to mitigate atmospheric carbon concentrations. In order to quantity the carbon loss character in soil by field irrigation，an leaching experiment was carried out in Fukang station of desert ecology in Xinjiang. This study measured inorganic carbon leaching loses from different soil salinity （farmland soil，composite soil and native desert soil） with rice and cotton growing to explore the inorganic carbon transport mechanism with different irrigation in the saline-alkali soil of arid zone. Each kind of soil had 7 experiments with rice and cotton growing，respectively. Moreover，there were 3 controls that did not plant any crop with rice and cotton growing，respectively. The irrigation of rice was 1 100 mm，and the cotton was 470 mm. The results showed as follows：（1） The leaching inorganic carbon in the soil with rice growing mainly occurred in the period of seeding tillering and panicle development，but with cotton growing that in the period of blooming and boll opening. The amount of leaching inorganic carbon in the farmland with rice growing was maximum in the period of seeding tillering，but the amount of leaching inorganic carbon in the farmland with cotton growing was maximum in the period of blooming and boll opening. （2） The total amount of leaching inorganic carbon was higher in high salinity soil than in low salinity soil with the same irrigation. The maximum value of leaching inorganic carbon was in DR-CK （the soil control treatment of native desert soil with rice growing） treatment （approximately 8.4 g·m^-2·a^-1），but the minimum value was in FC-CK (the control treatment of farmland soil with cotton growing) treatment （approximately 0.7 g·m^-2·a^-1） in the leaching experiment. （3） The total amount of leaching inorganic carbon in the same soil type was higher in rice growing than in cotton growing. The total amount of leaching inorganic carbon in FR （farmland soil with growing rice） treatment is 2.9 g·m^-2·a^-1 higher than in FC （farmland soil with cotton growing），and value in CR （composite soil with rice growing） is 4.1 g·m^-2·a^-1 higher than in CC (composite soil with cotton growing)，and with a 3.1 g·m^-2·a^-1 higher in DR （native desert soil with rice growing） than in DC （native desert soil with cotton growing）. The total amount of leaching inorganic carbon was higher in the soil with crops growing than their corresponding control treatments（p<0.05）. These conclusions indicate that soil salinity and irrigation are the important factors to affect quantity of leaching inorganic carbon.

Key words: inorganic carbon, leaching, farmland soil, composite soil, native desert soil

中图分类号:

S153.6.1

陆晴，王玉刚，李彦，唐立松. 干旱区不同土壤和作物灌溉量的无机碳淋溶特征实验研究[J]. 干旱区地理, 2013, 36(3): 450-456.

LU Qing，WANG Yu-gang，LI Yan，TANG Li-song. A leaching experiment on inorganic carbon characteristics in the different soil salinity and irrigation in arid area[J]. , 2013, 36(3): 450-456.

参考文献

1.SCHIMEL D S. Terrestrial ecosystems and the carbon cycle［J］. Global Change Biology，1995，1（1）：77-91.

2.许文强，陈曦，罗格平，等. 土壤碳循环研究进展及干旱区土壤碳循环研究展望［J］. 干旱区地理，2011，4（34）：614-620.

3.张杰，潘晓玲. 天山北麓山地-绿洲-荒漠生态系统净初级生产力空间分布格局及其季节变化［J］. 干旱区地理，2010，1（33）：78-86.

4.DIXOM R K，BROWN S，HOUGHTON R A. Carbon pools and flux of global forest ecosystems［J］. Science，1994，262（5144）：185-190.

5.HEIMANN M，REICHSTIN M. Terrestrial ecosystem dynamics and climate feedbacks［J］. Nature，2008，451（7176）： 289-292.

6.CHAPIN F S III，WOODWELL G M，RANDERSON J T，et al. Reconciling carbon-cycle concepts，terminology，and methods［J］. Ecosystems，2006，9（7）：1041-1050.

7.WILLIAM E E. Carbon dioxide fluxes in a semiarid environment with high carbonate soils［J］. Agricultural and Forest Meteorology，2003，116（1）：91-102.

