Scientia Agricultura Sinica ›› 2019, Vol. 52 ›› Issue (22): 4166-4176.doi: 10.3864/j.issn.0578-1752.2019.22.020

• CULTIVATION·PHYSIOLOGY • Previous Articles     Next Articles

Responses of Fertilization on Sorghum Grain Yield, Quality and Nutrient Utilization to Soil Fertility

WANG JinSong1,DONG ErWei1,WU AiLian1,BAI WenBin2,WANG Yuan1,JIAO XiaoYan1()   

  1. 1 Institute of Agricultural Environment and Resources, Shanxi Academy of Agricultural Sciences, Taiyuan 030031
    2 Institute of Sorghum, Shanxi Academy of Agricultural Sciences, Jinzhong 030600, Shanxi
  • Received:2019-05-31 Accepted:2019-07-01 Online:2019-11-16 Published:2019-11-16
  • Contact: XiaoYan JIAO E-mail:jiaoxiaoyan@sxagri.ac.cn

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Abstract:

【Objective】Responses of sorghum grain yield , quality and NPK utilization to inherent soil fertility, and their interaction were explored to provide theoretical basis for best nutrient management according to soil fertility. 【Method】Pot experiment was conducted in greenhouse. Soil was collected from three treatments of long-term fertilizer application experiment for 6 years, which were without fertilizer, NPK application and NPK application along with animal manure and straw returning to field, respectively. They were termed as low soil fertility (LSF), medium soil fertility (MSF) and high soil fertility (HSF), correspondingly. For each soil fertility, there were two treatments for pot experiment: without fertilizer (NF) and fertilizer application (CF). Plant and grain of sorghum were harvested after maturity. NPK accumulation in plant above ground and grain were calculated according to NPK concentration and biomass of each part of plant. The contents of starch, tannic and protein of grain were determined. 【Result】For LSF, MSF and HSF, a similar biomass and yield were gained if fertilizer was applied. They were significantly affected by inherent soil fertility if fertilizer was withdrawn. Soil fertility did not affect starch content of grain, which was 67.99%-69.33%, if fertilizer was not applied. However, HSF combined with fertilizer application resulted in 60.75% starch content in grain. For all treatments, the highest of tannin content was observed in grain of LSF without fertilizer. Fertilizer application significantly decreased tannin content of grain when sorghum was cultivated with LSF and HSF, only 70% of that was produced by LSF combined with NF. Protein content was promoted with the increase of inherent soil fertility, and was doubled by fertilizer application whatever soil fertility was. When fertilizer was applied, the contributions of soil fertility to yield were 90.25%, 51.75% and 8.5% for LSF, MSF and HSF, respectively. NPK accumulation of both grain and plant aboveground was regulated by inherent soil fertility. Fertilizer enhanced NPK absorption for all soil fertility treatments. For example, N accumulation in grain and plant, induced by fertilizer application, were 1.8 and 1.9 times of those when fertilizer was withdrawn under conditions of HSL. NPK harvest indices were enhanced by fertilizer application if soil fertility was either low or medium; whereas diminished NPK harvest indices were noticed with high soil fertility.【Conclusion】The potential sorghum grain yield can be gained for low soil fertility by means of fertilizer application. Without fertilizer, inherent soil fertility has a significant effect on grain yield. However its impacts on content of starch, tannin and protein can be neglected. Low soil fertility, combined withdrawn fertilizer, promotes starch and tannin accumulation in grain. Fertilizer application has relative more influence on grain protein content than soil fertility does. Fertilizer application diminishes nutrient harvest index and nutrient use efficiency if inherent soil fertility is high.

