Scientia Agricultura Sinica ›› 2018, Vol. 51 ›› Issue (21): 4030-4039.doi: 10.3864/j.issn.0578-1752.2018.21.003

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

The Increasing Effect and Influencing Factors of Leguminous Green Manure on Wheat Grain Zn in Weibei Highland

YiXuan LIU1(),DongLin HUANG1(),Na LIU1,ZhiYuan YAO1,Dan YIN1,YuanYong MENG1,HuBing ZHAO1,YaYun GAO1,ZhaoHui WANG1,2   

  1. 1College of Natural Resources and Environment, Northwest A&F University/Key Laboratory of Plant Nutrition and Agro-Environment in Northwest China, Ministry of Agriculture, Yangling 712100, Shaanxi
    2Northwest A&F University/ State Key Laboratory of Crop Stress Biology in Arid Areas, Yangling 712100, Shaanxi
  • Received:2018-05-10 Accepted:2018-09-29 Online:2018-11-01 Published:2018-11-01
  • Contact: YiXuan LIU,DongLin HUANG E-mail:liuyixuan930720@126.com;dlynnhuang@nwafu.edu.cn

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Abstract:

【Objective】Weibei Highland is one of important winter wheat production areas in northwest China, where Zn concentration in wheat grain are generally low due to soil bioavailable Zn deficiency. So we decided to study leguminous green manure-wheat rotations whether could improve wheat Zn concentration in different regions of Weibei Highland, and to explore the factors affecting wheat Zn biofortification by leguminous green manure-wheat rotations.【Method】Two field experiments were carried out during 2016-2017 cropping seasons in Yongshou and Changwu with a completely randomized block design. There were three main treatments: Summer fallow-wheat (FW) as CK, black kidney bean-wheat (KW) and mung bean-wheat (MW) in Yongshou; Summer fallow-wheat (FW) as CK, huai bean-wheat (HW) and mung bean-wheat (MW) in Changwu. Plant samples of legumes, wheat and 0-20 cm soil samples at different wheat growing stages were collected for chemical analysis. 【Result】 In Yongshou, compare with FW, wheat grain yield and biomass were decreased by 19.2%-38.3% under leguminous green manure-wheat rotations,. In Changwu, leguminous green manure-wheat rotations did not significantly reduce wheat grain yield, but reduced wheat glumes and straw biomass by 19.9%-33.2%. KW rotation in Yongshou and HW rotation in Changwu significantly increased grain Zn concentration by 14.2% and 18.6%, respectively, which partially compensated the potential reduction of wheat grain Zn export and aboveground shoot Zn uptake by increasing Zn concentrations of wheat grain and straw Zn concentration due to the shrink of wheat yield and biomass. There was no significant difference of wheat Zn uptake between HW and FW treatments in Changwu. Wheat grain Zn concentration was positively correlated with leguminous manure shoot Zn uptake. Wheat grain Zn concentration increases 0.23 mg·kg -1 when green manure shoot Zn uptake increases 1.0 g·hm -2, correspondingly. Besides, the Zn, N content of black kidney bean and huai bean were both higher than that of mung bean. Moreover, compared with mung bean, C/N of black kidney bean and huai bean were lower by 18.6% and 20.4%, respectively. At wheat maturity stage, soil nitrate of KW and HW rotations were both higher than that of FW by 36.7% and 69.1%, respectively. Leguminous green manure-wheat rotations had rarely significant effect on soil DTPA-Zn concentration during the growth of wheat.【Conclusion】Relatively higher Zn and N content and lower in C/N of black kidney bean and huai bean made them more readily improved subsequently wheat Zn uptake and accumulation than that of mung bean. The positive correlation between wheat grain Zn concentration and leguminous green manure shoot Zn uptake could be the guidance for screening and optimizing green manure varieties for wheat Zn biofortification. Therefore, leguminous green manure-wheat rotations could be an effective biofortification method to enhance wheat Zn nutrition for residents which suffered from Zn deficiency.

Key words: Weibei highland, leguminous green manure, rotation, winter wheat, grain, Zn concentration

Fig. 1

Precipitation from 2016 to 2017 and 25 year average precipitation (from 1992 to 2016)"

Table 1

Physical and chemical properties of tested soils (0-20 cm)"

地点
Site		 有机质
Organic matter (g·kg-1)		 全氮
Total N
(g·kg-1)		 有效磷
Olsen-P
(mg·kg-1)		 速效钾
Available K
(mg·kg-1)		 矿质氮Inorganic nitrogen DTPA-Zn
(mg·kg-1)		 pH
NO3--N
(mg·kg-1)		 NH4+-N
(mg·kg-1)
永寿县Yongshou 12.92 0.82 11.2 134.0 11.9 4.75 0.44 8.5
长武县Changwu 11.80 0.77 4.5 131.9 13.1 2.55 0.33 8.1

