近70年来黄土高原典型植物δ13C值变化研究

doi:10.17521/cjpe.2005.0037

摘要/Abstract

摘要：

对黄土高原地区 4种典型C3 植物狼牙刺 (Sophoraviciifolia) 、辽东栎 (Quercusliaotungensis) 、虎榛子 (Os tryopsisdavidiana) 和酸枣 (Zizyphusjujubavar.spinosa) 样品稳定性碳同位素组分 (δ¹³ C) 进行分析, 研究了从 2 0世纪 30年代至今近 70年中不同年代植物δ¹³ C值的变化。结果表明, 在近 70年中, 4种植物δ¹³ C值变化范围为- 2 5.0 5‰~ - 2 9.75‰, 平均值为 - 2 7.0 4‰。 4种植物叶片δ¹³ C值均呈下降趋势, 表明随气候环境变化, 近 70年4种植物的水分利用效率 (WUE) 均呈降低趋势。但不同植物叶片δ¹³ C值下降幅度不同 :狼牙刺和辽东栎叶片δ¹³ C值下降非常明显, 虎榛子叶片δ¹³ C值下降也较明显, 而酸枣叶片δ¹³ C值下降不明显。 4种植物δ¹³ C值的降低率分别为 14.6 5 %、14.4 6 %、11.99%和 2.4 4 %, 说明不同植物对气候环境因子的敏感性不同, 具有不同的适应环境变化的策略, 酸枣是 4种植物中耐旱能力较强, WUE较高的物种。

关键词: 碳同位素组分, C₃植物, 黄土高原, 气候环境

Abstract:

Increases in the world population combined with accelerated rates of industrialization has led to increases in green-house gases in the atmosphere, particularly CO₂ concentrations, resulting in an increase in global temperatures. Water use efficiency (WUE) is a measure of a plant’s performance growing under different environmental conditions, and is an important index that reflects a plant’s ability to adapt to climate change. Carbon isotopes provide a long-term, integrative measure of WUE with high δ¹³C indicating high WUE. Stable carbon isotopes have become an important technique in ecophysiology studies in recent years for analyzing the long-term WUE of plants growing in different habits and to study the response of plant to different environmental variables, such as light intensity, precipitation, temperature, CO₂, and mineral nutrient availability. The Loess Plateau is a critical ecosystem in China but suffers from serious soil erosion problems. Water is the most important limiting environmental factor in this region and research on plant WUE responses to climate change is of particular relevance. However, only a few studies have examined foliar δ ¹³C value in response to climate change in this ecosystem. Four C₃ plants that are typical of the Loess Plateau were chosen as materials: Quercus liaotungensis, a tree, and three species of shrubs, Ostryopsis davidiana, Zizyphus jujuba var. spinosa and Sophora viciifolia. Dry leaves were collected from herbarium specimens collected over a 70 year period from the 1930’s to 2002. A total of 25 samples from about 160 plant specimens were analyzed that were collected from the hilly and gully region of the Plateau ranging from the northern Tongchuan to the southern Yanan. The carbon isotope composition (δ¹³C) of leaves was analyzed using a MAT-251 mass-spectra photometer. The results showed that the variation in the δ ¹³C values differed among the species tested: :Ostryopsis davidiana (-25.05‰ to -29.75‰) > Quercus liaotungensis (-25.51‰ to -29.20‰) > Sophora viciifolia (-25.12‰ to -28.80‰) > Zizyphus jujuba var. spinosa (-26.69‰ to -28.69‰). The mean δ13C value of four plants was -27.04‰ ranging from -25.05‰ to -29.75‰. Comparing the mean δ¹³C value among four species in the age of 30, 50, 70, 80 and the year 2002 indicated that the following order of Sophora viciifolia (-26.54‰) > Ostryopsis davidiana (-26.99‰) > Quercus liaotungensis (-27.14‰) > Zizyphus jujuba var. spinosa (-27.49‰) is obtained. A decrease in the foliar δ¹³C value with time was found in all four species, indicating that the WUE of the four species all declined over time. However, the decrease in foliar δ ¹³C values varied among the four species with significant decreases measured in two species, Sophora viciifolia and Quercus liaotungensis, a strong but not significant decrease in the leaves of Ostryopsis davidiana, and only a slight decrease in Zizyphus jujuba var. spinosa. The decrease in the δ ¹³C values in the four species were: 14.65‰, 14.46‰, 11.99‰ and 2.44‰, respectively. It was shown that different species have different sensitivities to climate change, and Zizyphus jujuba var. spinosa was the most drought-tolerant of the four species with a high WUE.