Key words: sorghum, inherent soil fertility, grain quality, nutrient accumulation

Table 1

Soil basic chemical properties"

土壤肥力
Soil fertility		 有机质
OM (g·kg-1)		 全氮
Total N (g·kg-1)		 硝态氮
NO3--N (mg·kg-1)		 有效磷
Available P (mg·kg-1)		 速效钾
Available K (mg·kg-1)
LSF 7.84±0.70 0.71±0.01 19.44±0.07 3.97±0.23 145.36±1.34
MSF 8.89±1.03 0.95±0.04 33.34±0.12 6.97±0.52 217.72±2.68
HSF 18.48±2.43 1.39±0.01 70.45±0.29 21.23±0.61 357.75±1.16

Fig. 1

Effects of fertilization on biomass and grain yields with different soil fertility LSF: Low soil fertility; MSF: Medium soil fertility; HSF: High soil fertility; NF: Without fertilization; CF: With fertilization. Different lowercase letter indicates significant differences at 0.05 level. The same as below"

Table 2

Effects of fertilization on grain quality with different soil fertility"

土壤肥力
Soil fertility		 处理
Treatment		 总淀粉
Total starch
(%)		 淀粉组成 单宁
Tannic
(g·kg-1)		 蛋白质
Protein
(g·kg-1)
直链淀粉
Amylose (%)		 支链淀粉
Amylopectin (%)
LSF NF 69.69±0.47a 20.66±0.10a 79.34±0.10a 13.69±0.86a 50.98±2.73d
CF 67.99±0.53bc 20.83±0.87a 79.17±0.87a 10.53±0.28b 108.13±2.72b
MSF NF 69.33±0.52ab 20.67±0.50a 79.33±0.50a 10.67±0.69b 51.75±0.86d
CF 65.50±1.61c 20.89±0.50a 79.11±0.50a 10.07±0.61b 118.13±2.53a
HSF NF 69.70±0.27a 21.32±0.57a 78.68±0.57a 10.78±0.34b 68.54±1.71c
CF 60.75±2.13d 22.45±0.84a 77.55±0.84a 7.80±0.42c 117.19±0.54a
土壤肥力Soil fertility (S) * NS NS ** **
施肥处理Fertilizer (F) ** NS NS ** **
肥力×施肥 S×F * NS NS NS **

Fig. 2

Contribution of soil fertility and its effect on fertilizer contribution to sorghum yield"

Table 3

Effects of fertilization on nutrient accumulation of grain and total nutrient accumulation above ground with different soil fertility"

土壤处理
Treatment soil		 处理
Treatment		 籽粒吸收量
Accumulation of grain (mg/pot)		 地上部吸收量
Total accumulation above ground (mg/pot)		 收获指数
Harvest index (%)
N P K N P K N P K
LSF NF 24.20±0.49e 7.13±0.33d 9.33±0.34e 58.28±2.56f 9.54±0.27d 144.06±5.98e 41.76±2.78e 74.90±4.05c 6.48±0.04c
CF 524.87±12.17b 76.43±5.14b 100.13±4.64c 731.26±70.72c 84.74±5.19b 731.99±24.56c 71.76±0.64a 90.14±1.08a 13.74±1.01a
MSF NF 123.86±4.37d 33.07±1.42c 51.41±2.24d 207.61±4.08e 40.14±2.20c 455.44±9.36d 59.63±1.01d 82.49±0.97b 11.31±0.70b
CF 586.47±15.67b 87.45±2.52b 122.07±4.86a 861.91±21.15b 98.88±3.81b 1002.71±14.98b 68.05±0.93b 88.50±0.84ab 12.17±0.30b
HSF NF 319.42±5.00c 81.76±2.80b 103.91±2.20b 481.63±4.20d 93.89±1.58b 1033.12±28.62b 66.31±0.47b 87.05±2.08ab 10.08±0.48b
CF 597.11±5.90a 90.04±1.52a 116.60±8.51b 924.92±20.45a 113.15±1.01a 1167.32±15.55a 64.59±0.79bc 79.59±1.48bc 9.97±0.60b
土壤肥力
Soil fertility (S)		 ** ** ** ** ** ** ** NS **
施肥处理
Fertilizer (F)		 ** ** ** ** ** ** ** ** **
肥力×施肥
S×F		 ** ** ** ** ** ** ** ** **

Fig. 3

Effects of soil fertility on soil nutrient dependence,fertilizer recovery efficiency and partial factor productivity of fertilizer"

Fig. 4

Effects of soil fertility and fertilization on nitrogen, phosphorus, potassium use efficiency of grain"

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