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干旱区科学  2012, Vol. 4 Issue (3): 330-341    DOI: 10.3724/SP.J.1227.2012.00330
  学术论文 本期目录 | 过刊浏览 | 高级检索 |
Root growth and spatio-temporal distribution of three common annual halophytes in a saline desert, northern Xinjiang
Ke ZHANG1,2, ChangYan TIAN2, ChunJian LI1
1 College of Resources and Environment, China Agricultural University, Beijing 100193, China;
2 Key Laboratory of Oasis Ecology and Desert Environment, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi 830011, China
Root growth and spatio-temporal distribution of three common annual halophytes in a saline desert, northern Xinjiang
Ke ZHANG1,2, ChangYan TIAN2, ChunJian LI1
1 College of Resources and Environment, China Agricultural University, Beijing 100193, China;
2 Key Laboratory of Oasis Ecology and Desert Environment, Xinjiang Institute of Ecology and Geography, Chinese Academy of Sciences, Urumqi 830011, China
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摘要  Root growth and spatial and temporal distribution in the 0–100 cm soil profiles of three common annual halophytes Salsola subcrassa, Suaeda acuminate and Petrosimonia sibirica distributed in a saline desert in northern Xinjiang, China were studied in 2009 and 2010. The results showed that the root systems of the three halophytes were of the taproot type, vertically distributed in the 90-cm soil profile, and were deepest in late July. Their taproots reached maximum depth rapidly, early in the growth period, but with rare lateral roots. They were then dug out in an orderly way, from bottom to top, exhibiting vertical development first and then horizontal devel-opment. The distribution of specific root length, which reflects the characteristics of the feeder root, was gradually increased from top to bottom, whereas root weight displayed an opposite distribution pattern. The root length dis-tribution of the three halophytes was concentrated (62% to 76%) in the middle soil profile (20–60 cm), with less distribution in the surface (0–20 cm) and bottom (60–90 cm) soil profiles. The results indicated that the roots of the three annual halophytes grew rapidly into the deeper soil layer after germination, which ensured the plant survival and uptake of water and nutrition, and thus built up a strong tolerance to an arid, high-salt environment.
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Ke ZHANG
ChangYan TIAN
ChunJian LI
关键词:  Populus euphratica  inversed model  hyperspectral index  vertical profile  polymorphic leaf    
Abstract: Root growth and spatial and temporal distribution in the 0–100 cm soil profiles of three common annual halophytes Salsola subcrassa, Suaeda acuminate and Petrosimonia sibirica distributed in a saline desert in northern Xinjiang, China were studied in 2009 and 2010. The results showed that the root systems of the three halophytes were of the taproot type, vertically distributed in the 90-cm soil profile, and were deepest in late July. Their taproots reached maximum depth rapidly, early in the growth period, but with rare lateral roots. They were then dug out in an orderly way, from bottom to top, exhibiting vertical development first and then horizontal devel-opment. The distribution of specific root length, which reflects the characteristics of the feeder root, was gradually increased from top to bottom, whereas root weight displayed an opposite distribution pattern. The root length dis-tribution of the three halophytes was concentrated (62% to 76%) in the middle soil profile (20–60 cm), with less distribution in the surface (0–20 cm) and bottom (60–90 cm) soil profiles. The results indicated that the roots of the three annual halophytes grew rapidly into the deeper soil layer after germination, which ensured the plant survival and uptake of water and nutrition, and thus built up a strong tolerance to an arid, high-salt environment.
Key words:  Populus euphratica    inversed model    hyperspectral index    vertical profile    polymorphic leaf
收稿日期:  2012-01-17      修回日期:  2012-04-09           出版日期:  2012-09-03      发布日期:  2012-06-01      期的出版日期:  2012-09-03
基金资助: 

Chinese Academy of Sciences Action-plan for West Development (KZCX2-XB3-07) for financial support, and “Western Light” Talents Training Program of Chinese Academy of Sciences (XBBS200811).

通讯作者:  ChunJian LI    E-mail:  lichj@cau.edu.cn
引用本文:    
Ke ZHANG, ChangYan TIAN, ChunJian LI. Root growth and spatio-temporal distribution of three common annual halophytes in a saline desert, northern Xinjiang[J]. 干旱区科学, 2012, 4(3): 330-341.
Ke ZHANG, ChangYan TIAN, ChunJian LI. Root growth and spatio-temporal distribution of three common annual halophytes in a saline desert, northern Xinjiang. Journal of Arid Land, 2012, 4(3): 330-341.
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http://jal.xjegi.com/CN/10.3724/SP.J.1227.2012.00330  或          http://jal.xjegi.com/CN/Y2012/V4/I3/330
Bao S D. 2000. Analysis of Soil Agrochemistry. Beijing: China Agriculture Press, 49–56.

Chakraborty A, Li B L. 2009. Plant-to-plant direct competition for belowground resource in an overlapping depletion zone. Journal of Arid Land, 1(1): 9−15.

Eissenstat D M. 2000. Root structure and function in an ecological context. New Phytologist, 148: 353–354.