Key words: Carbon isotope composition, C₃ plant, Loess Plateau, Climate changes

郑淑霞, 上官周平. 近70年来黄土高原典型植物δ¹³C值变化研究. 植物生态学报, 2005, 29(2): 289-295. DOI: 10.17521/cjpe.2005.0037

ZHENG Shu-Xia, SHANGGUAN Zhou-Ping. VARIATION IN THE δ¹³ C VALUE OF TYPICAL PLANTS OF LOESS PLATEAU OVER THE LAST 70 YEARS. Chinese Journal of Plant Ecology, 2005, 29(2): 289-295. DOI: 10.17521/cjpe.2005.0037

导出引用管理器 EndNote|Ris|BibTeX

链接本文: https://www.plant-ecology.com/CN/10.17521/cjpe.2005.0037

https://www.plant-ecology.com/CN/Y2005/V29/I2/289

图/表 4

参考文献 24

[1]	Condon G, Richards A, Rebetzke J, Farquhar D (2002). Improving intrinsic water-use efficiency and crop yield. Crop Science, 42,122-131. PMID
[2]	Duquesnay A, Breda N, Stievenard M, Dupouey JL (1998). Changes of tree-ring δ ¹³C and water use efficiency of beech in north-eastern France during the past century . Plant, Cell and Environment, 21,565-572. DOI URL
[3]	Farquhar GD, Ehleringer JR, Hubick KT (1989). Carbon isotope discrimination and photosynthesis. Annual Review of Plant Physi-ology and Plant Molecular Biology, 40,503-507.
[4]	Houghton JT, Jenkins GJ, Ephraums JJ (1990). Climate Change:the IPCC Scientific Assessment. Ambridge University Press, Cambridge,1-15.
[5]	Jiang GM (蒋高明), Huang YX (黄银晓), Wan GJ (万国江), Chen YC (陈亚财), Geng LN (耿龙年), Zeng YQ (曾毅强), Wang HW (王宏卫) (1997). A study on the δ ¹³C values of tree rings and their indicative functions in revealing atmospheric CO ₂ changes in North China. Acta Phytoecologica Sinica (植物生态学报), 21,155-160. (in Chinese with English abstract)
[6]	Li B (李斌), Zhang JT (张金屯) (2003). Analysis of relation-ships between vegetation and climate variables in Loess Plateau. Acta Ecologica Sinica (生态学报), 23,82-89. (in Chinese with English abstract)
[7]	Lin ZF (林植芳) (1990). Application of stable carbon isotope in plant physioecology. Plant Physiology Communications (植物生理学通讯), 3,1-6. (in Chinesewith English abstract).
[8]	Lin ZF (林植芳), Lin GZ (林桂珠), Kong GH (孔国辉), Zhang HB (张鸿彬) (1995). Effect of growth irradiation on stable carbon isotope ratio, intercellular CO₂ concentration and water-useefficiency of two wood yplant in subtropical natural forest. Journal of Tropical and Subtropical Botany (热带亚热带植物学报), 3,77-82. (in Chinese with English abstract)
[9]	Liu QM (刘启明), Wang SJ (王世杰), Piao HC (朴河春), Ouyang ZY (欧阳志远) (2002). Soil organic matter changes of turnover ecosystems traced by carbon isotopes. Journal of Environmental Science (环境科学), 23,75-78. (in Chinese with English abstract)
[10]	O'Leary MH (1988). Carbon isotopes in photosynthesis. Bio Science, 38,328-336.
[11]	Polley HW, Johnson HB, Marino BD, Mayeux HS (1993). Increase in C ₃ plant water-use efficiency and biomass over glacial to present CO ₂ concentration . Nature, 361,61-63. DOI URL
[12]	Qin DH (秦大河) (2003). The fact, effect and measurement of climate change. Science Foundation of China (中国科学基金), 17,1-3. (in Chinese)
