Arid Zone Research ›› 2023, Vol. 40 ›› Issue (3): 412-424.doi: 10.13866/j.azr.2023.03.08
• Plant Ecology • Previous Articles Next Articles
SUN Qixing1,2(
),YANG Xiaodong2,3(),LI Borui1,2,KONG Cuicui1,2,Elhamjan ANWAR1,2,ZHOU Jie1,2,LYU Guanghui1,2
Received:2022-07-27
Revised:2022-10-22
Online:2023-03-15
Published:2023-03-31
SUN Qixing, YANG Xiaodong, LI Borui, KONG Cuicui, Elhamjan ANWAR, ZHOU Jie, LYU Guanghui. Effects of hydraulic traits on the species abundance distribution pattern of desert plant communities[J].Arid Zone Research, 2023, 40(3): 412-424.
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Fig. 1
Schematic diagram of study area and sample plot"
Tab. 1
Division of drought gradient"
| 采样序号 | 土壤含水量/% | 土壤干旱梯度 |
|---|---|---|
| D0 | 18.54±0.87 | 非干旱 |
| D1 | 12.74±1.25 | 轻度干旱 |
| D2 | 9.38±0.80 | 中度干旱 |
| D3 | 3.63±0.66 | 重度干旱 |
Fig. 2
Interspecific variance of abundance and their variation across the soil drought gradient"
Fig. 3
Interspecific variance of quasi steady state hydraulic conductivity and twig specific hydraulic conductancy and their variation across the soil drought gradient"
Fig. 4
Interspecific variance of middy minimum leaf water potential and middy minimum twig water potential and their variation across the soil drought gradient"
Fig. 5
Interspecific variance of pre-dawn leaf water potential and pre-dawn twig water potential and their variation across the soil drought gradient"
Fig. 6
Interspecific variance of Huber value and stem wood density and their variation across the soil drought gradient"
Tab. 2
RDA analysis results of abundance and hydraulic traits of desert plant community"
| 排序轴 | 第一轴 | 第二轴 |
|---|---|---|
| 特征值 | 0.65 | 0.26 |
| 多度与水力性状相关性 | 0.99 | 0.99 |
| 多度变异的累计百分数/% | 64.56 | 90.46 |
| 多度-水力性状关系的累计解释量/% | 65.96 | 92.42 |
Fig. 7
RDA results between desert plant community abundance and hydraulic traits on soil drought gradient"
Tab. 3
Statistical of using Generalized Additive Models to predict the abundance change of desert plant community"
| 模型 | R2 | Dexp/% | GCV | |
|---|---|---|---|---|
| a | s(Ψlmin*) | 0.13 | 13.30 | 32.73 |
| b | s(Ψlmin**)+s(Ks) | 0.28 | 34.00 | 31.17 |
| c | s(Ψlmin***)+s(Ks**)+s(Ψlpd*) | 0.43 | 51.70 | 28.07 |
| d | s(Ψlmin***)+s(Ks***)+s(Ψlpd**)+s(Hv*) | 0.80 | 75.30 | 23.43 |
| e | s(Ψlmin***)+s(Ks***)+s(Ψlpd**)+s(Hv*)+s(Ψsmin) | 0.80 | 76.50 | 22.41 |
| f | s(Ψlmin***)+s(Ks***)+s(Ψlpd**)+s(Hv***)+s(Ψsmin)+s(SWD*) | 0.81 | 76.80 | 19.56 |
| g | s(Ψlmin***)+s(Ks***)+s(Ψlpd***)+s(Hv***)+s(Ψsmin*)+s(SWD**)+s(Kwb**) | 0.87 | 86.40 | 15.62 |
| h | s(Ψlmin***)+s(Ks***)+s(Ψlpd***)+s(Hv**)+s(Ψsmin**)+s(SWD***)+s(Kwb***)+s(Ψspd**) | 0.93 | 92.80 | 14.45 |
Fig. 8
Relationship between hydraulic traits and its smoothing function in Generalized Additive Models"
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