Scientia Agricultura Sinica ›› 2019, Vol. 52 ›› Issue (20): 3611-3624.doi: 10.3864/j.issn.0578-1752.2019.20.012

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• SPECIAL FOCUS: SOIL WATER AND FERTILIZER MANAGEMENT IN GREENHOUSE VEGETABLE FIELDS • Previous Articles     Next Articles

Effects of Drip Irrigation Water and Fertilizer Integration Combined with Organic Fertilizers on Soil N2O Emission and Enzyme Activity

YaJing XI1,2,JunYu WANG1,2,YinKun LI3,XuePing WU2(),XiaoXiu LI1(),BiSheng WANG2,ShengPing LI2,XiaoJun SONG2,CaiCai LIU2   

  1. 1 College of Resources Environment and Tourism, Capital Normal University, Beijing 100037
    2 Institute of Agricultural Resource and Regional Planning, Chinese Academy of Agriculture Sciences, Beijing 100081
    3 Beijing Research Center of Intelligent Equipment for Agriculture, Beijing 100097
  • Received:2019-06-03 Accepted:2019-09-02 Online:2019-10-16 Published:2019-10-28
  • Contact: XuePing WU,XiaoXiu LI E-mail:wuxueping@caas.cn;lxiaoxiu0548@sina.com

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Abstract:

【Objective】 This paper mainly studied the dynamic changes of soil N2O emission and the activities of urease (UR), nitrate reductase (NR), nitrite reductase (Ni R) and hydroxylamine reductase (Hy R) under the condition of drip irrigation water and fertilizer integration by applying different amounts of inorganic nitrogen to organic nitrogen, and analyzed the soil N2O emission characteristics of every treatment and the effects of soil UR, NR, Ni R and Hy R activities on soil N2O emissions, the purpose of this research was to reveal the influence mechanism of N2O emission process under the integration of drip irrigation water and fertilizer.【Method】 The treatments consisted of CK (no nitrogen application), N1 (200 kg·hm -2 organic nitrogen), N2 (200 kg·hm -2organic nitrogen + 250 kg·hm -2 inorganic nitrogen), and N3 (200 kg·hm -2 organic nitrogen + 475 kg·hm -2inorganic nitrogen). Using static-chamber method, the soil N2O emission, enzyme activity, soil temperature and humidity during the growth period of tomato were monitored.【Result】 The integration of water and fertilizer in drip irrigation showed that the N2O emission peak of every treatment appeared at the first day after fertilization + irrigation, and decreased continuously with the passage of time. The N2O emission flux range under different treatments was 0.98-1544.79 μg·m -2·h -1. The total N2O emissions during the growth period of tomato under different treatments had significant differences among each treatment, which were N3 ((7.13±0.11) kg·hm -2) >N2 ((4.87±0.21) kg·hm -2) >N1 ((2.54±0.17) kg·hm -2) >CK ((1.56±0.23) kg·hm -2). Compared with N3, the total soil N2O emissions from N1 and N2 decreased by 64.38% and 31.70%, respectively. During the growth period of tomato, the characteristics of seasonal emission of N2O changed obviously, which revealed high in autumn and low in winter. The activity of soil nitrogen-related enzymes increased with the increase of nitrogen application rate. The soil N2O flux was positively correlated with 5 cm soil temperature, 0-10 cm soil nitrate nitrogen content, soil NR activity and soil Hy R activity (P<0.01).【Conclusion】 Under the integration of drip irrigation and water and fertilizer, soil N2O mainly came from the nitrification process, which reduced the N2O emissions generated by the denitrification process. Considering the factors such as tomato yield, quality and N2O emission, it was recommended to apply 200 kg·hm -2organic nitrogen +250 kg·hm -2 inorganic nitrogen, 75 kg·hm -2 P2O5 and 450 kg·hm -2 K2O in northern greenhouse autumn-winter tomato.

Key words: N2O emissions, soil nitrogen invertase, drip irrigation water and fertilizer integration, temperature, nitrate nitrogen, greenhouse tomato

Table 1

Physicochemical properties of soil under test greenhouse"

土层
Soil depth (cm)		 有机质
Organic matter (g·kg-1)		 全氮
Total nitrogen (g·kg-1)		 硝态氮
NO3--N (mg·kg-1)		 电导率
Electrical conductivity (μS·cm-1)		 容重
Bulk density (g·cm-3)
0-20 15.4 1.55 14.87 276 1.354
20-40 12.80 278 1.517
40-60 22.25 348 1.485
60-80 70.25 360 1.361
80-100 98.68 392 1.424

Fig. 1

Dynamic changes of soil temperature and humidity during the growth period of tomato The arrows in the figure represent fertilization. The same as below"

Fig. 2

Dynamic changes of soil inorganic nitrogen content in 0-10 cm soil layer"

Fig. 3

Dynamic changes of soil urease activity, nitrate reductase activity, nitrite reductase activity and hydroxylamine reductase activity under different treatments Different letters in the same growth period among the treatments mean significant difference (P<0.05)"

Fig. 4

Dynamic changes of soil N2O emission flux during tomato growth period"

"

处理
Treatment		 排放总量
Total emissions (kg·hm-2)		 排放系数
Emission coefficient (%)
CK 1.56±0.23d -
N1 2.54±0.17c 0.49
N2 4.87±0.21b 0.83
N3 7.13±0.11a 0.89

Table 3

Correlation analysis of soil N2O emission fluxes with environmental factors and inorganic nitrogen contents"

5 cm土温
5 cm soil temperature		 土壤含水量
Soil water content		 0-10 cm土层硝态氮含量
Nitrate nitrogen content in
0-10 cm soil layer		 0-10 cm土层铵态氮含量
Ammonium nitrogen content in
0-10 cm soil layer
CK 0.278 0.134 0.124 0.102
N1 0.319** 0.158 0.506** 0.155
N2 0.401** 0.237 0.766** 0.351
N3 0.445** 0.352 0.820** 0.512**

Table 4

Correlation analysis between soil nitrogen invertase activity and N2O emission flux"

N2O排放通量
N2O emission flux		 UR活性
UR activity		 NR活性
NR activity		 Ni R活性
Ni R activity		 Hy R活性
Hy R activity
N2O排放通量 N2O emission flux 1 -0.055 0.516** 0.163 0.757**
UR活性 UR activity 1 0.704** 0.843** 0.567**
NR活性 NR activity 1 0.605** 0.712**
Ni R活性 Ni R activity 1 0.566**
Hy R活性 Hy R activity 1
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