[13]	Saurer M, Siegenthaler U, Schweingruber F (1995). The climate-carbon isotope relationship in tree rings and significance of site conditions. Tellus, 47B,320-330.
[14]	Shangguan ZP (上官周平) (2000). Carbon isotope discrimination and water use efficiency in wheat under nitrogen nutrition and water stress conditions. Plant Nutrition and Fertilizer Science (植物营养与肥料学报), 6,345-348. (in Chinese with English abstract)
[15]	Shangguan ZP, Shao MA, Lei TW, Fan TL (2002). Runoff water management technologies for dryland agriculture on the Loess Plateau. International Journal of Sustainable Development and World Ecology, 9,341-350. DOI URL
[16]	Su B (苏波), Han XG (韩兴国), LiL H (李凌浩), Huang JH (黄建辉), Bai YF (白永飞), Qu CM (渠春梅) (2000). Responses of δ ¹³C value and water use efficiency of plant species to environmental gradients along the grassland zone of northeast China transect. Acta Phytoecologica Sinica (植物生态学报), 24,648-655. (in Chinese with English abstract)
[17]	Sun GC (孙谷畴), Lin ZF (林植芳), Lin GZ (林桂珠) (1993). The ¹³C/ ¹²C and water use efficiency of Pinus trees in subtropical plantation. Chinese Journal of Applied Ecology (应用生态学报), 4,325-327. (in Chinese with English abstract)
[18]	Wang GA (王国安), Han JM (韩家懋), Liu DS (刘东生) (2003). Studies on carbon isotope composition of C ₃ herbage plant in Loess Plateau of North China. Science in Chinese (Series D) (中国科学D辑), 33,550-556. (in Chinese)
[19]	Warren CR, McGrath Jf, Adams MA (2001). Water availability and carbon isotope discrimination in conifers. Oecologia, 127,476-486. DOI URL
[20]	Watson RH, Rodhe H, Oeschager H, Siegenthaler U (1990). Greenhouse gases and aerosols.In:Houghton JT, Oeschager H, Siegenthaler U eds. Change:the IPCC Scientific Assessment, Cambridge University Press, New York,1-40.
[21]	Wei MJ (魏明建), Zhao JB (赵景波), Zhang J (张静) (1999). The remnant stable isotope of modern plant in Loess Plateau.In:Zhang ZH (张宗祜), Shao SX (邵时雄), Chen Y (陈云), Wei MJ (魏明建), Shi DH (施德鸿), Shi JS (石建省) eds. The Geology Environments Evolvement with Renewing Century and Trend Estimate of Existing Environment Change with Futurein North China (中国北方晚更新世以来地质环境演化及未来生存环境变化趋势预测). The Geological Publishing House, Beijing,254-262. (in Chinese)
[22]	Yan CR (严昌荣), Han XG (韩兴国), Chen LZ (陈灵芝), Huang JH (黄建辉), Su B (苏波) (1998). The interspecific and temporal-spatial variation of leaf δ ¹³C value of plants in warm temperate deciduous broad-leaved forests. Acta Botanica Sinica (植物学报), 40,853-859. (in Chinese with English abstract)
[23]	Zheng FY (郑凤英), Peng SL (彭少麟), Zhao P (赵平) (2001). Changes in stomatal density and intrinsic water use efficiency of two Trema species over the last century. Acta Phytoecologica Sinica (植物生态学报), 25,405-409. (in Chinese with English abstract)
[24]	Ziegler H (1995). Stable isotopes in plant physiology and ecology.In:Behnke HD, Lüttge U,Esser K,Kadereit JW,Runge Meds. Progressin Botany, Vol.56. Berlin, Heidel berg, Germany, Springer_Verlag,1-24.

