Scientia Agricultura Sinica ›› 2018, Vol. 51 ›› Issue (18): 3531-3541.doi: 10.3864/j.issn.0578-1752.2018.18.009

• SOIL & FERTILIZER·WATER-SAVING IRRIGATION·AGROECOLOGY & ENVIRONMENT • Previous Articles     Next Articles

Research of the Irrigation Mode Controlled by Cumulative Radiation on Tomato Growth and Water and Fertilizer Utilization in Greenhouse

XiaoRan WEI(), RuiFeng CHENG(), QiChang YANG, YongKang HE, Chen ZHANG   

  1. Institute of Environment and Sustainable Development in Agriculture, Chinese Academy of Agricultural Sciences/ Key Laboratory of Energy Conservation and Waste Management of Agricultural Structures, Ministry of Agriculture, Beijing 100081
  • Received:2018-03-08 Accepted:2018-05-16 Online:2018-09-16 Published:2018-09-16

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Abstract:

【Objective】 Under the irrigation mode controlled by cumulative radiation, the objective of this paper was to study on the effects of different irrigation amount on tomato growth, water and fertilizer utilization in tomato flowering and fruit-set stage, so as to provide the scientific basis for tomato efficient production in Chinese solar greenhouse. 【Method】 Under the condition of soil ridge substrate embedded cultivation to test “harvest” hybrid tomato by the nutrient solution drip irrigation, irrigation mode was divided into regular time interval irrigation (hereinafter referred to as “normal irrigation”, CK) and irrigation controlled by cumulative radiation, which was divided into low irrigation (T1), middle irrigation (T2) and high irrigation (T3). It researched on the irrigation modes and amount difference of growth, development, and water and fertilizer utilization in tomato flowering and fruit-set stage. 【Result】Compared with CK, the irrigation amount of T1, T2 and T3 reduced by 39.3%, 30.3% and 14.0%, respectively. The greater irrigation amount was, the higher substrate moisture content was, as follow: CK > T3 > T2 > T1. Irrigation mode controlled by cumulative radiation was better for tomato vegetative and reproductive growth, and significantly improved tomato biomass. Compared with treatment CK, the tomato biomass of T1, T2 and T3 had increased by 57.1%, 75.3% and 32.7%, respectively. Among them, the tomato biomass of treatment T2 was 102.9 g·plant-1, which was also significantly higher than that of T1 and T3. Controlled by cumulative radiation, irrigation amount on sunny day was more than that on cloudy day, and irrigation amount on noon time was more than that on morning and afternoon, which was more consistent with the plant's demand for water and fertilizer. Besides, it saved the water and fertilizer and avoided the waste of water and fertilizer. Compared with CK, the drainage rate of T3 on sunny and cloudy day reduced by 62.5% and 72.6%, respectively. The suitable irrigation amount controlled by cumulative radiation also significantly improved tomato yield and irrigation water utilization efficiency. Compared with CK, the tomato yield of T2 was improved by 14.2%, reached to 61.3 t·hm-2, and the irrigation water utilization efficiency was improved by 34.1%. Too little irrigation amount inhibited the production of plants. 【Conclusion】 Irrigation mode controlled by cumulative radiation could promote growth and effectively save water and fertilizer. Among them, the irrigation amount of T2 was 533.0 m3·hm-2, which could be used as a referenced nutrient solution for tomato flowering and fruit-set stage in Chinese solar greenhouse.

Key words: cumulative radiation, irrigation amount, water and fertilizer utilization, flowering and fruit-set stage, tomato

Fig. 1

Schematic diagram of soil ridge substrate-embedded cultivation method"

Fig. 2

Schematic diagram of experiment arrangement"

Table 1

The irrigation amounts and nutrient rates"

时期
Time		 处理
Treatment		 每次灌溉量
Each irrigation amount (m3·hm-2)		 总灌溉量
Total irrigation amount (m3·hm-2)		 施肥量 Nutrient rates(kg·hm-2
N P2O5 K2O
花期
Flowering stage		 CK 1.3 319.3 51.8 28.9 83.1
T1 2.0 199.8 32.4 18.1 52.0
T2 2.3 229.0 37.2 20.8 59.6
T3 2.5 258.3 41.9 23.4 67.2
坐果期
Fruit-set stage		 CK 2.3 445.8 72.3 40.4 116.1
T1 2.3 264.8 43.0 24.0 68.9
T2 2.5 304.0 49.3 27.6 79.1
T3 3.5 399.8 64.8 36.2 104.1

Fig. 3

Changed situation of substrate moisture content under continual overcast day(Nov.10-Nov.16, 2017)"

Fig. 4

Changed situation of substrate moisture content under continual sunny day(Dec.5-Dec.11, 2017)"

Fig. 5

Effects of different treatments on height and stem thickness of tomato plants"

Fig. 6

Effect of different treatments on tomato biomass"

Fig. 7

Irrigation pattern controlled by cumulative radiation (Dec.1-Dec.6) The dotted line is cumulative solar radiation threshold"

Table 2

Irrigation and drainage amount of tomato under different irrigation modes"

日期
Date		 天气
Weather		 灌溉量Irrigation amount (m3·hm-2) 排出量Drainage amount (m3·hm-2) 排出率Drainage ratio (%)
CK T1 T2 T3 CK T3 CK T3
Dec. 1 多云Cloudy 21.3 10.6 11.8 17.1 10.2 1.8 47.9 10.5
Dec. 2 阴 Overcast 20.7 5.8 7.1 10.3 10.4 1.2 50.3 11.8
Dec. 3 阴 Overcast 21.4 7.7 9.4 13.5 11.1 2.5 51.8 18.8
Dec. 4 晴 Sunny 22.7 9.7 11.8 16.8 6.4 2.0 28.3 12.1
Dec. 5 晴 Sunny 22.3 9.7 11.8 16.8 6.1 1.5 27.4 8.7
Dec. 6 晴 Sunny 22.0 10.7 11.8 16.8 6.5 1.9 29.7 11.4

Fig. 8

Effects of different treatments on yield and irrigation water utilization efficiency"

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