荒漠植物叶片-土壤化学计量及植物内稳态特征

doi:10.13866/j.azr.2024.01.10

Abstract

Abstract:

To understand the relationship between C, N, and P contents of the leaves of desert plants and soil environmental factors, 14 desert plant communities in high and low water or salt environments in Xinjiang Ebinur Lake Nature Reserve were used as research subjects. The C, N, and P contents of the leaves were determined, their stoichiometric ratio, homeostasis characteristics, and their relationship with soil environmental factors were discussed. The results showed that: (1) There were significant differences in soil organic carbon (SOC), total N (TN), C:N, C:P, N, and P contents of leaves under varying water-salt environments. (2) Pearson correlation analysis revealed that the leaf C:P demonstrated a significant negative correlation with soil conductivity (EC), SOC, C:N, and C:P (P<0.05). Leaf C was remarkably negatively correlated with soil C:N (P<0.05). Leaf P was positively correlated with soil SOC and C:N; leaf N was positively correlated with soil C:N; and leaf C:N was positively associated with soil TN (P<0.05). Leaf P was positively correlated with soil C:P and leaf C:N with soil N:P (P<0.05). The redundancy analysis revealed that soil C:P significantly affected the C, N, and P contents and stoichiometric characteristics of the leaves of plants in the Ebinur Lake Nature Reserve. (3) The changes in soil water and salt levels, the contents of N and P in the leaves, and the results of the endostatic model simulation of N:P were insignificant. The internal stability index H was > 4, which belonged to the absolute steady state, indicating that the plants in this study area demonstrated good adaptability to soil nutrients.

Key words: desert, plant leaves, soil, stoichiometric characteristics, endostasis, Ebinur

LI Min, SUN Jie, CHEN Xue, LIU Jiaqing. Leaf-soil stoichiometry and homeostasis characteristics of desert-related plants[J].Arid Zone Research, 2024, 41(1): 104-113.

Figures/Tables 9

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样地号	群落名称	群落物种	地貌特征
A1	梭梭-沙蒿	梭梭、沙蒿、刺蓬	平沙地
A2	梭梭-沙蒿	梭梭、沙蒿、沙拐枣	平沙地
A3	梭梭-麻黄	梭梭、沙蒿、刺蓬、麻黄、碱蓬	小山丘
A4	梭梭-骆驼刺	梭梭、骆驼刺、刺蓬、碱蓬	细砂地
A5	梭梭-沙蒿	梭梭、骆驼刺、刺蓬、沙蒿	细砂地
A6	胡杨-沙蒿	胡杨、沙蒿、碱蓬	细砂地
A7	胡杨-骆驼刺	胡杨、骆驼刺、琵琶柴、沙蒿	平沙地
A8	胡杨-梭梭	胡杨、梭梭、琵琶柴	盐碱地
A9	胡杨-梭梭	胡杨、梭梭、琵琶柴、骆驼刺、罗布麻、花花柴	平沙地
A10	胡杨-骆驼刺	胡杨、琵琶柴、骆驼刺、芦苇、沙蒿	平沙地
A11	胡杨-琵琶柴	胡杨、琵琶柴、盐节木、白刺、刺蓬、碱蓬	平沙地、有结皮
A12	胡杨-柽柳	胡杨、柽柳、骆驼刺、琵琶柴、碱蓬、梭梭	平沙地、有结皮
A13	胡杨-盐豆木	胡杨、盐豆木、柽柳、琵琶柴、碱蓬	平沙地
A14	胡杨-盐豆木	胡杨、盐豆木、梭梭、罗布麻	平沙地

土壤环境因子	重要性排序	F	P
C:P	1	7.6	0.004
C:N	2	4.6	0.008
pH	3	1.8	0.158
SWC	4	0.9	0.368
TP	5	0.9	0.384
N:P	6	0.5	0.57
TN	7	0.2	0.71
EC	8	0.2	0.736
SOC	9	0.2	0.824

Leaf-soil stoichiometry and homeostasis characteristics of desert-related plants

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