植物名称 Name	科 Family	叶片碳同位素组分δ¹³C Leaf carbon isotope composition (‰)
		20世纪 20th century				2002年 Year of 2002	平均值 Average	2002年与30年代相比降低率 Dropping rate from 30's to 2002 (%)
				30年代 30's	50年代 50's	2002年 Year of 2002	平均值 Average	2002年与30年代相比降低率 Dropping rate from 30's to 2002 (%)	70年代 70's	80年代 80's
辽东栎 Quercus liaotungensis	壳斗科 Fagaceae	-25.51	-27.06	-25.92	-27.62	-29.20	-27.14	14.46
虎榛子 Ostryopsis davidiana	桦木科 Betulaceae	-26.57	-26.71	-26.99	-26.93	-29.75	-26.99	11.99
酸枣 Zizyphus jujuba var. spinosa	鼠李科 Rhamnaceae	-	-27.07	-26.69	-28.18	-27.73	-27.49	2.44^**
狼牙刺 Sophora viciifolia	豆科 Leguminosae	-25.12	-26.40	-26.01	-	-28.80	-26.54	14.65

植物名称 Name	科 Family	叶片碳同位素组分δ¹³C Leaf carbon isotope composition (‰)
		20世纪 20th century				2002年 Year of 2002	平均值 Average	2002年与30年代相比降低率 Dropping rate from 30's to 2002 (%)
				30年代 30's	50年代 50's	2002年 Year of 2002	平均值 Average	2002年与30年代相比降低率 Dropping rate from 30's to 2002 (%)	70年代 70's	80年代 80's
辽东栎 Quercus liaotungensis	壳斗科 Fagaceae	-25.51	-27.06	-25.92	-27.62	-29.20	-27.14	14.46
虎榛子 Ostryopsis davidiana	桦木科 Betulaceae	-26.57	-26.71	-26.99	-26.93	-29.75	-26.99	11.99
酸枣 Zizyphus jujuba var. spinosa	鼠李科 Rhamnaceae	-	-27.07	-26.69	-28.18	-27.73	-27.49	2.44^**
狼牙刺 Sophora viciifolia	豆科 Leguminosae	-25.12	-26.40	-26.01	-	-28.80	-26.54	14.65

地区 Region	地形 Terrain	气候类型 Climate type	海拔 Altitude (m)	年平均气温 Annual mean temperature (℃)	最冷月1月平均气温 Mean temperature of the coolest month in January (℃)	最热月7月平均气温 Mean temperature of the hottest month in July (℃)	年降水量 Annual precipitation (mm)	无霜期 Period of free frost (d)
陕北 The North in Shaanxi	黄土高原 Loess Plateau	暖温带半干旱或半湿润气候 Warm temperate semi_arid or semi_humid climate	900~1 000	7~11	-10~-4	21~25	400~600	150~190
陕南 The South in Shaanxi	盆地 Basin	北亚热带湿润气候 North sub_tropical humid climate	1 500~3 000	14~15	0~3	24~27.5	700~900	240~269

地区 Region	地形 Terrain	气候类型 Climate type	海拔 Altitude (m)	年平均气温 Annual mean temperature (℃)	最冷月1月平均气温 Mean temperature of the coolest month in January (℃)	最热月7月平均气温 Mean temperature of the hottest month in July (℃)	年降水量 Annual precipitation (mm)	无霜期 Period of free frost (d)
陕北 The North in Shaanxi	黄土高原 Loess Plateau	暖温带半干旱或半湿润气候 Warm temperate semi_arid or semi_humid climate	900~1 000	7~11	-10~-4	21~25	400~600	150~190
陕南 The South in Shaanxi	盆地 Basin	北亚热带湿润气候 North sub_tropical humid climate	1 500~3 000	14~15	0~3	24~27.5	700~900	240~269

