Bulletin of Botanical Research ›› 2023, Vol. 43 ›› Issue (2): 194-206.doi: 10.7525/j.issn.1673-5102.2023.02.005
• Physiology and Ecology • Previous Articles Next Articles
Zhenggang XU1, Hang XU1, Xiutao PENG1, Shijun LIANG2, Rong LIU1, Shanghua LUO1, Juan XIAO1(
)
Received:2022-05-27
Online:2023-03-20
Published:2023-03-07
Contact:
Juan XIAO
E-mail:xiaojuanhj@163.com
About author:XU Zhenggang(1996—),male,postgraduate student,mainly engaged in underground ecology research.
Supported by:CLC Number:
Zhenggang XU, Hang XU, Xiutao PENG, Shijun LIANG, Rong LIU, Shanghua LUO, Juan XIAO. Effects of N addition on Root Exudates and Their Mediated Nutrient Rransformation Processes in a Betula albosinensis Burk Forest in Southwest China[J]. Bulletin of Botanical Research, 2023, 43(2): 194-206.
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URL: https://bbr.nefu.edu.cn/EN/10.7525/j.issn.1673-5102.2023.02.005
Fig.1
Setting diagram of test sample area
Table 1
Soil physical and chemical properties and basic plot information(mean±SE, n=6)
试验区 Test area | 全碳 Total C /(g·kg-1) | 全氮 Total N /(g·kg-1) | 含水率 Rate of water content /% | pH | 硝态氮 Nitrate nitrogen /(mg·kg-1) | 铵态氮 Ammonium nitrogen /(mg·kg-1) | 株高 Plant height /m | 胸径 Diameter at breast height /cm |
|---|---|---|---|---|---|---|---|---|
| 1 | 35.910±2.997a | 3.580±0.111a | 34.810±0.002a | 4.450±0.027a | 18.060±0.057a | 24.250±0.303a | 20.800±1.200a | 29.400±2.400a |
| 2 | 36.620±1.385a | 3.230±0.046a | 35.180±0.002a | 4.310±0.047a | 18.300±0.095a | 23.870±0.078a | 20.600±0.600a | 29.400±1.500a |
| 3 | 36.470±1.955a | 3.690±0.756a | 35.320±0.002a | 4.340±0.100a | 18.160±0.081a | 23.710±0.196a | 19.700±0.300a | 29.100±1.400a |
Table 2
Repeated measurement analysis of variance on the effects of N addition and sampling time on the exudation rate of B. albosinensis Burk forest
因素 Factor | 根生物量分泌速率 Secretion rate of root biomass /(µg·g-1·h-1) | 根长分泌速率 Secretion rate of root length /(µg·g-1·h-1) | 根表面积分泌速率 Secretion rate of root surface area /(µg·g-1·h-1) |
|---|---|---|---|
采样时间 Sampling date | 0.067 | 0.065 | 0.057 |
氮添加 N addition | 0.027 | 0.015 | 0.037 |
氮添加×采样时间 N addition× Sampling date | 0.580 | 0.886 | 0.053 |
Fig.2
Difference of root exudation rate under different levels of N additionA.Root exudation rate per unit root biomass;B.Root exudation rate per unit root length;C.Root exudation rate per unit root surface area;Different lowercase letters indicated that the C input rate of root exudation changed significantly at the same sampling time under different N treatments(P<0.05);CK.Control group;N25.Low N group;N50.High N Group
Table 3
Differences in response of C input fluxes of root exudates to N addition in B. albosinensis Burk forest
氮处理 Nitrogen treatment | 细根生物量 Fine root biomass /(g·m-2) | 单位根生物量根系 分泌物C输入速率 Input rate of root exudate C per unit root biomass /(µg·g-1·h-1) | 年C输入通量 Annual C input flux /(g·m-2·a-1) |
|---|---|---|---|
| CK | 136.73±4.15a | 125.54±5.43a | 70.45±8.66a |
| N25 | 90.19±5.20b | 104.67±4.72ab | 38.45±3.97b |
| N50 | 57.72±5.24c | 79.27±4.19b | 18.78±2.41c |
Fig.3
Rhizosphere effects of different N additions on soil N mineralization rate
Table 4
Rhizosphere effect of N mineralization rate of B. albosinensis Burk forest under different N treatments and evaluation of contribution of roots to soil N mineralization
氮处理 Nitrogen treatment | 根际土比例 Proportion of rhizosphere soil /% | N矿化速率根际效应值 N mineralization rate rhizosphere effect value /% | 根系对土壤N矿化的贡献 Contribution of root system to soil N mineralization /% |
|---|---|---|---|
| CK | 6.73±0.35a | 110.62±10.70a | 7.44±0.72a |
| N25 | 5.19±0.24ab | 95.26±9.51ab | 4.94±0.49b |
| N50 | 3.72±0.24b | 80.71±7.95b | 3.00±0.30c |
Table 5
Variance analysis of N mineralization,N addition and repeated measurement of sampling time in rhizosphere soil of different B. albosinensis sample plots
因素 Factor | N矿化速率根际效应值 N mineralization rate rhizosphere effect value /% |
|---|---|
采样时间 Sampling date | 0.265 |
氮添加 N addition | 0.045 |
氮添加×采样时间 N addition× Sampling date | 0.836 |
Fig.4
Effects of different N application treatments on the magnitude of rhizosphere effect of soil microbial biomass C(A) and rhizosphere effect of soil microbial biomass N(B)
Fig.5
Effects of different N treatments on the size of rhizosphere effect of β -D-glucosidase(A), β -N-acetylglucosaminidase(B),polyphenol oxidase(C) and peroxidase(D)
Fig.6
Correlation analysis of root exudates input soil C/N conversion soil enzyme activity characteristicsA. N mineralization;B. C Mineralization;C. Microbial C;D. Microbial N;E. Polyphenol oxidase;F. β-N-acetylglucosaminidase;G. Peroxidase;H. β-D-glucosidase
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