8.赵哈林，李玉强，周瑞莲. 沙漠化对科尔沁沙质草地土壤呼吸速率及碳平衡的影响［J］.土壤学报，2009，46（5）：809-816.

9.李彦，许皓. 梭梭对降水的响应与适应机制——生理，个体与群落水平碳水平衡的整合研究［J］. 干旱区地理，2008，31（3）：313-323.

10.孙洪波，王让会，张慧芝，等. 新疆山地一绿洲一荒漠系统及其气候特征［J］. 干旱区地理，2005，28（2）：199-204.

11.汪业勖，赵士洞，牛栋. 陆地土壤碳循环的研究动态［J］. 生态学杂志，1999，18（5）：29-35.

12.CIAIS P，BORGES A V，ABRIL G， MEYBECK M，et al. The impact of lateral carbon fluxes on the European carbon balance［J］. Biogeosciences，2008，5（5）：1259-1271.

13.JANNSSENS I，FREIBAUER A，CIAIS P，et al. Europe’s biosphere absorbs 7 to 12% of European anthropogenic carbon emissions［J］. Science，2003，300（5625）：1538-1542.

14.杨继松，刘景双，于君宝，等.草甸湿地土壤溶解有机碳淋溶动态及其影响因素［J］. 应用生态学报，2006，17（1）：113-117.

15.SIEMENS J. The European carbon budget：a gap［J］. Science，2003，302（5651）：1681-1681.

16.WALMSLEY D C，SIEMENS J，KINDLER R，et al. Dissolved carbon leaching from an Irish cropland soil is increased by reduced tillage and cover cropping［J］. Agriculture， Ecosystems & Environment，2011，142（3）：393-402.

17.COLE J，PRAIRIE Y，CARACO N，et al. Plumbing the global carbon cycle：integrating inland waters into the terrestrial carbon budget［J］. Ecosystems ，2007，10（1）：172-85.

18.BATTIN TJ，LUYSSAERT S，KAPLAN LA，et al. The boundless carbon cycle［J］. Nature Geoscience，2009，2（9）：598-600.

19.于素华，杨守祥，刘春生，等. 水分淋洗下菜园土壤各形态锌的迁移转化特征［J］. 水土保持学报，2006，20（4）：31-33.

20.鲁如坤. 土壤农业化学分析方法［M］. 北京：中国农业科技出版社，2000：239-246．

21.WADA H， TSUCHIYA K，TAKAI Y. Leaching of substances from paddy soils：（Part 1） Leaching process of common inorganic substances［J］. Journal of the Science of Soil and Manure，Japan，1979，50（6）：511-516.

22.KATOH M，IWATA A，SHAKU I，et al. Impact of water percolation on leaching from an irrigated paddy field in Japan［J］. Soil Management，2003，19（4）：298-304（Erratum 20，1（2004））.

23.韩广轩，朱波，江长胜. 川中丘陵区水稻田土壤呼吸及其影响因素［J］. 植物生态学报，2006，30（3）：450-456.

24.KINDLER R，SIEMENS J，KAISER K，et al. Dissolved carbon leaching from soil is a crucial component of the net ecosystem carbon balance［J］. Global Change Biology，2010，17（2）：1167-1185.

25.SCHULZE E D，LUYSSAERT S，CIAIS P，et al. Importance of methane and nitrous oxide for Europe′s terrestrial greenhouse-gas balance ［J］. Nature Geoscience， 2009，2（12），842-850.

[1]	王洁, 李王成, 穆敏, 董亚萍. 冻融干湿交替下灰绿板岩矿质元素释放特征及释放模型[J]. 干旱区地理, 2022, 45(6): 1795-1804.
[2]	王琦，张恩和，师尚礼，刘青林，Keith Cameron. 陶瓷杯与蒸渗仪测定硝态氮和氨态氮淋溶的比较[J]. 干旱区地理, 2015, 38(2): 298-304.
[3]	王玉刚，王忠媛，李彦. 干旱区盐碱土剖面无机碳组分分布特征[J]. 干旱区地理, 2013, 36(4): 631-636.