黄土高原旱作区糜子-绿豆带状种植农田小气候特征与产量效应

doi:10.13287/j.1001-9332.201810.028

应用生态学报 ›› 2018, Vol. 29 ›› Issue (10): 3256-3266.doi: 10.13287/j.1001-9332.201810.028

黄土高原旱作区糜子-绿豆带状种植农田小气候特征与产量效应

宫香伟¹, 李境¹, 马洪驰¹, 陈光华¹, 王孟², 杨璞¹, 高金锋¹, 冯佰利^1*

¹西北农林科技大学农学院/旱区作物逆境生物学国家重点实验室, 陕西杨凌 712100;
²榆林市农业科学研究院, 陕西榆林 719000

收稿日期:2018-03-08 出版日期:2018-10-20 发布日期:2018-10-20
通讯作者: E-mail: fengbaili@nwsuaf.edu.cn
作者简介:宫香伟,男,1993年生,博士研究生.主要从事作物耕作制度与栽培生理生态技术研究.E-mail: gxw199308@163.com
基金资助:
本文由国家自然科学基金项目(31371529)、国家谷子高粱产业技术体系项目(CARS-13.5-07-A9)、国家科技支撑计划项目(2014BAD07B03)和陕西省小杂粮产业技术体系项目(2009-2018)资助

Field microclimate and yield for proso millet intercropping with mung bean in the dryland of Loess Plateau, Northwest China

GONG Xiang-wei¹, LI Jing¹, MA Hong-chi¹, CHEN Guang-hua¹, WANG Meng², YANG Pu¹, GAO Jin-feng¹, FENG Bai-li^1*

¹College of Agronomy, Northwest A&F University/State Key Laboratory of Crop Stress Biology for Arid Areas, Yangling 712100, Shaanxi, China;
²Yulin Academy of Agriculture Sciences, Yulin 719000, Shaanxi, China

Received:2018-03-08 Online:2018-10-20 Published:2018-10-20
Supported by:
This work was supported by the National Natural Science Foundation of China (31371529), Program on Industrial Technology System of National Millet and Sorghum (CARS-13.5-07-A9), the National Key Research and Development Program of China (2014BAD07B03) and the Minor Coarse Cereals Technique System of Shaanxi Province (2009-2018)

摘要/Abstract

摘要： 基于黄土高原干旱地区生态环境特性,研究了4种糜子(P)-绿豆(M)间作模式下[2∶2(2P2M)、4∶2(4P2M)、4∶4(4P4M)、2∶4(2P4M)]农田小气候特征及产量效应.结果表明: 糜子-绿豆间作模式显著增加了生育后期糜子的株高、叶面积指数(LAI)和叶绿素含量(SPAD),使其达到最佳的生长状态;由于高位糜子的遮阴,导致矮位绿豆阶段性徒长,株高显著增加,而LAI和SPAD均有所下降.糜子-绿豆间作模式降低了糜子籽粒灌浆过程中的群体上层光照度和空气温度,而相对湿度显著上升.地上部气候环境的变化调控了间作体系地下部的土壤温度,减少了群体的漏光损失,使其表现出冷湿的生态环境.而矮位绿豆较差的通风透光条件形成相对封闭的间作系统,抑制了绿豆植株的生长发育,使其处于间作劣势.与单作相比,2P2M、4P2M、4P4M和2P4M处理的糜子单株穗数、穗长、单株粒重和千粒重分别增加了7.5%～45.0%、2.2%～12.2%、35.4%～94.0%和2.3%～4.7%,产量比单作提高了5.6%～20.7%;间作处理下矮位绿豆的分枝数、单株荚数、单株粒重和百粒重均有不同程度的下降,2P4M间作模式下的绿豆受糜子影响最小,产量比单作降低了34.8%.糜子-绿豆间作存在明显的间作优势,各间作处理下的土地当量比(LER)均大于1,2P4M间作模式下的LER达到最大值(1.86).因此,黄土高原地区糜子-绿豆最佳的间作配比为2P4M.