Table 2

Effects of different leguminous green manure-wheat rotations on yield, biomass and harvest index of winter wheat"

地点
Site		 处理
Treatment		 籽粒产量
Grain yield (kg·hm-2)		 颖壳生物量
Glume biomass (kg·hm-2)		 茎叶生物量
Stem biomass (kg·hm-2)		 地上部生物量
Shoot biomass (kg·hm-2)		 收获指数
Harvest index (%)
永寿
Yongshou		 休闲—小麦FW 4272a 1373a 5008a 10652a 40.5a
黑麦豆—小麦KW 3053b 854b 3092b 6999b 43.8a
绿豆—小麦MW 3452b* 984 ab* 3698b* 8135b* 42.5a
平均Mean 3592 1070 3933 8595 42.3
长武
Changwu		 休闲—小麦FW 2624a 967a 3444a 7036a 37.3a
怀豆—小麦HW 2291a 759b 2583b 5633b 40.6a
绿豆—小麦MW 2246a 646b 2547b 5458b 40.9a
平均Mean 2387 791 2858 6042 39.6

Fig. 2

Effects of different leguminous green manure-wheat rotations on Zn concentration of winter wheat (mg·kg-1) Different small letters above the bars with the same symbols indicate significant differences at 0.05 level among different leguminous green manure-wheat rotation treatments at the same site. * indicates significant differences at 0.05 level between mung bean-wheat rotation treatment at Yongshou and Changwu"

Table 3

Effects of different leguminous green manure-wheat rotations on Zn accumulation and Zn harvest index of winter wheat"

地点
Site		 处理
Treatments		 锌累积量 Zn content (g·hm-2) 锌收获指数
Zn harvest index (%)
籽粒 Grain 颖壳 Glume 茎叶 Stem 地上部 Shoot
永寿
Yongshou		 休闲—小麦FW 92.3a 6.0a 25.7a 124.0a 74.8a
黑麦豆—小麦KW 71.0c 4.8a 17.9a 93.8c 75.7a
绿豆—小麦MW 78.3b* 5.7a* 24.3a* 108.3b* 72.3a
平均Mean 80.5 5.5 22.7 108.7 74.3
长武
Changwu		 休闲—小麦FW 40.8a 4.1a 9.9a 54.9a 74.5a
怀豆—小麦KW 42.6a 3.7a 11.0a 57.3a 74.3a
绿豆—小麦MW 36.9a 2.8a 7.9a 47.6a 77.3a
平均Mean 40.1 3.5 9.6 53.2 75.4

Table 4

Shoot biomass and chemical properties of leguminous green manures"

地点
Site		 处理
Treatment		 生物量
Biomass
(kg·hm-2)		 锌含量
Zn concentration (mg·kg-1)		 锌吸收量
Zn uptake
(g·hm-2)		 C/N 氮含量
N concentration
(g·kg-1)		 氮吸收量
N uptake
(kg·hm-2)
永寿
Yongshou		 黑麦豆—小麦KW 1886a 21.9b 41.4a 13.1b 33.5a 63.2a
绿豆—小麦 MW 1520 b 25.2a* 38.5a* 16.1a 26.0b 39.5b
长武
Changwu		 怀豆—小麦 KW 1242a 20.4a 25.4a 13.3b 32.8a 40.8a
绿豆—小麦MW 1294a 13.6b 17.7a 16.7a 25.4b 32.7a

Fig. 3

Correlation between wheat grain Zn concentration and leguminous green manure Zn uptake"

Table 5

Effects of different leguminous green manure rotations on the DTPA-Zn and NO3- in 0-20 cm soil at the critical growing stages of wheat (mg·kg-1)"

地点
Site		 处理
Treatment		 土壤有效锌含量DTPA-Zn 土壤硝态氮含量NO3--N content
绿肥翻压前
GMI		 小麦播前
SOW		 小麦收获期
MAT		 小麦播前
SOW		 小麦收获期
MAT
永寿
Yongshou		 休闲—小麦FW 0.23b 0.23a 0.52a 9.2a 3.0b
黑麦豆—小麦KW 0.29ab 0.27a 0.44a 8.8a 4.1a
绿豆—小麦MW 0.30a 0.29a 0.47a 5.0b 3.6ab
平均Mean 0.28 0.26 0.48 7.7 3.6
长武
Changwu		 休闲—小麦FW 0.36a 0.34a 0.47a 15.3a 9.7b
怀豆—小麦HW 0.35a 0.37a 0.45a 14.6a 16.4a
绿豆—小麦MW 0.34a 0.39a 0.44a 16.4a* 13.2ab*
平均Mean 0.35 0.37 0.45 15.4 13.1
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