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Acta Agronomica Sinica ›› 2022, Vol. 48 ›› Issue (11): 2891-2907.doi: 10.3724/SP.J.1006.2022.14206

• TILLAGE & CULTIVATION·PHYSIOLOGY & BIOCHEMISTRY • Previous Articles     Next Articles

Characteristics of water supply-demand equilibrium and water production benefits of the dryland multiple cropping patterns in the Yangtze River basin

ZHANG Jia-Yun1(), MA Shu-Mei2, YU Chang-Bing3, WANG Shu-Bin4, WEI Ya-Feng5, YANG Wen-Yu1, WANG Xiao-Chun1,*()   

  1. 1College of Agronomy, Sichuan Agricultural University / Key Laboratory of Crop Ecophysiology and Farming System in Southwest China, Ministry of Agriculture and Rural Affairs / Crop Ecophysiology and Cultivation Key Laboratory of Sichuan Province, Chengdu 611130, Sichuan, China
    2Crop Research Institute of Hunan Province, Changsha 410125, Hunan, China
    3Oil Crops Research Institute, Chinese Academy of Agricultural Sciences, Wuhan 430062, Hubei, China
    4College of Agronomy, Jiangxi Agricultural University, Nanchang 330045, Jiangxi, China
    5Jiangsu Yanjiang Institute of Agricultural Sciences, Nantong 226541, Jiangsu, China
  • Received:2021-11-03 Accepted:2022-03-25 Online:2022-11-12 Published:2022-04-20
  • Contact: WANG Xiao-Chun E-mail:3305298443@qq.com;xchwang@sicau.edu.cn
  • Supported by:
    The National Key Research and Development Program of China(2016YFD0300209)

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Abstract:

The seasonal drought is a serious problem because of the unevenly distributed rainfall during the years in the Yangtze River basin. To construct multi-cropping patterns of intercropping with drought avoidance and disaster reduction as the main body is the fundamental way to realize the efficient utilization of water resources. Therefore, we carried out dryland multiple cropping patterns evaluation in test in the Yangtze River (Sichuan, Hubei, Hunan, Jiangxi, and Jiangsu) from 2016 to 2020, the cropping patterns was set as wheat-summer maize (C1), wheat-summer maize ‖ summer soybean (C2), forage rape-spring maize/summer soybean (C3), and potato-spring maize/summer soybean (C4) in Sichuan. Rape-maize‖summer soybean (B1), forage rape-spring maize ‖ spring soybean (B2), and potato / spring maize / summer soybean (B3) in Hubei; rape-maize ‖ summer soybean (N1), forage rape-spring maize/summer soybean (N2), and forage rape-spring maize ‖ spring soybean-autumn soybean (N3) in Hunan; potato/spring maize/summer soybean (X1), rape-maize ‖ summer soybean (X2), ryegrass-spring maize/summer soybean (X3), and ryegrass-spring maize ‖ spring soybean (X4). Wheat-fresh maize/fresh maize (S1), wheat-fresh maize/fresh soybean (S2), fresh broad bean/fresh maize-fresh maize (S3), and fresh broad bean/fresh maize-fresh soybean (S4) in Jiangsu. We compared the characteristics of supply-demand equilibrium, the paddy of the overall productions and the water benefits of different cropping patterns with the AquaCrop model. These results showed that the water satisfy rate of C4 was 5.28%, 2.91%, and 6.00% higher than C1, C2, and C4, and the paddy of the overall production was 71.2%, 49.3%, and 25.6% higher, respectively, and the water benefit was 329.29%, 123.42%, and 45.52% higher in Sichuan. The water satisfy rate of B3 was 3.99% and 3.51% higher than B1 and B2, and the paddy of the overall production was 36.8% and 25.8% higher, and the water benefit was 295.60% and 69.01% higher in Hubei, respectively. The water satisfy rate of N2 was 9.08% and 2.93% higher than N1 and N3, and the water benefit was 58.47% and 183.33% higher in Hunan, respectively. The water satisfy rate of X1 was 7.94%, 6.70%, and 4.05% higher than X2, X3, and X4, and paddy of the overall production was 112.4%, 152.5%, and 116.8% higher, respectively, and the water benefit was 97.03%, 126.14%, and 77.68% higher in Jiangxi, respectively. The water satisfy rate of S4 was 7.94%, 6.70%, and 4.05% higher than X2, X3, and X4, and paddy of the overall production was respectively 35.4%, 17.5%, and 12.6% higher, and the water benefit was 60.25%, 14.93%, and 45.56% higher in Jiangsu, respectively. Potato-spring maize/summer soybean in Sichuan, potato/spring maize/summer soybean in Hubei, forage rape-spring maize/summer soybean in Hunan, potato/spring maize/summer soybean in Jiangxi and fresh broad bean/fresh maize-fresh soybean in Jiangsu were the appropriate cropping patterns that can improve the water supply-demand equilibrium, paddy of the overall production, and water benefit. To avoid seasonal drought and achieve annual high yield, the appropriate multiple cropping patterns of intercropping should be selected depending on the rainfall conditions in the dryland of the Yangtze River basin.