近70年来黄土高原典型植物δ¹³C值变化研究

VARIATION IN THE δ¹³ C VALUE OF TYPICAL PLANTS OF LOESS PLATEAU OVER THE LAST 70 YEARS

全文

PDF (PC)

可视化

被引次数

摘要/Abstract

引用本文

使用本文

图/表 4

参考文献 24

相关文章 15

编辑推荐

Metrics

本文评价

[1]	贺洁, 何亮, 吕渡, 程卓, 薛帆, 刘宝元, 张晓萍. 2001-2020年黄土高原光合植被时空变化及其驱动机制[J]. 植物生态学报, 2023, 47(3): 306-318.
[2]	张雪韩凤朋肖波沈思铭. 黄土高原生物结皮对地表粗糙度和灌草植物种子二次扩散的影响[J]. 植物生态学报, 2023, 47(12): 1668-1683.
[3]	薛金儒, 吕肖良. 黄土高原生态工程实施下基于日光诱导叶绿素荧光的植被恢复生产力效益评价[J]. 植物生态学报, 2022, 46(10): 1289-1304.
[4]	杨克彤, 常海龙, 陈国鹏, 俞筱押, 鲜骏仁. 兰州市主要绿化植物气孔性状特征[J]. 植物生态学报, 2021, 45(2): 187-196.
[5]	乔鲜果, 郭柯, 赵利清, 王孜, 刘长成. 中国长芒草群系的群落特征[J]. 植物生态学报, 2020, 44(9): 986-994.
[6]	李单凤, 于顺利, 王国勋, 方伟伟. 黄土高原优势灌丛营养器官化学计量特征的环境分异和机制[J]. 植物生态学报, 2015, 39(5): 453-465.
[7]	荐圣淇, 赵传燕, 方书敏, 余凯, 马文瑛. 黄土高原丘陵沟壑区柠条与沙棘冠层的持水能力[J]. 植物生态学报, 2013, 37(1): 45-51.
[8]	安卓, 牛得草, 文海燕, 杨益, 张洪荣, 傅华. 氮素添加对黄土高原典型草原长芒草氮磷重吸收率及C:N:P化学计量特征的影响[J]. 植物生态学报, 2011, 35(8): 801-807.
[9]	单长卷, 韩蕊莲, 梁宗锁. 黄土高原冰草叶片抗坏血酸和谷胱甘肽合成及循环代谢对干旱胁迫的生理响应[J]. 植物生态学报, 2011, 35(6): 653-662.
[10]	任书杰, 于贵瑞. 中国区域478种C₃植物叶片碳稳定性同位素组成与水分利用效率[J]. 植物生态学报, 2011, 35(2): 119-124.
[11]	魏丽萍, 王孝安, 王世雄, 朱志红, 郭华, 孙嘉男, 郝江勃. 黄土高原马栏林区基于不同植被组织尺度的群落物种多样性[J]. 植物生态学报, 2011, 35(1): 17-26.
[12]	唐丽霞, 张志强, 王新杰, 王盛萍, 查同刚. 晋西黄土高原丘陵沟壑区清水河流域径流对土地利用与气候变化的响应[J]. 植物生态学报, 2010, 34(7): 800-810.
[13]	王迪海, 赵忠, 李剑. 土壤水分对黄土高原主要造林树种细根表面积季节动态的影响[J]. 植物生态学报, 2010, 34(7): 819-826.
[14]	吴芳, 陈云明, 于占辉. 黄土高原半干旱区刺槐生长盛期树干液流动态[J]. 植物生态学报, 2010, 34(4): 469-476.
[15]	李军, 王学春, 邵明安, 赵玉娟, 李小芳. 黄土高原半干旱和半湿润地区刺槐林地生物量与土壤干燥化效应的模拟[J]. 植物生态学报, 2010, 34(3): 330-339.