Fractal root system of Melica przewalskyi along different aspect in degraded grassland

doi:10.17521/cjpe.2015.0078

Abstract

Abstract:

Aims Fractal root system is phenotypic plasticity result of plant root architecture to respond to environmental heterogeneity, may reflect the growth strategy of plants to adapt to environmental conditions. Our objective was to explore the relationship between root fractal dimension and fractal abundance of fractal root system of Melica przewalskyi population in response to aspect variation in the northwest of China. Methods The study site was located in a degraded alpine grassland on the northern slope in Qilian Mountains, Gansu Province, China. Survey and sampling were carried out at 40 plots which were set up along four slope aspects transects with 20 m distance between adjacent plots. Handheld GPS was used to determine the elevation, longitude and latitude of each plot. ArcGIS was used to set up digital elevation model (DEM). Community traits were investigated and six individuals roots of M. przewalskyi were collected randomly at each plot. The samples were cleaned and divided into different organs, then scanning the root with the Win-RHIZO for measurements of fractal dimension and fractal abundance in laboratory, and their biomass were then measured after being dried at 80 °C in an oven. Important findings With the slope aspect turned from north to east, west, and south, the density, height and soil moisture content of the plant community displayed a pattern of initial decline, the height, density, root fractal abundance of M. przewalskyi increased and the root fractal dimension decreased. The root fractal dimension was negatively associated with the fractal abundance in all aspects, but the relationship varied along the slope aspects gradient; there was a highly significant negative correlation (p < 0.01) between the root fractal dimension and fractal abundance at north slope and south slope aspect, whereas the correlation only reached a significant level (p < 0.05) at the east slope aspect and west slope aspect; indicating that there is a trade-off between the root fractal dimension and fractal abundance. In addition, when the slope aspect changed from north to east, west and south, the standardized major axis (SMA) slope of the regression equation in the scaling relationships between root fractal dimension and fractal abundance increased (p < 0.05), indicating that the roots of M. przewalskyi at the droughty southern slope have less branch and more sparse in the same soil volume of root exploitation and utilization. Consequently, the resource allocation pattern on reasonable trade-off between root fractal dimension and fractal abundance in different slope aspect of M. przewalskyi, reflects the relationship between the income and the cost of construction of plant root architecture.

Key words: aspect, root architecture, Melica przewalskyi, fractal root system, fractal dimension, fractal abundance

SONG Qing-Hua,ZHAO Cheng-Zhang,SHI Yuan-Chun,DU Jing,WANG Ji-Wei,CHEN Jing. Fractal root system of Melica przewalskyi along different aspect in degraded grassland[J]. Chin J Plan Ecolo, 2015, 39(8): 816-824.

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Figures/Tables 4

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坡向 Aspect	群落特征 Community properties			土壤水分含量 Soil moisture content (%)
坡向 Aspect	密度 Density (plant·m^-2)	高度 Height (cm)	地上生物量 Aboveground biomass (g·m^-2)	土壤水分含量 Soil moisture content (%)
北 North	261 ± 18.54^a	34.50 ± 1.74^a	100.18 ± 2.13^a	12.30 ± 0.56^a
东 East	214 ± 17.42^b	27.80 ± 1.32^b	97.66 ± 2.28^b	8.90 ± 0.38^b
西 West	192 ± 16.17^c	25.80 ± 1.16^b	94.78 ± 1.49^c	8.50 ± 0.37^b
南 South	147 ± 12.46^d	21.80 ± 0.87^c	92.23 ± 1.74^d	6.70 ± 0.24^c

坡向 Aspect	群落特征 Community properties			土壤水分含量 Soil moisture content (%)
坡向 Aspect	密度 Density (plant·m^-2)	高度 Height (cm)	地上生物量 Aboveground biomass (g·m^-2)	土壤水分含量 Soil moisture content (%)
北 North	261 ± 18.54^a	34.50 ± 1.74^a	100.18 ± 2.13^a	12.30 ± 0.56^a
东 East	214 ± 17.42^b	27.80 ± 1.32^b	97.66 ± 2.28^b	8.90 ± 0.38^b
西 West	192 ± 16.17^c	25.80 ± 1.16^b	94.78 ± 1.49^c	8.50 ± 0.37^b
南 South	147 ± 12.46^d	21.80 ± 0.87^c	92.23 ± 1.74^d	6.70 ± 0.24^c

坡向Aspect	密度 Density (plant·m^-2)	高度 Height (cm)	总生物量 Total biomass (g·m^-2)	根系生物量 Root biomass (g·m^-2)
北坡 North slope	56 ± 4.31^c	15.61 ± 0.14^c	96.02 ± 4.61^c	17.39 ± 0.83^c
东坡 East slope	94 ± 8.17^b	18.30 ± 0.26^b	210.68 ± 10.24^b	58.27 ± 2.92^b
西坡 West slope	98 ± 8.21^b	18.63 ± 0.32^b	209.75 ± 11.05^b	61.83 ± 3.08^b
南坡 South slope	141 ± 12.27^a	21.80 ± 0.87^a	242.51 ± 14.94^a	88.02 ± 4.41^a

坡向Aspect	密度 Density (plant·m^-2)	高度 Height (cm)	总生物量 Total biomass (g·m^-2)	根系生物量 Root biomass (g·m^-2)
北坡 North slope	56 ± 4.31^c	15.61 ± 0.14^c	96.02 ± 4.61^c	17.39 ± 0.83^c
东坡 East slope	94 ± 8.17^b	18.30 ± 0.26^b	210.68 ± 10.24^b	58.27 ± 2.92^b
西坡 West slope	98 ± 8.21^b	18.63 ± 0.32^b	209.75 ± 11.05^b	61.83 ± 3.08^b
南坡 South slope	141 ± 12.27^a	21.80 ± 0.87^a	242.51 ± 14.94^a	88.02 ± 4.41^a

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