Abstract: Based on the ecological environment features of Loess Plateau, we examined field microclimate characteristics and yield of four different intercropping patterns for proso millet (P) and mung bean (M) including 2:2, 4:2, 4:4, 2:4. The results showed that, compared with monoculture, intercropping increased plant height, leaf area index (LAI) and chlorophyll content (SPAD) of proso millet in its late growth stage, while LAI and SPAD of mung bean decreased due to the shade of the high proso millet. Mung bean appeared spindly growth for a while by increasing the plant height. Moreover, upper canopy illumination and air temperature during grain filling stage of proso millet decreased under intercropping conditions, but relative humidity substantially increased. These changes regulated soil temperature and light leakage, which decreased under intercropping systems, and thereby led to a cold and wet ecological environment. Poor atmospheric and light conditions formed a relative closure growth environment for mung bean, which suppressed its growth. The panicles, spike length, grain mass per plant and 1000-grain mass of proso millet under 2P2M, 4P2M, 4P4M and 2P4M treatments was significantly increased by 7.5%-45.0%, 2.2%-12.2%, 35.4%-94.0% and 2.3%-4.7%, respectively. This caused a 5.6%-20.7% increase of yield than the mono-culture. The branch number, pods per plant, grain mass per plant and 100-grain mass in mung bean were decreased under different intercropping treatments, and the yield was significantly reduced by 34.8%. Land equivalent ratios (LER) of each intercropping pattern were all greater than 1. Among them, LER of 2P4M was the maximum (1.86), and 2P4M treatment held relatively reasonable composite configuration. Our results suggested that 2:4 ratio of proso millet/mung bean intercropping patterns performed better than other ratios on the Loess Plateau.

宫香伟, 李境, 马洪驰, 陈光华, 王孟, 杨璞, 高金锋, 冯佰利. 黄土高原旱作区糜子-绿豆带状种植农田小气候特征与产量效应[J]. 应用生态学报, 2018, 29(10): 3256-3266.

GONG Xiang-wei, LI Jing, MA Hong-chi, CHEN Guang-hua, WANG Meng, YANG Pu, GAO Jin-feng, FENG Bai-li. Field microclimate and yield for proso millet intercropping with mung bean in the dryland of Loess Plateau, Northwest China[J]. Chinese Journal of Applied Ecology, 2018, 29(10): 3256-3266.