Key words: Yangtze River basin, multiple cropping patterns, water supply-demand equilibrium, water benefit

Table 1

Basic information of different test sites of different regions in the Yangtze River basin"

试验点
Test plot		 经度
Longitude		 纬度
Latitude		 土壤
Soil		 海拔
Elevation (m)		 平均气温
Average
temperature (℃)		 无霜期
Frost-free season (d)		 全年日照
Year-round sunshine (h)
四川 Sichuan 109.13 29.99 棕紫泥土 Brown purple soil 500 16-18 230-340 1000-1400
湖北 Hubei 109.47 30.29 黄壤黏土 Yellow soil clay 900 15-17 230-300 1400-2200
湖南 Hunan 112.90 28.68 红土 Red soil 500 15-17 253-311 1400-2200
江西 Jiangxi 115.89 28.68 红土 Red soil 25-30 17-18 240-307 1400-2200
江苏 Jiangsu 120.55 32.37 黄棕土 Yellow brown soil 2-6 14-16 256-326 2200-3000

Table 2

Multiple cropping patterns of dry land of different regions in the Yangtze River basin"

地区Region 种植模式Cropping pattern
四川仁寿
Renshou, Sichuan		 C1: 小麦-夏玉米 Wheat-Summer maize
C2: 小麦-夏玉米‖夏大豆 Wheat-Summer maize‖Summer soybean
C3: 饲草油菜-春玉米/夏大豆 Forage rape-Spring maize/Summer soybean
C4: 马铃薯-春玉米/夏大豆 Potato-Spring maize/Summer soybean
湖北恩施
Enshi, Hubei		 B1: 油菜-夏玉米‖夏大豆 Rape-Summer maize‖Summer soybean
B2: 饲草油菜-春玉米‖春大豆 Forage rape-Spring maize‖Spring soybean
B3: 马铃薯/春玉米/夏大豆 Potato/Spring maize/Summer soybean
湖南湘阴
Xiangyin, Hunan		 N1: 油菜-夏玉米‖夏大豆 Rape-Summer maize‖Summer soybean
N2: 饲草油菜-春玉米/夏大豆 Forage rape-Spring maize/Summer soybean
N3: 饲草油菜-春玉米‖春大豆-秋大豆Forage rape-Spring maize‖Spring soybean-Autumn soybean
江西南昌
Nanchang, Jiangxi		 X1: 马铃薯/春玉米/夏大豆 Potato/Spring maize/Summer soybean
X2: 油菜-夏玉米‖夏大豆 Rape-Summer maize‖Summer soybean
X3: 黑麦草-春玉米/夏大豆 Ryegrass-Spring maize/Summer soybean
X4: 黑麦草-春玉米‖春大豆 Ryegrass-Spring maize‖Spring soybean
江苏如皋
Rugao, Jiangsu		 S1: 小麦-鲜食玉米/鲜食玉米 Wheat-Fresh maize/Fresh maize
S2: 小麦-鲜食玉米/鲜食大豆 Wheat-Fresh maize/Fresh soybean
S3: 鲜食蚕豆/鲜食玉米-鲜食玉米 Fresh broad bean/Fresh maize-Fresh maize
S4: 鲜食蚕豆/鲜食玉米-鲜食大豆 Fresh broad bean/Fresh maize-Fresh soybean

Table 3

Varieties and densities of different crops"

