Scientia Agricultura Sinica ›› 2020, Vol. 53 ›› Issue (1): 29-41.doi: 10.3864/j.issn.0578-1752.2020.01.003

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY·AGRICULTURE INFORMATION TECHNOLOGY • Previous Articles     Next Articles

Effects of Straw Returning Amount on Grain Yield, Dry Matter Accumulation and Transfer in Summer Maize with Different Genotypes

XinYuan MU1,Xia ZHAO1,LiMin GU1,BaoYi JI2,Yong DING1,FengQi ZHANG1,Jun ZHANG1,JianShuang QI1,ZhiYan MA1,LaiKun XIA1(),BaoJun TANG1()   

  1. 1 Cereal Institute, Henan Academy of Agricultural Sciences/Henan Provincial Key Laboratory of Maize Biology, Zhengzhou 450002
    2 Xinyang Agriculture and Forestry University, Xinyang 464000, Henan
  • Received:2019-05-05 Accepted:2019-07-03 Online:2020-01-01 Published:2020-01-19
  • Contact: LaiKun XIA,BaoJun TANG E-mail:xialaikun@126.com;henan.maize@163.com

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Abstract:

【Objective】 Scientific and objective evaluation of the comprehensive effect of straw returning is important to improve the utilization rate of straw resources and to promote the green and sustainable development of agriculture. In this study, a field located experiment was conducted in wheat-maize cropping system on the North China Plain, to clarify the responses of different genotypes summer maize to various straw returning amounts. The purpose of this paper was to provide support for the comprehensive evaluation of the straw returning technology and for the optimization of straw returning amount. 【Method】 The experiment was conducted from October 2017 to October 2018 at Yuanyang, Henan province. The experimental design was a split plot. The main plot was four straw returning amount, no straw returning to field (S0), 50% amount of straw returning to field (S1), 100% amount of straw returning to field (S2) and 200% amount of straw returning to field (S3), and the subplot was genotype, including XD20 and ZD958. The differences in leaf area index (LAI), dry matter accumulation and transfer, and grain yield under different treatments were analyzed. 【Result】 Compared with no straw returning to field, the straw returning increased LAI after silking, and there was a significant interaction between genotypes and straw returning amount on LAI. At anthesis stage, the LAI of XD20 and ZD958 increased with the increasing of straw returning amount, and were the highest under S3 treatment. At maturity stage, with the increasing of straw returning amount, the decline in LAI for XD20 and ZD958 showed a trend of first decreasing and then increasing, and was the lowest under S1 for XD20 and S2 for ZD958. In addition, the LAI of XD20 and ZD958 at maturity stage showed a trend of first rising and then falling with the increasing of straw returning amount, and were the highest under S1 for XD20 and S2 for ZD958. Higher post-silking LAI was conducive to maintain higher post-silking dry matter production capacity, eventually significantly increased post-silking dry matter accumulation and optimize dry matter accumulation and distribution characteristics. The interaction of genotype and straw returning amount significantly affected the dry matter remobilization (DMR), dry matter remobilization efficiency (DMRE), contribution of dry matter remobilization to grain (DMRCG), dry matter accumulation after anthesis (DMAA) and contribution of dry matter accumulation after anthesis to grain (DMAACG). With the increasing of straw returning amount, DMR, DMRE and DMRCG of the vegetative organs (stem sheath + leaf) in XD20 firstly decreased and then increased, and were the lowest under S1 treatment. Meanwhile, DMAA and DMAACG showed an increasing trend first and then a decreasing trend, which were the highest under S1 treatment. The DMR, DMRE, DMRCG and DMAA of the vegetative organs (stem sheath + leaf) of ZD958 all showed an ascending and then descending trend with increasing of straw returning amount, and those were the highest under S2 treatment. The increase of dry matter accumulation was beneficial to increase grain weight and grain yield. Compared with S0 treatment, S1, S2 and S3 treatment improved the grain yield, but the grain yield did not increase continuously with the increasing of straw returning amount. For XD20, the highest grain yield was obtained under S1 treatment, which was 3.5% to 17.7% averagely higher than other treatments. For ZD958, the highest grain yield was achieved under S2 treatment, which was 0.4% to 16.8% averagely higher than other treatments. 【Conclusion】 Our results showed that, for wheat-maize cropping system on the North China Plain, appropriate amount of straw to the field could delay the leaf senescence process in the later growth stage of maize, optimize the dry matter accumulation and distribution characteristics, improve the post-silking dry matter accumulation and grain weight, and thereby improve the grain yield of maize. However, the responses of different maize cultivars to straw returning amount vary greatly. When promoting straw returning to the field, the effects of crop genetic factors on straw returning should also be considered.