参考文献

[1] Han Y-W (韩永伟), Gao J-X (高吉喜), Wang B-L (王宝良), et al. Evaluation of soil conservation function and its values in major eco-function areas of Loess Plateau in eastern Gansu Province. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2012, 28(17): 78-85 (in Chinese)
[2] Xie B-N (谢宝妮), Qin Z-F (秦占飞), Wang Y (王洋), et al. Spatial and temporal variation in terrestrial net primary productivity on Chinese Loess Plateau and its influential factors. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2014, 30(11): 244-253 (in Chinese)
[3] Willey RW. Intercropping: Its importance and research needs. Part 2. Agronomy and research approaches. Field Crop Abstracts, 1979, 32: 73-85
[4] Hauggaardnielsen H, Johansen A, Carter MS, et al. Annual maize and perennial grass-clover strip cropping for increased resource use efficiency and productivity using organic farming practice as a model. European Journal of Agronomy, 2013, 47: 55-64
[5] Hu FL, Gan YT, Chai Q, et al. Boosting system productivity through the improved coordination of interspecific competition in maize/pea strip intercropping. Field Crops Research, 2016, 198: 50-60
[6] Zhang XQ, Huang GQ, Zhao QG. Differences in maize physiological characteristics, nitrogen accumulation, and yield under different cropping patterns and nitrogen levels. Chilean Journal of Agricultural Research, 2014, 74: 326-332
[7] Liu X, Rahman T, Song C, et al. Changes in light environment, morphology, growth and yield of soybean in maize-soybean intercropping systems. Field Crops Research, 2017, 200: 38-46
[8] Feng X-M (冯晓敏), Yang Y (杨永), Ren C-Z (任长忠), et al. Effects of legumes intercropping with oat on photosynthesis characteristics of and grain yield. Acta Agronomica Sinica (作物学报), 2015, 41(9): 1426-1434 (in Chinese)
[9] Dong W-L (董宛麟), Zhang L-Z (张立祯), Yu Y (于洋), et al. Productivity and water use in sunflower intercropped with potato. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2012, 28(18): 127-133 (in Chinese)
[10] Zhang P-P (张盼盼), Zhou Y (周瑜), Song H (宋慧), et al. Comparison of growth and field microclimate characteristics of proso millet under different fertilization conditions. Chinese Journal of Applied Ecology (应用生态学报), 2015, 26(2): 473-480 (in Chinese)
[11] Gong X-W (宫香伟), Han H-K (韩浩坤), Zhang D-Z (张大众), et al. Effects of nitrogen fertilizers on the field microclimate and yield of proso millet at grain filling stage. Journal of China Agricultural University (中国农业大学学报), 2017, 22(12): 10-19 (in Chinese)
[12] Li J-X (李俊祥), Wan Z-H (宛志沪). Microclimatic effect and soil moisture change of poplar-wheat intercropping systems in Huaibei Plain. Chinese Journal of Applied Ecology (应用生态学报), 2002, 13(4): 390-394 (in Chinese)
[13] Wang X-L (王小林), Zhang S-Q (张岁岐), Wang S-Q (王淑庆), et al. The dynamic variation of maize (Zea mays L.) population growth characteristics under cultivars-intercropped on the Loess Plateau. Acta Ecologica Sinica (生态学报), 2012, 32(23): 7383-7390 (in Chinese)
[14] Guo R-S (郭仁松), Tian L-W (田立文), Lin T (林涛), et al. Effect of jujube-cotton intercropping on chara-cteristics of microclimate during cotton flowering and boll-setting period and cotton yield. Acta Agriculturae Boreali-occidentalis Sinica (西北农业学报), 2014, 23(2): 92-98 (in Chinese)
[15] Qiao X (乔旭), Lei J-J (雷钧杰), Chen X-W (陈兴武), et al. Effect of microclimate in walnut-wheat intercropping system on wheat yield. Chinese Journal of Agrometeorology (中国农业气象), 2012, 33(4): 540-544 (in Chinese)
[16] Wang YQ, Zhao ZG, Li JP, et al. Does maize hybrid intercropping increase yield due to border effects? Field Crops Research, 2017, 214: 283-290
[17] Yang F, Liao DP, Wu XL, et al. Effect of aboveground and belowground interactions on the intercrop yields in maize-soybean relay intercropping systems. Field Crops Research, 2017, 203: 16-23
[18] Wang ZK, Zhao XN, Wu PT, et al. Border row effects on light interception in wheat/maize strip intercropping systems. Field Crops Research, 2017, 214: 1-13
[19] Gong X-W (宫香伟), Liu C-J (刘春娟), Feng N-J (冯乃杰), et al. Effects of plant growth regulators S3307 and DTA-6 on photosynthetic characteristics and yield in soybean canopy. Plant Physiology Journal (植物生理学报), 2017, 53(10): 1867-1876 (in Chinese)
[20] Tang X-M (唐秀梅), Zhong R-C (钟瑞春), Jie H-K (揭红科), et al. Effect of interplanting peanut on metabolites and key enzyme activities of carbon-nitrogen metabolism of cassava. Chinese Agricultural Science Bulletin (中国农学通报), 2011, 27(3): 94-98 (in Chinese)
