Responses of growth and litterfall production to nitrogen addition treatments from common shrublands in Mt. Dongling, Beijing, China

doi:10.17521/cjpe.2016.0093

Abstract

Abstract:

Aims The shrublands of northern China have poor soil and nitrogen (N) deposition has greatly increased the local soil available N for decades. Shrub growth is one of important components of C sequestration in shrublands and litterfall acts as a vital link between plants and soil. Both are key factors in nutrient and energy cycling of terrestrial ecosystems, which greatly affected by nitrogen (N) addition (adding N fertilizer to the surface soil directly). However, the effects and significance of N addition on C sequestration and litterfall in shrublands remain unclear. Thus, a study was designed to investigate how N deposition and related treatments affected shrublands growth related to C sequestration and litterfall production of Vitex negundo var. heterophylla and Spiraea salicifolia in Mt. Dongling region of China.
Methods A N enrichment experiment has been conducted for V. negundo var. heterophylla and S. salicifolia shrublands in Mt. Dongling, Beijing, including four N addition treatment levels (control (N₀, 0 kg N·hm^-2·a^-1), low N (N₁, 20 kg N·hm^-2·a^-1), medium N (N₂, 50 kg N·hm^-2·a^-1) and high N (N₃, 100 kg N·hm^-2·a^-1)). Basal diameter and plant height of shrub were measured from 2012-2013 within all treatments, and allometric models for different species of shrub’s live branch, leaf and root biomass were developed based on independent variables of basal diameter and plant height, which will be used to calculate biomass increment of shrub layer. Litterfall (litterfall sometimes is named litter, referring to the collective name for all organic matter produced by the aboveground part of plants and returned to the surface, and mainly includes leaves, bark, dead twigs, flowers and fruits.) also was investigated from 2012-2013 within all treatments.
Important findings The results showed 1) mean basal diameter of shrubs in the V. negundo var. heterophylla and S. salicifolia shrublands were increased by 1.69%, 2.78%, 2.51%, 1.80% and 1.38%, 1.37%, 1.59%, 2.05% every year; 2) The height growth rate (the shrub height relative growth rate is defined with the percentage increase of plant height) of shrubs in the V. negundo var. heterophylla and S. salicifolia shrublands were 8.36%, 8.48%, 9.49%, 9.83% and 2.12%, 2.86%, 2.36%, 2.52% every year, respectively. Thee results indicated that N deposition stimulated growth of shrub layer both in V. negundo var. heterophylla and S. salicifolia shrublands, but did not reach statistical significance among all nitrogen treatments. The above-ground biomass increment of shrub layer in the V. negundo var. heterophylla and S. salicifolia shrublands were 0.19, 0.23, 0.14, 0.15 and 0.027, 0.025, 0.032, 0.041 t C·hm^-2·a^-1 respectively, which demonstrated that short-term N addition had no significant effects on the accumulation of C storage of the two shrublands. The litter production of the V. negundo var. heterophylla and S. salicifolia communities in 2013 were 135.7 and 129.6 g·m^-2under natural conditions, respectively. Nitrogen addition promoted annual production of total litterfall and different components of litterfall to a certain extent, but did not reach statistical significance among all nitrogen treatments. Above results indicated that short-term fertilization, together with extremely low soil moisture content and other related factors, lead to inefficient use of soil available nitrogen and slow response of shrublands to N addition treatments.

http://jtp.cnki.net/bilingual/detail/html/ZWSB201701009

Key words: nitrogen deposition, carbon cycle, temperate shrublands, growth rate, litterfall, seasonal dynamics

Jian-Hua ZHANG, Zhi-Yao TANG, Hai-Hua SHEN, Jing-Yun FANG. Responses of growth and litterfall production to nitrogen addition treatments from common shrublands in Mt. Dongling, Beijing, China[J]. Chin J Plant Ecol, 2017, 41(1): 71-80.