Key words: straw returning amount, summer maize, genotypes, dry matter, remobilization

Table 1

The total amount of maize and wheat straw each year"

年度
Year		 冬小麦季全量玉米秸秆
The total maize straw in winter wheat season (kg·hm-2)		 夏玉米季全量小麦秸秆
The total wheat straw in summer maize season (kg·hm-2)
2015-2016 7816.5 8092.8
2016-2017 7661.1 8804.4
2017-2018 7566.2 7685.7

Table 2

LAI as affected by the summer maize genotypes and straw returning amount"

基因型
Genotype		 秸秆还田量
Straw returning amount		 2017 2018
LAIa LAIm LAIa LAIm
浚单20
XD20		 S0 3.42±0.31b 0.66±0.08b 3.30±0.19a 0.75±0.02b
S1 4.11±0.49ab 1.16±0.06a 3.58±0.18a 1.31±0.05a
S2 4.10±0.28ab 1.02±0.03ab 3.60±0.33a 1.25±0.07a
S3 4.63±0.20a 0.79±0.04ab 3.64±0.31a 0.77±0.03b
均值 Mean 4.06 0.91 3.53 1.02
郑单958
ZD958		 S0 3.32±0.08a 1.86±0.07b 3.11±0.13b 1.74±0.11b
S1 3.71±0.09a 2.11±0.13ab 3.49±0.30ab 2.27±0.25a
S2 3.75±0.37a 2.21±0.28ab 3.57±0.10ab 2.64±0.07a
S3 4.05±0.17a 2.26±0.01a 3.89±0.11a 2.43±0.21a
均值 Mean 3.70 2.11 3.52 2.27
方差分析
ANOVA (F-value)		 G 3.22 190.38** 0.01 188.16**
S 3.99* 3.61* 1.99 11.05**
G×S 0.25 1.65 0.52 3.33*

Table 3

Dry matter accumulation as affected by the summer maize genotypes and straw returning amount"

基因型
Genotype		 秸秆还田量
Straw returning amount		 开花期 Anthesis stage (g/plant) 成熟期 Maturity stage (g/plant)
叶片
Leaf		 茎鞘
Stem+sheath
Ear		 总重
Total		 叶片
Leaf		 茎鞘
Stem+sheath		 苞轴
Cob+husk		 籽粒
Grain		 总重
Total
浚单20
XD20		 S0 36.3±1.8a 41.2±2.1a 8.6±0.6b 86.1±4.5b 22.2±3.2ab 40.2±1.4ab 19.4±1.2b 118.7±1.3b 200.5±0.5b
S1 40.9±2.0a 51.9±3.9a 12.7±1.2a 105.5±6.1a 28.3±1.7a 49.9±4.8a 26.7±3.1a 157.1±14.4a 261.9±23.4a
S2 41.2±0.9a 49.2±3.3a 11.1±1.3ab 101.5±4.9ab 27.4±1.8ab 47.0±2.5ab 24.2±3.3ab 143.3±7.0ab 241.9±11.7a
S3 42.0±2.5a 52.0±6.6a 10.0±1.4b 103.9±9.4ab 20.5±1.7b 37.6±2.6b 20.2±1.6b 122.9±7.9b 201.1±11.7b
均值 Mean 40.1 48.6 10.9 99.3 24.6 43.7 22.4 135.5 226.4
郑单958
ZD958		 S0 34.0±1.4c 43.1±2.9c 6.7±0.1a 83.8±3.0b 30.8±2.3a 41.6±2.9b 26.7±1.9a 130.1±12.0b 229.2±13.2b
S1 35.5±1.7bc 44.3±4.5bc 7.8±0.8a 87.6±6.0b 31.6±2.1a 42.0±5.8b 29.1±2.5a 144.3±2.0ab 247.0±11.7b
S2 39.9±1.2ab 56.4±3.0ab 8.8±1.2a 105.2±1.8a 37.0±2.5a 55.4±2.7a 32.6±0.7a 164.0±3.0a 289.0±1.8a
S3 42.2±0.5a 60.0±1.3a 9.6±0.7a 111.8±1.2a 36.6±2.1a 51.0±0.6ab 28.5±1.9a 160.5±2.8a 276.6±4.6a
均值 Mean 37.9 51.0 8.2 97.1 34.0 47.5 29.2 149.7 260.5
方差分析
ANOVA (F-value)		 G 2.83 0.82 14.22** 0.34 36.09** 2.71 19.63** 4.52* 13.53**
S 6.16** 4.94** 3.83* 6.87** 2.30 3.38* 3.14* 5.00* 6.02**
G×S 1.36 2.05 2.60 2.77 2.82 3.93* 0.98 5.31* 6.07**