[21] Ding A-M (丁安明), Cui F (崔法), Li J (李君), et al. QTL analysis on grain yield per plant and plant height in wheat. Scientia Agricultura Sinica (中国农业科学), 2011, 44(14): 2857-2867 (in Chinese)
[22] Wu Z-D (吴忠东), Wang Q-J (王全九). Effects of stage water shortage on water consumption and leaf area index of winter wheat. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2010, 26(10): 63-68 (in Chinese)
[23] Yao HS, Zhang YL, Yi XP, et al. Cotton responds to different plant population densities by adjusting specific leaf area to optimize canopy photosynthetic use efficiency of light and nitrogen. Field Crops Research, 2016, 188: 10-16
[24] Gou F, Ittersum MKV, Simon E, et al. Intercropping wheat and maize increases total radiation interception and wheat RUE but lowers maize RUE. European Journal of Agronomy, 2017, 84: 125-139
[25] Munz S, Graeff-Hönninger S, Lizaso JI, et al. Modeling light availability for a subordinate crop within a strip-intercropping system. Field Crops Research, 2014, 155: 77-89
[26] Ewansiha SU, Kamara AY, Chiezey UF, et al. Performance of cowpea grown as an intercrop with maize of different populations. African Crop Science Journal, 2015, 23: 113-122
[27] Liu B, Qu DN, Zhou XM. The shoot dry matter accumulation and vertical distribution of soybean yield or yield components in response to light enrichment and shading. Emirates Journal of Food & Agriculture, 2015, 27: 258-265
[28] Ruberti I, Sessa G, Ciolfi A, et al. Plant adaptation to dynamically changing environment: The shade avoidance response. Biotechnology Advances, 2012, 30: 1047-1058
[29] Wang Z (王竹), Yang W-Y (杨文钰), Wu Q-L (吴其林). Effects of shading in maize/soybean relay-cropping system on the photosynthetic characteristics and yield of soybean. Acta Agronomica Sinica (作物学报), 2007, 33(9): 1502-1507 (in Chinese)
[30] Huang W-D (黄卫东), Wu L-K (吴兰坤), Zhan J-C (战吉成). Growth and photosynthesis adaptation of dwarf-type Chinese cherry (Prunus pseudocerasus L. cv. Laiyang) leaves to weak light stress. Scientia Agricultura Sinica (中国农业科学), 2004, 37(12): 1981-1985 (in Chinese)
[31] Gong X-W (宫香伟), Han H-K (韩浩坤), Zhang D-Z (张大众), et al. Effects of nitrogen fertilizer on dry matter accumulation, transportation and nitrogen meta-bolism in functional leaves of proso millet at late growth stage. Scientia Agricultura Sinica (中国农业科学), 2018, 51(6): 1045-1056 (in Chinese)
[32] Du F (杜峰), Liang Z-S (梁宗锁), Hu L-J (胡莉娟). A review on plant competition. Chinese Journal of Ecology (生态学杂志), 2004, 23(4): 157-163 (in Chinese)
[33] Luo B (罗冰). Analysis of characters microclimate of intercropping ecosystems in upland red soil. Acta Agriculturae Universitatis Jiangxisis (江西农业大学学报), 2007, 29(4): 634-637 (in Chinese)
[34] Yang B-J (杨滨娟), Huang G-Q (黄国勤). Effects of straw incorporation action plus chemical fertilizer on soil temperature, root micro-organisms and enzyme activities. Acta Pedologica Sinica (土壤学报), 2014, 51(1): 150-157 (in Chinese)
[35] Zhang X-C (张绪成), Wang H-L (王红丽), Yu X-F (于显枫), et al. The study on the effect of potato and beans intercropping with whole field plastics mulching and ridge-furrow planting on soil thermal-moisture status and crop yield on semi-arid area. Scientia Agricultura Sinica (中国农业科学), 2016, 49(3): 468-481 (in Chinese)
[36] Mushagalusa GN, Ledent JF, Draye X. Shoot and root competition in potato/maize intercropping: Effects on growth and yield. Environmental & Experimental Botany, 2008, 64: 180-188
[37] Ren X-M (任学敏), Zhu Y (朱雅), Wang X-L (王小立), et al. Relationships between diurnal changes of peanut canopy temperature and surface temperature and illuminance. Journal of Northwest A&F University (Natural Science) (西北农林科技大学学报:自然科学版), 2015, 43(1): 77-84 (in Chinese)
[38] Ren Y-Y (任媛媛), Wang Z-L (王志梁), Wang X-L (王小林), et al. The effect and mechanism of intercropping pattern on yield and economic benefit on the Loess Plateau. Acta Ecologica Sinica (生态学报), 2015, 35(12): 4168-4177 (in Chinese)
[39] Ye Y-L (叶优良), Li L (李隆). Effects of nitrogen fertilizer application and irrigation level on soil nitrate nitrogen accumulation and water and nitrogen use efficiency for wheat/maize intercropping. Transactions of the Chinese Society of Agricultural Engineering (农业工程学报), 2009, 25(1): 33-39 (in Chinese)

黄土高原旱作区糜子-绿豆带状种植农田小气候特征与产量效应

Field microclimate and yield for proso millet intercropping with mung bean in the dryland of Loess Plateau, Northwest China

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