Scientia Agricultura Sinica ›› 2022, Vol. 55 ›› Issue (14): 2762-2774.doi: 10.3864/j.issn.0578-1752.2022.14.007

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

Yield of Wheat and Maize and Utilization Efficiency of Nitrogen, Phosphorus and Potassium in Xinjiang

TANG MingYao1,2(),SHEN ChongYang2,CHEN ShuHuang3,TANG GuangMu3,LI QingJun3,YAN CuiXia1,GENG QingLong3,FU GuoHai4()   

  1. 1. Xinjiang Soil and Fertilizer Station, Urumqi 830006
    2. College of Land Science and Technology, China Agricultural University, Beijing 100193
    3. Institute of Soil Fertilizer and Agricultural Water Saving, Xinjiang Academy of Agricultural Sciences, Urumqi 830091
    4. National Agricultural Technology Extension Service Center, Beijing 100125
  • Received:2021-04-28 Accepted:2021-05-31 Online:2022-07-16 Published:2022-07-26
  • Contact: GuoHai FU E-mail:78291308@qq.com;fuguohai@agri.gov.cn

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Abstract:

【Objective】The objectives of the present paper were to understand current status of fertilizer utilization efficiency of wheat and maize in Xinjiang, to optimize their nutrient management, and to improve fertilizer utilization efficiency, so as to provide basic data and technique support for the food security of Xinjiang and as well as all the country. 【Method】72 field trials (40 for wheat and 32 for maize) were carried out in main grain growing areas of Xinjiang from 2018 to 2020. Four different treatments of fertilizer application were designed, including nitrogen, phosphorus and potassium (NPK), no nitrogen (PK), no phosphorus (NK), and no potassium (NP). Each experiment was conducted in triplicate. Then, the nutrient uptake of main grain crops, the response of nitrogen, phosphorus, and potassium fertilizers, the agronomic efficiency, the utilization rate and other parameters were examined under the current conditions of fertilization for agricultural production in Xinjiang. 【Result】(1) The average application amounts of N, P and K fertilizers for wheat in Xinjiang were 233.1 kg N·hm-2, 128.0 kg P2O5·hm-2 and 75.5 kg K2O·hm-2, respectively; the average application amounts of N, P and K fertilizers for maize were 254.9 kg N·hm-2, 148.0 kg P2O5·hm-2 and 67.8 kg K2O·hm-2, respectively. (2) The wheat yield of per unit area was 7 505 kg·hm-2 under NPK treatment, and the yield responses of N, P and K fertilizers were 2 206 kg·hm-2 (500-3 795 kg·hm-2), 2016 kg·hm-2 (288-4 230 kg·hm-2), and 1 362 kg·hm-2 (105-2 910 kg·hm-2), respectively. The average rates of yield increase for N, P and K fertilizers were 45.0%, 39.7% and 23.0%, respectively. The yield per unit area of maize under NPK treatment was 13 715 kg·hm-2, and the yield responses of N, P and K fertilizers were 4 657 kg·hm-2 (1 559-6 900 kg·hm-2), 1 942 kg·hm-2 (473-4 699 kg·hm-2), and 1 297 kg·hm-2 (113-5 440 kg·hm-2), respectively. The average rates of yield increase for N, P and K fertilizers were 52.2%, 21.2%, and 15.5%, respectively. (3) The uptakes of N and K by wheat and maize were relatively large, whereas the uptake of phosphorus was relatively small. The application of chemical fertilizers could significantly promote the uptake of nitrogen, phosphorus and potassium by plants, and increase the accumulation of nitrogen, phosphorus and potassium in soil. For NPK treatment, it required 2.7 kg (1.7-4.0 kg) of nitrogen (N), 0.8 kg (0.4-1.3 kg) of phosphorus (P2O5), and 2.1 kg (1.2-3.9 kg) of potassium (K2O) to form 100 kg of grains for wheat; for maize using the NPK treatment, it required 2.1 kg (1.5-2.9 kg) of nitrogen (N), 0.8 kg (0.4-1.2 kg) phosphorus (P2O5), and 2.1 kg (0.7-3.4 kg) of potassium (K2O) to form 100 kg of grains. (4) The agronomic efficiency of nitrogen fertilizer for maize was higher than that of wheat. There were no significant differences in the agronomic efficiencies of phosphorus and potassium fertilizers. The agronomic efficiencies of N, P and K fertilizers for wheat were 9.6, 15.9 and 18.7 kg·kg-1, respectively. Therefore, the agronomic efficiencies of P and K fertilizers were significantly higher than that of nitrogen fertilizer. The agronomic efficiencies of nitrogen, phosphorus, and potassium fertilizers for maize were 18.7, 13.4 and 18.1 kg·kg-1, respectively, N and K fertilizers were significantly higher than P fertilizer. (5) The utilization rates of N, P and K fertilizers for wheat were 41.4%, 21.8% and 45.2%, respectively. The utilization rates of N, P and K fertilizers for maize were 46.9%, 20.5% and 49.6%, respectively. The N and K utilization efficiency for wheat and maize were significantly higher than that of P. 【Conclusion】To date, the yield of wheat and maize in Xinjiang was high, the utilization efficiency of nitrogen, phosphorus and potassium was at a high level, and the utilization efficiency of nitrogen and potassium was significantly higher than that of phosphorus. In Xinjiang, wheat and maize yield was most sensitive to nitrogen deficiency. The phosphorus deficiency had lower influence on the wheat and maize yield, and the potassium deficiency had the lowest reduction. The amount of nitrogen application applied to wheat and maize in Xinjiang was reasonable. In contrast, the amount of potassium application was seriously insufficient. The excessive application of phosphate in wheat existed. In the future, it was necessary to increase the input of potassium fertilizer for wheat and maize and to reduce the input of phosphorus fertilizer for wheat.

