冬小麦-夏玉米与双季玉米种植模式产量及光温资源利用特征比较

doi:10.3724/SP.J.1006.2015.01393

摘要/Abstract

摘要： 优化传统冬小麦-夏玉米模式并探索新型种植模式是挖掘黄淮海区周年高产潜力, 提高资源利用效率的重要途径。本研究以冬小麦-夏玉米传统种植模式为对照(CK), 建立了冬小麦-夏玉米优化种植模式(T1)和双季玉米模式(T2), 于2009—2012年在河南新乡进行田间试验, 对其周年资源分配、产量及资源利用效率进行了比较。结果表明: (1) T1模式通过播/收期调整, 协调了两季的光、温资源分配比例(0.7:1.0和1.4:1.0); T2模式两季积温基本为均等分配, 光照资源分配比例为1.5:1.0。(2)资源分配的变化引起了产量的变化。与CK比, T1模式周年产量平均增幅为7.8%, 其产量的增加主要来自于夏玉米季, T1模式夏玉米季平均叶面积指数(MLAI)、生物量和产量均显著高于CK, 且冬小麦晚播并未造成减产。双季玉米(T2)是“双C₄作物”的新型种植模式, 其第1季的MLAI、生物量和产量均显著高于CK和T1, 第2季(除MLAI外)显著低于CK和T1。T2与T1周年产量差异不显著, 但显著高于CK, 平均增幅为9.2%。另外, T2模式周年日产量显著高于CK和T1, 平均增幅分别为53.9%和46.2%。(3)T2模式周年光、温生产效率及籽粒光能利用效率显著高于CK和T1, 平均增幅分别为30.5%和23.3%, 15.5%和9.7%, 30.3%和23.0%。综上所述, T1和T2高产高效模式建立的核心均是充分利用C₄作物玉米高物质生产能力的优势, 二者的建立为黄淮海区周年产量潜力的挖掘及种植结构调整提供了思路。

关键词: 冬小麦-夏玉米, 双季玉米, 产量, 光温资源分配, 光温资源利用效率

Abstract: Optimizing traditional wheat-maize cropping and exploring new cropping system are essential for increasing annual yield and resource use efficiency in the Yellow-Huaihe-Haihe Rivers Plain. The optimized winter wheat-summer maize cropping (T1) and double maize cropping (T2) were established in our field experiment conducted in Xinxiang from 2009 to 2012. The dry matter production, grain yield, and energy (light and temperature) use efficiency were investigated in the two cropping systems and compared with those in traditional cropping system (CK). In the two optimized cropping systems, the distributions of light and temperature between two cropping seasons were adjusted to 0.7:1.0 and 1.4:1.0 in T1 cropping system, and 1.5:1.0 and 1.0:1.0 in T2 cropping system, respectively, by changing the sowing and harvest dates. Under T1 condition, the annual yield increased by 7.8% over that of CK (P < 0.05), and the yield promotion was mainly attributed to the significant increase in the summer maize season. Late sowing of winter wheat in T1 system resulted in significant improvements of mean leaf area index (MLAI), above-ground biomass, and grain yield of summer maize, meanwhile with no significant yield loss of winter wheat. T2 is a new high-yield production pattern with double maize growing seasons. In the first season, the MLAI, above-ground biomass, and yield of maize were significantly higher than those of winter wheat in CK and T1. In the second season, the above-ground biomass, and yield of T2 were lower than those of CK and T1. However, the annual yield of T2 was higher than that of CK and had no significant difference to that of T1. Compared to CK and T1, T2 resulted in increases by 53.9% and 46.2% in daily yield, 30.5% and 23.3% in light production efficiency, 15.5% and 9.7% in temperature production efficiency, and 30.3% and 23.0% in light energy use efficiency, respectively. These results indicate that the advantages of high resource use efficiency and production capabilities of C₄ crop plays the key role in promoting the annual production capability in T1 and T2. The two optimized cropping systems (T1 and T2) may lighten the thoughts for adjusting production patterns to meet an increasing desire of high yield and resource use efficiency in the Yellow-Huaihe-Haihe Rivers Plain.