地区
Region		 冬季作物
Winter crop		 品种
Variety		 密度
Density
(×104 plants hm-2)		 其他作物
Other crops		 品种
Variety		 密度
Density
(×104 plants hm-2)
四川仁寿
Renshou, Sichuan		 小麦
Wheat		 蜀麦969
Shumai 969		 240 玉米
Maize		 荣玉1210
Rongyu 1210		 6
饲草油菜
Forage rape		 德选油 569
Dexuanyou 569		 18 大豆
Soybean		 南豆 25
Nandou 25		 15
马铃薯
Potato		 费乌瑞它
Feiwuruita		 10
湖北恩施Enshi,
Hubei		 饲草油菜
Forage rape		 大地199
Dadi 199		 4.5 玉米
Maize		 青青500
Qingqing 500		 4.5
马铃薯
Potato		 鄂马铃薯10号
Emalingshu 10		 5.5 春大豆
Spring soybean		 05-48 12
油菜
Rape		 大地199
Dadi 199		 1.5 夏大豆
Summer soybean		 十月黄
Shiyuehuang		 12
湖南湘阴Xiangyin, Hunan 油菜
Rape		 沣油823
Fengyou 823		 25 玉米
Maize		 登海605
Denghai 605		 6
饲草油菜
Forage rape		 油肥1号
Youfei 1		 25 春大豆
Spring soybean		 湘春豆24
Xiangchundou 24		 16.5
夏大豆
Summer soybean		 中豆41
Zhongdou 41		 16.5
秋大豆
Autumn soybean		 湘春豆24
Xiangchundou 24		 25
江西南昌Nanchang, Jiangxi 油菜
Rape		 沣油730
Fengyou 730		 30 玉米
Maize		 登海605
Denghai 605		 6
马铃薯
Potato		 田园春
Tianyuanchun		 2.5 春大豆
Spring soybean		 天隆2号
Tianlong 2		 12
黑麦草
Ryegrass		 鑫大叶
Xindaye		 850 夏大豆
Summer soybean		 南豆12
Nandou 12		 12
江苏如皋Rugao,
Jiangsu		 小麦
Wheat		 扬麦16
Yangmai 16		 240 鲜食玉米
Fresh maize		 苏玉糯14
Suyunuo 14		 6
鲜食蚕豆
Fresh broad bean		 通蚕鲜7号
Tongcanxian 7		 7.5 鲜食大豆
Fresh soybean		 通豆6号
Tongdou 6		 15

Table 4

Fertilizing amount of different crops (kg hm-2)"

肥料
Fertilizer		 玉米(鲜食)
Maize
(fresh)		 大豆(鲜食)
Soybean (fresh)		 小麦
Wheat		 油菜
Rape		 饲草油菜
Forage rape		 马铃薯
Potato		 黑麦草
Ryegrass		 鲜食蚕豆
Fresh broad bean
四川仁寿Renshou, Sichuan
尿素 Urea 489 0 326 293 326
过磷酸钙(含P2O5 12%)
Ca(H2PO4)2·H2O		 625 375 90 375 250
氯化钾(含K2O 60%) KCl 125 0 90 75 250
湖北恩施Enshi, Hubei
复合肥Complex fertilizer (15%N-15%P-15%K) 60 30 50 50 50
生物有机肥Bio-organic fertilizer 50 0 50 100 100
尿铵磷(含N 29%, P2O5 12%)
Urine ammonium phosphate		 100 0 0 100 100
湖南湘阴Xiangyin, Hunan
尿素 Urea 300 75 150 75
复合肥Complex fertilizer (15%N-15%P-15%K) 600 225 600 0
钙镁磷肥(含P 15%)
Calcium magnesium phosphate		 750 750 750 0
江西南昌Nanchang, Jiangxi
尿素 Urea 0 0 450 750 0
复合肥Complex fertilizer
(15%N-15%P-15%K)		 391 75 112 0 0
过磷酸钙(含P2O5 12%)
Ca(H2PO4)2·H2O		 600 600 0 0 0
氯化钾(含K2O 60%) KCl 150 150 0 0 0
江苏如皋Rugao, Jiangsu
尿素 Urea 375 225 175 375
复合肥Complex fertilizer (15%N-15%P-15%K) 600 0 200 0

Table 5

Sowing and harvest time of combined crops of different cropping patterns (month/day)"