Key words: Xinjiang, wheat, maize, chemical fertilizer, yield, fertilizer utilization efficiency

Table 1

Average content of major nutrients in topsoil of Xinjiang with 6 996 samples"

土壤养分
Nutrient		 平均值
Mean		 标准差
SD
pH 8.2 0.4
有机质 OM (g·kg-1) 18.8 14.2
全氮 Total nitrogen (g·kg-1) 0.9 0.5
碱解氮 Alkali-hydro nitrogen (mg·kg-1) 69.3 38.4
有效磷 Available phosphorus (mg·kg-1) 23.4 20.6
速效钾 Available potassium (mg·kg-1) 211.4 146.1

Fig. 1

Distribution of wheat and maize experimental sites in Xinjiang"

Fig. 2

Frequency distribution of N, P2O5 and K2O application amounts of wheat and maize in Xinjiang"

Table 2

Yield (kg·hm-2) and relative yield (%) of nitrogen, phosphorus and potassium fertilizer application for wheat and maize in Xinjiang"

作物
Crop		 产量/相对产量
Yield or relative yield		 最小值
Min.		 最大值
Max.		 平均值
Mean		 标准差
SD		 25%数
25Q		 50%数
50Q		 75%数
75Q
小麦Wheat
(n=40)		 NPK处理产量 NPK yield 3987 9270 7504 a 1242 6728 7290 8385
PK处理产量PK yield 2398 7080 5298 c 1182 4155 5428 6225
NK处理产量 NK yield 2441 6945 5488 c 1090 4500 5820 6387
NP处理产量 NP yield 2901 8081 6142 b 937 5820 6300 6465
缺氮相对产量Relative yield to N application 50.3% 92.1% 70.4% 9.8% 62.0% 69.9% 73.5%
缺磷相对产量Relative yield to P application 53.2% 95.1% 73.6% 12.3% 63.0% 71.7% 82.9%
缺钾相对产量Relative yield to K application 68.6% 98.4% 82.7% 10.6% 70.9% 84.5% 92.7%
玉米 Maize
(n=32)		 NPK处理产量 NPK yield 8612 17430 13715 a 2017 12045 13530 15240
PK处理产量 PK yield 5964 13035 9058 d 2061 7230 8865 10725
NK处理产量 NK yield 7848 15270 11773 c 1817 10425 11340 13065
NP产量 NP yield 8004 16275 12418 b 2197 10575 11910 14226
缺氮相对产量Relative yield to N application 48.9% 86.9% 65.7% 9.0% 58.3% 63.8% 74.2%
缺磷相对产量Relative yield to P application 69.2% 96.4% 86.0% 5.9% 82.5% 86.6% 88.4%
缺钾相对产量Relative yield to K application 64.3% 99.2% 90.4% 7.1% 86.6% 91.8% 94.4%

Fig. 3

Yield response to applied N, P2O5 and K2O in the NPK treatments for wheat and maize in Xinjiang The different letters represent the significant difference at P<0.05, the hollow circle and the short line indicate median and mean, respectively. The box boundaries indicate the upper and lower quartiles, the whisker caps indicate 95th and 5th percentiles, the circles circle indicate maximum and minimum"

Fig. 4

N, P and K uptake of wheat and maize with different fertilizer treatments in Xinjiang For a given treatment, different letters above the bars mean significant at P<0.05 level"

Table 3

Agronomic efficiency of nitrogen, phosphorus and potassium fertilizer applied to NPK treatment of wheat and maize in Xinjiang (kg·kg-1)"

作物
Crop		 化肥种类
Chemical fertilizer		 最小值
Min.		 最大值
Max.		 平均值
Mean		 标准差
SD		 25%数
25Q		 50%数
50Q		 75%数
75Q
小麦 Wheat
(n=40)		 氮肥 Nitrogen fertilizer 1.9 18.3 9.6 b 3.6 8.2 9.1 10.4
磷肥 Phosphorus fertilizer 2.3 33.9 15.9 a 8.2 10.1 15.8 18.9
钾肥 Potassium fertilizer 3.1 60.3 18.7 a 13.6 9.3 16.9 21.9
玉米 Maize
(n=32)
氮肥 Nitrogen fertilizer 6.9 28.6 18.7 a 5.8 13.8 18.3 23.4
磷肥 Phosphorus fertilizer 2.9 27.2 13.4 b 6.1 9.2 13.2 16.0
钾肥 Potassium fertilizer 1.9 60.5 18.1 a 11.1 9.8 16.0 23.2

Table 4

Fertilizer use efficiency (%) of applied N, P2O5 and K2O of NPK treatment for wheat and maize in Xinjiang"

作物
Crop		 化肥种类
Chemical fertilizer		 最小值
Min.		 最大值
Max.		 平均值
Mean		 标准差
SD		 25%数
25Q		 50%数
50Q		 75%数
75Q
小麦 Wheat
(n=40)		 氮肥 Nitrogen fertilizer 29.0 59.4 41.4 a 6.5 36.3 40.9 44.2
磷肥 Phosphorus fertilizer 6.2 40.1 21.8 b 7.9 16.0 21.1 27.1
钾肥 Potassium fertilizer 18.3 62.3 45.2 a 11.6 35.4 47.1 53.8
玉米 Maize
(n=32)		 氮肥 Nitrogen fertilizer 37.5 60.3 46.9 a 5.8 41.0 46.3 49.8
磷肥 Phosphorus fertilizer 12.2 31.5 20.5 b 3.7 17.7 19.7 23.0
钾肥 Potassium fertilizer 32.9 66.4 49.6 a 8.0 42.4 50.7 54.2
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