Key words: Wheat-Maize, Double maize, Yield, Resource distribution, Resource use efficiency

周宝元, 王志敏, 岳阳, 马玮, 赵明. 冬小麦-夏玉米与双季玉米种植模式产量及光温资源利用特征比较[J]. 作物学报, 2015, 41(09): 1393-1405.

ZHOU Bao-Yuan, WANG Zhi-Min, YUE Yang, MA Wei, ZHAO Ming. Comparison of Yield and Light-temperature Resource Use Efficiency between Wheat-Maize and Maize-Maize Cropping Systems[J]. Acta Agron Sin, 2015, 41(09): 1393-1405.

参考文献

[1] 侯满平, 郝晋珉, 丁忠义, 孟鹏. 黄淮海平原资源低耗生态农业模式研究. 中国生态农业学报, 2005, 13(1): 189-191 Hou M P, Hao J M, Ding Z Y, Meng P. Research on the eco-agriculture mode of resource low dissipation in Huang-Huai-Hai Plain. Chin J Eco-Agric , 2005, 13(1): 189-191 (in Chinese with English abstract)
[2] 侯美亭, 毛任钊, 吴素霞. 黄淮海平原不同生态类型区农业可持续发展策略研究. 干旱地区农业研究, 2006, 24(3): 156-159 Hou M T, Mao R Z, Wu S X. A discussion on sustainable agricultural development in the different ecological districts in Huang-Huai-Hai Plain. Agric Res Arid Areas , 2006, 24(3): 156-159 (in Chinese with English abstract)
[3] Tao F, Yokozawa M, Xu Y L, Yousay H, Zhao Z. Climate changes and trends in penology and yields of field crops in China, 1981-2000. Agric For Meteorol , 2006, 138: 82-92
[4] Wang J, Wang E L, Yang X G, Zhang F S, Yin H. Increased yield potential of wheat-maize cropping system in the North China Plain by climate change adaptation. Climat Change , 2012, 113: 825-840
[5] Sun H Y, Zhang X Y, Chen S Y, Pei D, Liu C M. Effects of harvest and sowing time on the performance of the rotation of winter wheat-summer maize in the North China Plain. Ind Crops Prod , 2007, 25: 239-247
[6] 胡焕焕, 刘丽平, 李瑞奇, 李慧玲, 李雁鸣. 播种期和密度对冬小麦品种河农822产量形成的影响. 麦类作物学报, 2008, 28: 490-495 Hu H H, Liu L P, Li R Q, Li H L, Li Y M. Effect of sowing date and planting density on the yield formation of a winter wheat cultivar Henong 822. J Triticeae Crops , 2008, 28: 490-495 (in Chinese with English abstract)
[7] Rácz F, Kása S, Hadi G. Daily changes in the water content of early and late maturing grain maize varieties in the later stages of over-ripening. Cereal Res Commun , 2008, 36: 583-589
[8] 王树安. 小麦-夏玉米平播亩产吨粮的理论与实践. 北京: 农业出版社, 1991 Wang S A. Theory and Practice High Yield Output of 15 Tons per Hectare in Winter Wheat and Summer Maize Double-Cropping Pattern. Beijing: Agriculture Press, 1991 (in Chinese)
[9] 黄川容, 刘洪. 气候变化对黄淮海平原冬小麦与夏玉米生产潜力的影响. 中国农业气象, 2011, 32(增刊): 118 -123 Huang C R, Liu H. The effect of the climate change on potential productivity of winter wheat and summer maize in the Huang-Huai-Hai Plain. China J Agrometeorol , 2011, 32(suppl): 118 -123 (in Chinese with English abstract)
[10] 陈国平, 尉德铭, 刘志文, 赵仕孝, 杨洪友. 夏玉米的高产生育模式及其控制技术. 中国农业科学, 1986, 19(1): 33-40 Chen G P, Wei D M, Liu Z W, Zhao S X, Yang H Y. The model of development and control technique for a high yielding summer maize. Sci Agric Sin , 1986, 19(1): 33-40 (in Chinese with English abstract)
