|Table of Contents|

Synergistic Effects of Soil-plant-microbe Functional Diversity on Phosphorus Cycling in the Glacier Retreat Area of Gongga Mountain, China(PDF)

《地球科学与环境学报》[ISSN:1672-6561/CN:61-1423/P]

Issue:
2023年第03期
Page:
696-705
Research Field:
环境与可持续发展
Publishing date:

Info

Title:
Synergistic Effects of Soil-plant-microbe Functional Diversity on Phosphorus Cycling in the Glacier Retreat Area of Gongga Mountain, China
Author(s):
WU Yan-hong1 LUO Chao-yi12 WANG Zhi-guo12 ZHU He1 ZHOU Jun1 BING Hai-jian1
(1. Institute of Mountain Hazards and Environment, Chinese Academy of Sciences, Chengdu 610299, Sichuan, China; 2. University of Chinese Academy of Sciences, Beijing 100049, China)
Keywords:
biogeochemistry phosphorus cycling plant-soil feedback nutrient resorption functional diversity synergism Gongga mountain
PACS:
P593
DOI:
10.19814/j.jese.2022.12055
Abstract:
Phosphorus is one of the important nutrient elements for plants and soil microbes. The bioavailability of soil phosphorus changes with the soil-forming process, and plants and soil microbes affect soil phosphorus cycling by adjusting their nutrient utilization strategies. The synergistic process of soil-plant-microbe functional diversity development and its impact on phosphorus cycling on the glacier retreat area were studied based on the vegetation primary succession and soil development sequence; plants, soil physicochemical properties, and enzyme activities in the glacier retreat area of Hailuogou, Gongga mountain at four moraine exposure times(1980, 1970, 1958, and 1930)were studied. The results show that ① soil phosphorus content and its bioavailability change obviously in the glacier retreat area of Hailuogou with vegetation succession and soil development. ② At the early stage of soil development, microbes promote the transformation of primary mineral phosphorus and provide nutrients for the early vegetation development; with the amount of phosphorus released from primary mineral decreasing, the plant nutrient use strategy changes at three stages from the phosphorus recycling cycle to simple acquisition, and then to recycling cycle again; with the succession of vegetation, microbes participate more in mineralizing the organic phosphorus and improve the plant reabsorption rate. ③ The rapid loss of moraine phosphorus in the glacier retreat area of Hailuogou intensifies the competition between plants and microbes for phosphorus. Rhizosphere soil phosphorus is significantly enriched at 58 years’ site, and plant phosphorus reabsorption rate reaches its peak at late-soil development.

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Last Update: 2023-05-30