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URL: https://www.plant-ecology.com/EN/10.17521/cjpe.2016.0093

https://www.plant-ecology.com/EN/Y2017/V41/I1/71

Figures/Tables 7

References 30

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项目 Item	荆条灌丛 Vitex negundo var. heterophylla shrubland	绣线菊灌丛 Spiraea salicifolia shrubland
地形和气候 Topography and climate
海拔 Elevation (m)	791	1 170
坡向 Aspect	S	S
坡度 Slope (°)	28	25
年平均气温 Mean annual temperature (°C)	12.3	9.2
表层土壤特征 Topsoil property
土壤pH Soil pH	8.7	8.9
总碳含量 Total carbon (mg·g^-1)	28.88 ± 2.10	39.50 ± 5.03
总氮含量 Total nitrogen (mg·g^-1)	2.72 ± 0.32	2.29 ± 0.36
总磷含量 Total phosphorous (mg·g^-1)	0.47 ± 0.04	0.48 ± 0.03
无机氮含量 Inorganic nitrogen (mg·kg^-1)	6.01 ± 2.38	2.51 ± 2.88
速效磷含量 Available phosphorous (mg·kg^-1)	1.03 ± 0.09	1.38 ± 0.77
群落特征 Community character
灌木高度 Shrub height (cm)	78.10 ± 12.37	79.80 ± 7.43
平均基径 Average base diameter (cm)	0.77 ± 1.77	0.56 ± 0.04
灌木密度 Shrub density (stems·hm^-2)	1.6 × 10⁵	3.6 × 10⁵

项目 Item	荆条灌丛 Vitex negundo var. heterophylla shrubland	绣线菊灌丛 Spiraea salicifolia shrubland
地形和气候 Topography and climate
海拔 Elevation (m)	791	1 170
坡向 Aspect	S	S
坡度 Slope (°)	28	25
年平均气温 Mean annual temperature (°C)	12.3	9.2
表层土壤特征 Topsoil property
土壤pH Soil pH	8.7	8.9
总碳含量 Total carbon (mg·g^-1)	28.88 ± 2.10	39.50 ± 5.03
总氮含量 Total nitrogen (mg·g^-1)	2.72 ± 0.32	2.29 ± 0.36
总磷含量 Total phosphorous (mg·g^-1)	0.47 ± 0.04	0.48 ± 0.03
无机氮含量 Inorganic nitrogen (mg·kg^-1)	6.01 ± 2.38	2.51 ± 2.88
速效磷含量 Available phosphorous (mg·kg^-1)	1.03 ± 0.09	1.38 ± 0.77
群落特征 Community character
灌木高度 Shrub height (cm)	78.10 ± 12.37	79.80 ± 7.43
平均基径 Average base diameter (cm)	0.77 ± 1.77	0.56 ± 0.04
灌木密度 Shrub density (stems·hm^-2)	1.6 × 10⁵	3.6 × 10⁵

物种 Species	器官 Organ	变量 Variable	R²	方程 Equation
山杏	根 Root	D²H	0.81	y = 1.26x^0.77
Armeniaca sibirica	枝 Branch	D²H	0.94	y = 1.09x^0.79
	叶 Leaf	D²H	0.87	y = 1.61x^0.56
	总计 Total	D²H	0.95	y = 3.53x^0.74
小叶白蜡	根 Root	D²H	0.88	y = 0.2x^0.91
Fraxinus bungeana	枝 Branch	D²H	0.50	y = 5.47x^0.51
	叶 Leaf	D²H	0.77	y = 0.13x^0.8
	总计 Total	D²H	0.72	y = 4.47x^0.62
小叶鼠李	根 Root	D²H	0.95	y = 0.7x^0.85
Rhamnus	枝 Branch	D²H	0.96	y = 0.74x^0.91
parvifolia	叶 Leaf	D²H	0.88	y = 0.89x^0.58
	总计 Total	D²H	0.96	y = 1.95x^0.85
河朔荛花	根 Root	D²H	0.83	y = 0.81x^0.61
Wikstroemia	枝 Branch	D²H	0.95	y = 0.92x^0.78
chamedaphne	叶 Leaf	D²H	0.48	y = 1.32x^0.35
	总计 Total	D²H	0.92	y = 2.31x^0.68
绣线菊	根 Root	D²H	0.77	y = 0.18x^1.14
Spiraea salicifolia	枝 Branch	D²H	0.78	y = 0.23x^1.18
	叶 Leaf	D²H	0.62	y = 0.07x^1.15
	总计 Total	D²H	0.79	y = 0.48x^1.16
荆条	根 Root	D²H	0.84	y = 0.2x^1.09
Vitex negundo var.	枝 Branch	D²H	0.82	y = 0.54x^0.95
heterophylla	叶 Leaf	D²H	0.66	y = 0.86x^0.59
	总计 Total	D²H	0.90	y = 1.07x^0.95
蚂蚱腿子	根 Root	D²H	0.95	y = 0.07x^1.16
Myripnois dioica	枝 Branch	D²H	0.91	y = 0.42x^1.00
	叶 Leaf	D²H	0.79	y = 0.31x^0.71
	总计 Total	D²H	0.95	y = 0.64x^1.00
胡枝子	根 Root	D²H	0.41	y = 0.19x^1.06
Lespedeza bicolor	枝 Branch	D²H	0.87	y = 0.15x^1.5
	叶 Leaf	D²H	0.84	y = 0.29x^1.25
	总计 Total	D²H	0.84	y = 0.61x^1.29