[11] 杨晓光, 刘志娟, 陈阜. 全球气候变暖对中国种植制度可能影响: I. 气候变暖对中国种植制度北界和粮食产量可能影响的分析. 中国农业科学, 2010, 43: 329-336 Yang X G, Liu Z J, Chen F. The possible effects of global warming on cropping systems in China: I. The possible effects of climate warming on northern limits of cropping systems and crop yields in China. Sci Agric Sin , 2010, 43: 329-336 (in Chinese with English abstract)
[12] 张厚. 中国种植制度对全球气候变化响应的有关问题: II. 我国种植制度对气候变化响应的主要问题. 中国农业气象, 2000, 21(2): 10-13 Zhang H. Response of cropping system in China to global climatic changes: II. Effect of cropping system in China to global climatic changes. China J Agrometeorol , 2000, 21(2): 10-13 (in Chinese with English abstract)
[13] 王绍武. 近百年气候变化与变率的诊断研究. 气象学报, 1994, 52: 261-273 Wang S W. Diagnostic studies on the climate change and variability for the period of 1880-1990. Acta Meteorol Sin , 1994, 52: 261-273 (in Chinese)
[14] Westgate M E. Water status and development of the maize endosperm and embryo during drought. Crop Sci , 1994, 34: 76-83
[15] Borrás L, Gambín B L. Trait dissection of maize kernel weight: towards integrating hierarchical scales using a plant growth approach. Field Crops Res , 2010, 118: 1-12
[16] Cairns J E, Sonder K, Zaidi P H, Verhulst N, Mahuku G, Babu R. Maize production in a changing climate: impacts, adaptation, and mitigation strategies. In: Sparks D, ed. Advances in Agronomy. Burlington: Academic Press, 2012, Vol. 114: pp 1-58
[17] 王美云. 热量限制两熟区双季青贮玉米模式及其技术体系研究. 中国农业科学院博士学位论文, 北京, 2006 Wang M Y. Study on Mode and Technique of Two Harvests Silage Maize in the Temperature Limited Region of Double Cropping System. PhD Dissertation of Chinese Academy of Agricultural Sciences, Beijing, China, 2006 (in Chinese with English abstract)
[18] 李立娟, 王美云, 薛庆林, 崔彦宏, 侯海鹏, 葛均筑, 赵明. 黄淮海双季玉米产量性能与资源效率的研究. 作物学报, 2011, 37: 1229-1234 LI L J, Wang M Y, Xue Q L, Cui Y H, Hou H P, Ge J Z, Zhao M. Yield performance and resource efficiency of double-cropping maize in the Yellow, Huai and Hai River Valleys Region. Acta Agron Sin , 2011, 37: 1229-1234 (in Chinese with English abstract)
[19] 付雪丽, 张惠, 贾继增, 杜立丰, 付金东, 赵明. 冬小麦-夏玉米“双晚”种植模式的产量形成及资源效率研究. 作物学报, 2009, 35: 1708-1714 Fu X L, Zhang H, Jia J Z, Du L F, Fu J D, Zhao M. Yield performance and resources use efficiency of winter wheat and summer maize in double late-cropping system. Acta Agron Sin , 2009, 35: 1708-1714 (in Chinese with English abstract)
[20] 张甲元, 周苏玫, 尹钧, 刘万代, 李巧云, 石珊珊, 年力. 适期晚播对弱春性小麦籽粒灌浆期光合性能的影响. 麦类作物学报, 2011, 31: 535-539 Zhang J Y, Zhou S M, Yin J, Liu W D, Li Q Y, Shi S S, Nian L. Effect of suitable late sowing on photosynthetic performance of weak spring wheat during grain filling stage. J Triticeae Crops , 2011, 31: 535-539 (in Chinese with English abstract)
[21] Coventry D R, Reeves T G, Brooke H D, Cann D K. Influence of genotype, sowing date, and seeding rate on wheat development and yield. Aust J Exp Agric , 1993, 33: 751-757