地区
Region		 种植
模式
Patterns		 第1熟 1st mature 第2熟 2nd mature 第3熟 3rd mature 第4熟 4th mature
播种日期
Sowing date		 收获日期
Harvest date		 播种日期
Sowing date		 收获日期
Harvest date		 播种日期
Sowing date		 收获日期
Harvest date		 播种日期
Sowing date		 收获日期
Harvest date
四川仁寿Renshou, Sichuan C1 11/1 5/15 5/16 9/14
C2 11/1 5/15 5/16 9/14 6/5 10/31
C3 11/1 3/30 4/1 7/31 6/5 10/31
C4 12/1 4/20 4/21 8/20 6/5 10/31
湖北恩施Enshi,
Hubei		 B1 11/4 5/16 6/5 9/12 7/8 11/3
B2 10/30 4/16 4/19 8/12 4/29 8/5
B3 12/27 6/7 4/19 9/12 7/8 11/3
湖南湘阴Xiangyin, Hunan N1 10/10 5/5 5/24 9/27 5/24 9/29
N2 11/18 3/23 4/6 7/27 5/24 9/29
N3 11/18 3/23 4/6 7/27 4/16 7/21 8/5 11/10
江西南昌Nanchang, Jiangxi X1 1/13 5/24 4/6 7/25 6/14 11/5
X2 11/25 4/25 6/14 8/30 6/14 11/5
X3 11/25 3/18 4/6 7/25 6/14 11/5
X4 11/25 3/18 4/6 7/25 4/6 7/13
江苏如皋Rugao, Jiangsu S1 11/7 6/1 6/27 9/5 7/29 10/28
S2 11/7 6/1 6/27 9/5 7/29 10/21
S3 11/7 5/22 4/4 7/18 7/29 10/28
S4 11/7 5/22 4/4 7/18 7/29 10/21

Table 6

Average marker prices for different crops of different regions in the Yangtze River basin (Yuan kg-1)"

地区
Region		 玉米(鲜食)
Maize (fresh)		 大豆(鲜食)
Soybean (fresh)		 小麦
Wheat		 马铃薯
Potato		 油菜
Rape		 饲草油菜(鲜重)
Forage rape		 黑麦草
(鲜重)
Ryegrass		 鲜食蚕豆
Fresh broad bean
四川仁寿Renshou, Sichuan 2.0 5 2.0 1.2 0.2
湖北恩施Enshi, Hubei 2.0 6 1.7 6.0 0.4
湖南湘阴Xiangyin, Hunan 2.0 5.0 6.0 0.2
江西南昌Nanchang, Jiangxi 1.7 4.6 2 6.0 0.3
江苏如皋Rugao, Jiangsu 1.5 3.0 2.0 1.0

Fig. 1

Comparison of simulated and observed yield"

Fig. 2

Relative wetting index (M) of different regions in the Yangtze River basin in 1990 and 2020"

Fig. 3

Water demand of different crops"

Table 7

Water supply-demand equilibrium of different patterns in Sichuan"

种植模式
Cropping pattern		 项目
Item		 2017 2018 2019 2020 平均
Mean
C1 需水量Water demand (mm) 637.9 645.4 631.4 751.4 666.5
耗水量Water consumption (mm) 443.0 513.9 487.9 517.3 490.5
盈亏量Deficiency (mm) -194.9 -131.5 -143.5 -234.1 -176.0
水分满足率Water satisfy rate (%) 69.5 79.6 77.3 68.8 73.8
C2 需水量Water demand (mm) 639.1 657.9 645.1 750.9 673.2
耗水量Water consumption (mm) 460.2 531.9 511.2 525.7 507.2
盈亏量Deficiency (mm) -179.0 -126.0 -133.9 -225.1 -166.0
水分满足率Water satisfy rate (%) 72.0 80.8 79.3 70.0 75.5
C3 需水量Water demand (mm) 553.4 567.5 570.1 642.3 583.3
耗水量Water consumption (mm) 400.9 425.0 440.7 441.4 427.0
盈亏量Deficiency (mm) -152.6 -142.5 -129.4 -200.8 -156.3
水分满足率Water satisfy rate (%) 72.4 74.9 77.3 68.7 73.3
C4 需水量Water demand (mm) 552.8 546.5 532.5 632.0 565.9
耗水量Water consumption (mm) 410.2 453.0 441.7 447.9 438.2
盈亏量Deficiency (mm) -142.6 -93.5 -90.8 -184.1 -127.7
水分满足率Water satisfy rate (%) 74.2 82.9 83.0 70.9 77.7

Table 8

Water supply-demand equilibrium of different patterns in Hubei"

