Ren Sanxue, Zhao Huarong, Qi Yue, et al. The outbreak and damage of the Pleonomus canaliculatus in wheat field under the background of climate change. J Appl Meteor Sci, 2020, 31(5): 620-630. DOI:  10.11898/1001-7313.20200509.
Citation: Ren Sanxue, Zhao Huarong, Qi Yue, et al. The outbreak and damage of the Pleonomus canaliculatus in wheat field under the background of climate change. J Appl Meteor Sci, 2020, 31(5): 620-630. DOI:  10.11898/1001-7313.20200509.

The Outbreak and Damage of the Pleonomus Canaliculatus in Wheat Field Under the Background of Climate Change

DOI: 10.11898/1001-7313.20200509
  • Received Date: 2020-03-01
  • Rev Recd Date: 2020-06-02
  • Publish Date: 2020-09-30
  • In recent years, with the large-scale implementation of conservation tillage measures and crop straw crushing in North China, the winter wheat and summer corn are planted in two crops per year, creating a favorable environment for feeding and habituating for the Pleonomus canaliculatus. As the temperature in autumn, winter and spring of Gucheng Station in Hebei Province alternates between cold and warm from 2018 to 2019, the minimum temperature is significantly higher, inducing the explosive occurrence of the Pleonomus canaliculatus in the wheat field. According to the investigation of spring wheat field excavation, the maximum density of insect population is 144 heads·m-2, the maximum weight of insect population is 18.764 g·m-2. Among 58 investigation points, densities of 57 points exceed 5 heads·m-2, which calls for control measures. The density of insects in the jointing-harvest period is the highest during the booting period, followed by the jointing period, and that of the harvest period is the lowest. The oldest larvae have a maximum length of 34.68 mm, and a maximum width of 4.9 mm, 4.68 mm longer and 0.90 mm wider comparing to existing record respectively. The density of insect populations in the continuous cropping winter wheat and summer maize gramineous crops is 35.3 to 40.4 heads·m-2, which is significantly higher than that of soybean, corn, and winter wheat recreation grounds. The peanut and spring corn lands are more than 5 times higher than the soybean insect population density, and the weight of insect population is more than 10 times higher. Yield measurement in mature wheat fields shows the grain yield is reduced by 36.8%. When the insect population density increases by 10 heads·m-2, grain yield decreases by 4.824%. When insect population weight increases by 1 g·m-2, grain yield reduction increases by 3.871%, and 10% increase of plant pest will make the grain yield reduction rate increase by 11.587%.
  • Fig. 1  Daily temperature anomaly at Gucheng Station from 1 Oct 2018 to 30 Apr 2019

    Fig. 2  Monthly temperature anomaly and extreme minimum temperature anomaly at Gucheng Station from Oct 2018 to Apr 2019

    Fig. 3  Density of Pleonomus canaliculatus in the wheat field at Gucheng Station in spring of 2019

    Fig. 4  Weight of Pleonomus canaliculatus in the wheat field at Gucheng Station in spring of 2019

    Fig. 5  Pest rate of Pleonomus canaliculatus in the wheat field at Gucheng Station in spring of 2019

    Fig. 6  Relationship of Pleonomus canaliculatus density, weight, pest rate to grain yield reduction

    Table  1  Investigation on Pleonomus canaliculatus in the winter wheat field at Gucheng Station in 2019

    调查时段 地段 沟金针虫数量/(头·m-2) 最大沟金针虫 沟金针虫
    重量/(g·m-2)
    总数量 长度/mm 宽度/mm
    返青-拔节期 麦田A 20.7 12.3 15.0 48.0 28.71 3.67 5.764
    麦田B 24.2 15.0 15.8 55.0 28.05 3.82 7.095
    孕穗期 麦田A 12.0 11.2 31.6 54.8 29.81 4.17 5.849
    麦田B 24.0 30.7 34.7 89.4 29.00 3.92 9.465
    收获期 麦田A 7.0 0.6 2.4 10.0 26.00 4.05 1.107
    麦田B 21.0 11.2 10.6 42.8 26.34 3.92 3.983
    DownLoad: Download CSV

    Table  2  Comparison of Pleonomus canaliculatus between winter wheat, summer maize continuous cropping and leisure land at Gucheng Station in 2019

    调查地段 沟金针虫数量/(头·m-2) 最大沟金针虫 沟金针虫
    重量/(g·m-2)
    总数量 长度/mm 宽度/mm
    前茬大豆 1.0 1.2 1.6 3.8 23.72 3.45 0.311
    前茬冬小麦 4.3 0.3 0.0 4.6 25.81 3.70 0.732
    前茬春玉米 12.6 4.0 3.3 19.9 25.72 3.55 1.791
    前茬夏玉米 11.4 5.4 4.2 21.0 24.63 3.61 1.934
    冬小麦与夏玉米连作A 30.6 7.2 2.6 40.4 29.40 4.09 5.520
    冬小麦与夏玉米连作B 27.8 6.0 1.5 35.3 30.93 4.03 5.416
    DownLoad: Download CSV

    Table  3  Investigation on Pleonomus canaliculatus in the leisure land at Gucheng Station in 2019

    调查地段 沟金针虫数量/(头·m-2) 最大沟金针虫 沟金针虫
    重量/(g·m-2)
    总数量 长度/mm 宽度/mm
    前茬大豆地 0.0 1.7 3.3 5.0 17.20 2.42 0.187
    前茬花生地 4.7 4.0 18.0 26.7 24.90 3.55 1.399
    前茬春玉米A 10.3 8.3 8.0 26.5 27.80 3.48 2.444
    前茬春玉米B 13.3 7.3 7.7 28.3 29.03 3.60 2.905
    前茬夏玉米A 5.7 2.0 1.3 9.0 25.95 3.65 1.239
    前茬夏玉米B 4.3 3.0 0.3 7.6 27.07 3.74 0.754
    前茬夏玉米C 5.3 1.0 0.3 6.6 27.00 3.47 0.828
    DownLoad: Download CSV
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    • Received : 2020-03-01
    • Accepted : 2020-06-02
    • Published : 2020-09-30

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