物种 Species	器官 Organ	变量 Variable	R²	方程 Equation
山杏	根 Root	D²H	0.81	y = 1.26x^0.77
Armeniaca sibirica	枝 Branch	D²H	0.94	y = 1.09x^0.79
	叶 Leaf	D²H	0.87	y = 1.61x^0.56
	总计 Total	D²H	0.95	y = 3.53x^0.74
小叶白蜡	根 Root	D²H	0.88	y = 0.2x^0.91
Fraxinus bungeana	枝 Branch	D²H	0.50	y = 5.47x^0.51
	叶 Leaf	D²H	0.77	y = 0.13x^0.8
	总计 Total	D²H	0.72	y = 4.47x^0.62
小叶鼠李	根 Root	D²H	0.95	y = 0.7x^0.85
Rhamnus	枝 Branch	D²H	0.96	y = 0.74x^0.91
parvifolia	叶 Leaf	D²H	0.88	y = 0.89x^0.58
	总计 Total	D²H	0.96	y = 1.95x^0.85
河朔荛花	根 Root	D²H	0.83	y = 0.81x^0.61
Wikstroemia	枝 Branch	D²H	0.95	y = 0.92x^0.78
chamedaphne	叶 Leaf	D²H	0.48	y = 1.32x^0.35
	总计 Total	D²H	0.92	y = 2.31x^0.68
绣线菊	根 Root	D²H	0.77	y = 0.18x^1.14
Spiraea salicifolia	枝 Branch	D²H	0.78	y = 0.23x^1.18
	叶 Leaf	D²H	0.62	y = 0.07x^1.15
	总计 Total	D²H	0.79	y = 0.48x^1.16
荆条	根 Root	D²H	0.84	y = 0.2x^1.09
Vitex negundo var.	枝 Branch	D²H	0.82	y = 0.54x^0.95
heterophylla	叶 Leaf	D²H	0.66	y = 0.86x^0.59
	总计 Total	D²H	0.90	y = 1.07x^0.95
蚂蚱腿子	根 Root	D²H	0.95	y = 0.07x^1.16
Myripnois dioica	枝 Branch	D²H	0.91	y = 0.42x^1.00
	叶 Leaf	D²H	0.79	y = 0.31x^0.71
	总计 Total	D²H	0.95	y = 0.64x^1.00
胡枝子	根 Root	D²H	0.41	y = 0.19x^1.06
Lespedeza bicolor	枝 Branch	D²H	0.87	y = 0.15x^1.5
	叶 Leaf	D²H	0.84	y = 0.29x^1.25
	总计 Total	D²H	0.84	y = 0.61x^1.29

物种 Species	变量 Variable	对照 Control (N₀)	低氮 Low-N (N₁)	中氮 Medium-N (N₂)	高氮 High-N (N₃)
荆条灌丛 Vitex negundo var. heterophylla shrubland	D	0.70 ± 0.10	0.90 ± 0.20	0.70 ± 0.00	0.70 ± 0.10
荆条灌丛 Vitex negundo var. heterophylla shrubland	H	78.30 ± 7.80	84.20 ± 10.10	74.60 ± 3.00	75.40 ± 9.00
绣线菊灌丛 Spiraea salicifolia shrubland	D	0.53 ± 0.00	0.57 ± 0.00	0.57 ± 0.00	0.54 ± 0.00
绣线菊灌丛 Spiraea salicifolia shrubland	H	76.40 ± 0.60	78.80 ± 4.00	81.40 ± 7.10	82.80 ± 4.70