种植模式
Cropping pattern		 项目
Item		 2017 2018 2019 2020 平均
Mean
B1 需水量Water demand (mm) 573.4 562.5 529.0 516.0 545.2
耗水量Water consumption (mm) 525.2 443.8 477.0 467.0 478.2
盈亏量Deficiency (mm) -48.1 -118.8 -52.0 -49.0 -67.0
水分满足率Water satisfy rate (%) 91.6 78.9 90.2 90.5 87.8
B2 需水量Water demand (mm) 572.4 536.9 519.6 515.8 536.2
耗水量Water consumption (mm) 525.2 472.2 463.5 433.3 473.5
盈亏量Deficiency (mm) -47.2 -64.7 -56.1 -82.6 -62.7
水分满足率Water satisfy rate (%) 91.8 88.0 89.2 84.0 88.2
B3 需水量Water demand (mm) 512.9 515.6 461.7 445.1 483.8
耗水量Water consumption (mm) 478.3 463.6 419.1 406.5 441.9
盈亏量Deficiency (mm) -34.6 -52.0 -42.6 -38.6 -41.9
水分满足率Water satisfy rate (%) 93.3 89.9 90.8 91.3 91.3

Table 9

Water supply-demand equilibrium of different patterns in Hubei"

种植模式
Cropping pattern		 项目
Item		 2017 2018 2019 2020 平均
Mean
N1 需水量Water demand (mm) 736.4 798.0 721.7 708.6 741.2
耗水量Water consumption (mm) 607.3 588.2 532.4 648.3 594.0
盈亏量Deficiency (mm) -129.2 -209.9 -189.3 -60.3 -147.1
水分满足率Water satisfy rate (%) 82.5 73.7 73.8 91.5 80.4
N2 需水量Water demand (mm) 645.1 665.6 591.4 587.1 622.3
耗水量Water consumption (mm) 600.7 552.5 471.8 557.8 545.7
盈亏量Deficiency (mm) -44.4 -113.1 -119.6 -29.2 -76.6
水分满足率Water satisfy rate (%) 93.1 83.0 79.8 95.0 87.7
N3 需水量Water demand (mm) 874.7 898.7 831.5 803.6 852.1
耗水量Water consumption (mm) 799.8 718.7 636.1 747.0 725.4
盈亏量Deficiency (mm) -74.9 -180.0 -195.4 -56.5 -126.7
水分满足率Water satisfy rate (%) 91.4 80.0 76.5 93.0 85.2

Table 10

Water supply-demand equilibrium of different patterns in Jiangxi"

种植模式
Cropping pattern		 项目
Item		 2017 2018 2019 2020 平均
Mean
X1 需水量Water demand (mm) 417.7 446.9 480.2 405.6 437.6
耗水量Water consumption (mm) 385.1 418.9 438.7 374.8 404.4
盈亏量Deficiency (mm) -32.5 -28.0 -41.5 -30.8 -33.2
水分满足率Water satisfy rate (%) 92.2 93.7 91.4 92.4 92.4
X2 需水量Water demand (mm) 448.4 474.1 561.4 424.2 477.0
耗水量Water consumption (mm) 406.0 431.5 429.7 356.8 406.0
盈亏量Deficiency (mm) -42.4 -42.6 -131.7 -67.3 -71.0
水分满足率Water satisfy rate (%) 90.5 91.0 76.5 84.1 85.6
种植模式
Cropping pattern		 项目
Item		 2017 2018 2019 2020 平均
Mean
X3 需水量Water demand (mm) 451.7 472.1 500.3 441.1 466.3
耗水量Water consumption (mm) 403.8 430.2 403.6 375.0 403.2
盈亏量Deficiency(mm) -47.9 -41.9 -96.6 -66.1 -63.1
水分满足率Water satisfy rate (%) 89.4 91.1 80.7 85.0 86.6
X4 需水量Water demand (mm) 442.0 436.9 423.5 429.1 432.9
耗水量Water consumption (mm) 395.4 395.8 382.6 363.4 384.3
盈亏量Deficiency (mm) -46.6 -41.1 -41.0 -65.7 -48.6
水分满足率Water satisfy rate (%) 89.5 90.6 90.3 84.7 88.8

Table 11

Water supply-demand equilibrium of different patterns in Jiangsu"