Table 4

Dry matter transfer before and after anthesis and their contribution to grain dry matter as affected by the summer maize genotypes and straw returning amount"

基因型
Genotype		 秸秆还田量
Straw returning amount		 花前 Before anthesis 花后
After anthesis
叶片 Leaf 茎鞘 Stem+sheath
DMR
(g/plant)		 DMRE
(%)		 DMRCG
(%)		 DMR
(g/plant)		 DMRE
(%)		 DMRCG
(%)		 DMAA
(g/plant)		 DMAACG
(%)
浚单20
XD20		 S0 14.1±1.9b 39.2±4.6b 11.9±1.7b 1.0±0.4b 2.4±0.3b 0.8±0.1b 114.4±9.0b 87.3±2.0a
S1 12.6±0.6b 30.9±1.3b 8.2±0.7b 2.0±0.8b 4.1±0.1b 1.4±0.4b 156.4±9.3a 90.5±1.3a
S2 13.8±2.2b 33.4±5.0b 9.7±1.6b 2.3±0.3b 4.6±0.6b 1.6±0.2b 140.4±5.6ab 88.8±1.4a
S3 20.5±3.0a 49.6±5.3a 16.9±3.2a 14.4±2.0a 27.5±1.2a 12.0±1.0a 97.2±8.9c 71.1±3.8b
均值 Mean 15.3 38.3 11.6 4.9 9.7 4.0 126.9 84.4
郑单958
ZD958		 S0 3.2±0.9a 9.3±1.2a 2.6±0.5a 1.5±0.3c 3.5±0.5c 1.1±0.1c 145.4±6.9b 96.3±0.9a
S1 3.9±0.7a 11.1±1.1a 2.9±0.4a 2.3±0.4bc 5.7±0.5bc 1.7±0.3bc 159.4±2.9b 95.3±0.7a
S2 5.3±0.7a 12.5±1.9a 3.2±0.7a 4.6±0.5ab 7.8±0.9ab 2.8±0.4ab 183.8±1.5a 94.0±0.5a
S3 3.3±0.5a 8.1±1.2a 2.0±0.3a 5.4±0.6a 9.2±1.6a 3.4±0.7a 164.8±6.0a 94.6±2.3a
均值 Mean 3.9 10.3 2.7 3.5 6.5 2.3 163.4 95.0
方差分析
ANOVA (F-value)
 G 103.05** 151.40** 75.22** 5.83* 27.52** 22.35** 27.86** 61.89**
S 2.11 2.14 2.69 42.75** 135.89** 78.46** 4.41* 11.81**
G×S 3.30* 4.89* 4.34* 18.26** 72.52** 43.98** 10.07** 10.50**

Table 5

Yield and its components as affected by the summer maize genotypes and straw returning amount"

基因型
Genotype		 秸秆还田量
Straw returning amount		 2017 2018
公顷穗数
Ear number
(No./hm2)		 穗粒数
Grain number per ear		 百粒重
100-grain weight (g)		 产量
Yield
(kg·hm-2)		 公顷穗数
Ear number
(No./hm2)		 穗粒数
Grain number per ear		 百粒重
100-grain weight (g)		 产量
Yield
(kg·hm-2)
浚单20
XD20		 S0 66700a 509.4b 24.8b 6822.4b 66422a 484.3a 24.9b 6881.4b
S1 66144a 545.5ab 27.2a 8065.3a 68645a 488.3a 27.2a 8062.6a
S2 67256a 537.4ab 26.9a 7951.4a 65033a 507.7a 26.7ab 7626.0ab
S3 65588a 567.8a 24.5b 7543.9ab 65866a 525.0a 25.2ab 7393.8ab
均值 Mean 66422 540.0 25.7 7595.8 66492 501.3 26.0 7490.9
郑单958
ZD958		 S0 65866a 495.8a 28.5a 7729.0b 67311a 497.0a 28.9a 7885.4b
S1 65088a 500.2a 28.7a 8210.7ab 66811a 506.0a 29.6a 8195.7b
S2 67978a 503.2a 30.6a 8900.2ab 64810a 516.5a 30.8a 9340.6a
S3 66811a 511.4a 29.5a 9058.9a 67423a 536.7a 30.7a 9102.0ab
均值 Mean 66436 502.7 29.3 8474.7 66589 514.1 30.0 8630.9
方差分析
ANOVA (F-value)		 G 0.12 4.69* 56.17** 8.71** 0.99 0.70 71.56** 20.41**
S 0.44 1.77 4.76* 3.21* 0.73 1.39 3.93* 3.72*
G×S 0.20 0.28 2.58 0.80 0.90 0.02 1.77 2.22
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