Flowers T J, Colmer T D. 2008. Salinity tolerance in halophytes. New Phytologist, 179: 945–963.

Gao R R, Zhao R H, Du X M, et al. 2010. Characteristics of root systems of two halophytes for adaptability to salinity. Scientia Silvae Sinicae, 46: 1761–1782.

Hartlea R T, Fernandez G C J, Nowaka R S. 2006. Horizontal and vertical zones of influence for root systems of four Mojave Desert shrubs. Journal of Arid Environments, 64: 586–603.

Kong L S, Ma M H. 1995. The bioecological characteristics of Halocnemum strobilaceum and its community on the border of an oasis in Hutubi, Xinjiang. Acta Ecologica Sinica, 15: 351–358.

Kroon H D, Visser E J W. 2003. Root Ecology, New York: Springer- Verlag, 1–27.

Lai W L, Wang Y B, Peng C L, et al. 2010. Growth characteristics of four species in surface-flow-constructed wetlands. Journal of Tropical and Subtropical Botany, 18: 238–244.

Liu G J, Zhang X M, Li X R, et al. 2008. Adaptive growth of Tamarix taklamakanensis root systems in response to wind action. Chinese Science Bulletin, 53 (Suppl. II): 164–168.

Liu J M, An S Q, Liao R W, et al. 2009. Temporal variation and spatial distribution of the root systems of corn in a soil profile. Chinese Journal of Eco-Agriculture, 17: 517–521.

Lu H D, Xue J Q, Ma G S, et al. 2010. Soil physical and chemical properties and root distribution in high yielding spring maize fields in Yulin, Shaanxi province. Chinese Journal of Applied Ecology, 21: 895–900.

Ma C M. 2007. Research on the agroforestry models based on water utilization characteristics—take the old field in Pingshan, Hebei as an example. Ph.D. Dissertation. Beijing: Beijing Forestry University.

Ma J, Wang X L, Zhao S L. 1996. Studies of root systems of Peganum in Northwest China. Arid Zone Research, 13: 60–64.

Ownbey R S, Mahall B E. 1983. Salinity and root conductivity: differential responses of a coastal succulent halophyte, Salicornia virginica, and a weedy glycophyte, Raphanus sativus. Physiologia Plantarum, 57: 189–195.

Rundell P W, Nobel P S. 1991. Structure and function of desert root systems. In: Atkinson D. Plant Root Growth. An Ecological Perspective, Oxford: Blackwell, 349–378.

Sala A, Smith S D. 1996. Water use by Tamarix ramosissima and associated phreatophytes in a Mojave Desert floodplain. Journal of Applied Ecology, 6: 888–898.

Schippers P, Olff H. 2000. Biomass partitioning, architecture and turnover of six herbaceous species from habitats with different nutrient supply. Plant Ecology, 149: 219–231.

Su L T, Song Y D, Zhang Z Y. 2005. Spatial variability and fractal dimensions of groundwater and natural vegetation in the north foot of Tianshan Mountains. Journal of Mountain Science, 23: 14–20.

Sun X, Yu Z. 1992. A study of the root systems of Nitraria tangutorum. Journal of Desert Research, 12: 50–54.

Wang Y M, Hudan T, Zhang J Z, et al. 2010. Study on the root distribution peculiarity of cotton in drip irrigation under mulched-film. Journal of Agricultural University of Hebei, 33: 103–106.

Wang Z J, Di L, Li C L. 2002. Study on the spring floods caused by snow melt water in low-mountain and hill regions of northern piedmont of the Tianshan Mountains—a case study in the paleochannels of Sangong River. Arid Land Geography, 25: 302–308.

Wei L Y, Shangguan Z P. 2006. Specific root length characteristics of three plant species, Bothriochloa ischaemum, Hippophae rhamnoidess and Quercus liaotungensis in the Loess Plateau. Acta Ecologica Sinica, 26: 4164–4170.

Xi J B, Zhang F S, Tian C Y. 2006. Halophytes in Xinjiang. Beijing: Science Press, 33–63.

Xu G Q, Li Y, Zou T. 2010. Hydraulic resistance partitioning between shoot and root system and plant water status of Haloxyolon ammodendron growing at sites of contrasting soil texture. Journal of Arid Land, 2(2): 98−106.

Xu H, Li Y. 2006. Water-use strategy of three central Asian desert shrubs and their responses to rain pulse events. Plant and Soil, 285: 5−17.

Xu H, Li Y, Xu G Q, et al. 2007. Eco-physiological response and morphological adjustment of two Central Asian desert shrubs towards variation in summer precipitation. Plant, Cell and Environment, 30: 399–409.

Zhang L Y, Maimaiti A, Xia Y. 1995. Effect of summer irrigation on morphological characteristics, community eco-structure and natural regeneration of Alhagi sparsifolia. Arid Zone Research, 12: 34–40.

Zhu M Q, Ma C M, Zhai M P, et al. 2009. Fine roots distribution characteristics of Zanthoxylum bungeanum in the rocky mountainous area of Hebei. Scientia Silvae Sinicae, 45: 131–135.
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