种植模式
Cropping pattern		 项目
Item		 2017 2018 2019 2020 平均
Mean
S1 需水量Water demand (mm) 582.1 559.3 592.2 545.4 569.8
耗水量Water consumption (mm) 505.6 487.3 418.6 523.5 483.7
盈亏量Deficiency (mm) -76.5 -72.0 -173.7 -21.9 -86.0
水分满足率Water satisfy rate (%) 86.9 87.1 70.7 96.0 85.2
S2 需水量Water demand (mm) 589.6 571.3 602.6 555.1 579.6
耗水量Water consumption (mm) 511.8 506.3 424.6 531.3 493.5
盈亏量Deficiency (mm) -77.7 -65.0 -178.0 -23.8 -86.1
水分满足率Water satisfy rate (%) 86.8 88.6 70.5 95.7 85.4
S3 需水量Water demand (mm) 564.2 594.0 591.8 509.5 564.9
耗水量Water consumption (mm) 503.1 516.3 488.0 471.5 494.7
盈亏量Deficiency (mm) -61.1 -77.6 -103.7 -38.1 -70.1
水分满足率Water satisfy rate (%) 89.2 86.9 82.5 92.5 87.8
S4 需水量Water demand (mm) 588.6 631.9 583.9 550.1 588.6
耗水量Water consumption (mm) 533.3 562.4 500.7 528.5 531.2
盈亏量Deficiency (mm) -55.3 -69.5 -83.2 -21.7 -57.4
水分满足率Water satisfy rate (%) 90.6 89.0 85.8 96.1 90.4

Table 12

Paddy of the overall productions of different patterns (kg hm-2)"

地区
Region		 种植模式
Cropping pattern		 2017 2018 2019 2020 平均
Mean
四川仁寿
Renshou,
Sichuan		 C1 14,782.7 13,217.3 14,898.1 14,132.2 14,257.6 d
C2 17,478.0 17,040.5 16,161.6 16,147.8 16,707.0 c
C3 18,996.4 20,438.0 18,609.9 19,453.5 19,374.5 b
C4 26,060.5 25,081.3 25,502.2 21,002.4 24,411.6 a
湖北恩施
Enshi,
Hubei		 B1 16,726.3 18,403.6 18,563.9 24,666.0 19,590.0 c
B2 19,137.3 16,471.1 18,922.0 28,159.4 20,672.4 b
B3 21,684.9 26,342.1 24,064.8 23,657.0 23,937.2 a
湖南湘阴
Xiangyin,
Hunan		 N1 11,626.6 12,350.8 13,593.5 14,508.5 13,019.9 a
N2 12,523.0 12,774.0 10,478.0 13,899.0 12,418.5 a
N3 11,145.4 14,875.4 13,318.4 14,215.1 13,388.6 a
江西南昌
Nanchang,
Jiangxi		 X1 11,313.7 21,516.4 25,112.8 16,966.0 18,727.2 a
X2 12,386.1 10,763.6 9578.8 6337.3 9766.4 c
X3 8813.9 6043.9 11,807.1 8824.9 8872.5 d
X4 10,038.4 7679.2 11,847.8 11,100.3 10,166.4 b
江苏如皋
Rugao,
Jiangsu		 S1 25,378.4 26,777.3 28,487.8 30,542.7 27,796.5 d
S2 29,544.1 30,430.8 29,975.8 36,855.7 31,701.6 c
S3 32,292.9 30,439.9 36,065.5 34,817.7 33,404.0 b
S4 35,090.5 34,012.3 36,823.3 43,326.7 37,313.2 a

Fig. 4

Water benefits of different patterns Abbreviations are the same as those given in Table 2."

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[7] Zhao Qinghua;Huang Jianhua;Yan Changjing. A STUDY ON THE POLLEN GERMINATION OF BRASSICA NAPUS L.[J]. Acta Agron Sin, 1986, (01): 15 -20 .
[8] ZHOU Lu-Ying;LI Xiang-Dong;WANG Li-Li;TANG Xiao;LIN Ying-Jie. Effects of Different Ca Applications on Physiological Characteristics, Yield and Quality in Peanut[J]. Acta Agron Sin, 2008, 34(05): 879 -885 .
[9] WANG Li-Xin; LI Yun-Fu; CHANG Li-Fang; HUANG Lan ;; LI Hong-Bo ; GE Ling-Ling; Liu Li-Hua ;; YAO Ji ;; ZHAO Chang-Ping ;. Method of ID Constitution for Wheat Cultivars[J]. Acta Agron Sin, 2007, 33(10): 1738 -1740 .
[10] ZHENG Tian-Qing;XU Jian-Long;FU Bing-Ying;GAO Yong-Ming;Satish VERUKA;Renee LAFITTE;ZHAI Hu-Qu;WAN Jian-Min;ZHU Ling-Hua;LI Zhi-Kang. Preliminary Identification of Genetic Overlaps between Sheath Blight Resistance and Drought Tolerance in the Introgression Lines from Directional Selection[J]. Acta Agron Sin, 2007, 33(08): 1380 -1384 .
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