[22] McDonald G K, Sutton B G, Ellison F W. The effect of sowing date, irrigation and cultivar on the growth and yield of wheat in the Namoi River Valley, New South Wales. Irrig Sci , 1984, 5: 123-135
[23] 高海涛, 王育红, 孟战赢, 席玲玲, 段国辉, 温红霞. 小麦-玉米双晚种植对周年产量和资源利用的影响. 麦类作物学报, 2012, 32: 1102-1106 Gao H T, Wang Y H, Meng Z Y, Xi L L, Duan G H, Wen H X. Effects of later sowing of winter wheat and later harvest of summer maize cropping system on yield and resources use efficiency of whole-year. J Triticeae Crops , 2012, 32: 1102-1106 (in Chinese with English abstract)
[24] 张宾, 赵明, 董志强, 李建国, 陈传永, 孙锐. 作物高产群体LAI 动态模拟模型的建立与检验. 作物学报, 2007, 33: 612-619 Zhang B, Zhao M, Dong Z Q, Li J G, Chen C Y, Sun R. Establishment and test of LAI dynamic simulation model for high yield population. Acta Agron Sin , 2007, 33: 612-619 (in Chinese with English abstract)
[25] 李向岭, 赵明, 李从锋, 葛均筑, 侯海鹏. 玉米叶面积系数动态特征及其积温模型的建立. 作物学报, 2011, 37: 321-330 Li X L, Zhao M, Li C F, Ge J Z, Hou H P. Dynamic characteristics of leaf area index in maize and its model establishment based on accumulated temperature. Acta Agron Sin , 2011, 37: 321-330 (in Chinese with English abstract)
[26] 杨羡敏, 曾燕, 邱新法, 姜爱军. 1960-2000年黄河流域太阳总辐射气候变化规律研究. 应用气象学报, 2005, 16: 243-247 Yang X M, Zeng Y, Qiu X F, Jiang A J. The climatic change of solar radiation over the Yellow River basin during 1961-2000. Quarterly J Appl Meteorol , 2005, 16: 243-247 (in Chinese)
[27] 郑海霞, 封志明, 游松财. 基于GIS的甘肃省农业生产潜力研究. 地理科学进展, 2003, 22: 400-408 Zheng H X, Feng Z M, You S C. A study on potential land productivity based on GIS technology in Gansu province. Prog Geogr , 2003, 22: 400-408 (in Chinese with English abstract)
[28] 徐勇, 齐文虎, 谢高地, 章予舒. 农业自然资源利用效率的因子-能量评价模型及其应用. 资源科学, 2002, 24(3): 86-91 Xu Y, Qi W H, Xie G D, Zhang Y S. The factor-energy evaluation model of agricultural natural resources utilization efficiency and its application. Resour Sci , 2002, 24(3): 86-91 (in Chinese with English abstract)
[29] Meng Q F, Sun Q P, Chen X P, Cui Z L, Yue S C, Zhang F S, Römheld V. Alternative cropping systems for sustainable water and nitrogen use in the North China Plain. Agric Ecosyst Environ , 2012, 146: 93-102
[30] Pronk A A, Heuvelink E, Challa H. Dry mass production and leaf area development of field grown ornamental conifers: measurements and simulation. Agric Syst , 2003, 78: 337-353
[31] Fageria N K, Baligar V C, Clark R B. Physiology of Crop Production. Food Products Press. An Imprint of the Haworth Press, Inc. New York, London, Oxford, 2005. pp 72-82
[32] Ding L, Wang K J, Jiang G M, Liu M Z, Niu S L, Gao L M. Post-anthesis changes in photosynthetic traits of maize hybrids released in different years. Field Crops Res , 2005, 93: 108-115. doi:10.1016/j.fcr.2004.09.008
[33] 中华人民共和国农业部. 中国农业统计资料. 北京: 中国农业出版社, 2012 Ministry of Agriculture, The People’s Republic of China. China Agriculture Statistical Report. Beijing: China Agriculture Press, 2012

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