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| Resource use efficiency, ecological intensification and sustainability of intercropping systems |
| MAO Li-li, ZHANG Li-zhen, ZHANG Si-ping, Jochem B Evers, Wopke van der Werf, WANG Jingjing, SUN Hong-quan, SU Zhi-cheng, Huub Spiertz |
1、College of Agronomy and Biotechnology, China Agricultural University, Beijing 100193, P.R.China
2、College of Agricultural Resources and Environmental Sciences, China Agricultural University, Beijing 100193, P.R.China
3、Centre for Crop Systems Analysis (CSA), Department of Plant Sciences, Wageningen University, Wageningen 6708 PB, The Netherlands
4、Institute of Cotton Research, Chinese Academy of Agricultural Sciences/State Key Laboratory of Cotton Biology, Anyang 455004,P.R.China
5、China Institute of Water Resources and Hydropower Research, Beijing 100038, P.R.China |
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摘要 The rapidly growing demand for food, feed and fuel requires further improvements of land and water management, crop productivity and resource-use efficiencies. Combined field experimentation and crop growth modelling during the past five decades made a great leap forward in the understanding of factors that determine actual and potential yields of monocrops. The research field of production ecology developed concepts to integrate biological and biophysical processes with the aim to explore crop growth potential in contrasting environments. To understand the potential of more complex systems (multi-cropping and intercropping) we need an agro-ecosystem approach that integrates knowledge derived from various disciplines: agronomy, crop physiology, crop ecology, and environmental sciences (soil, water and climate). Adaptation of cropping systems to climate change and a better tolerance to biotic and abiotic stresses by genetic improvement and by managing diverse cropping systems in a sustainable way will be of key importance in food security. To accelerate sustainable intensification of agricultural production, it is required to develop intercropping systems that are highly productive and stable under conditions with abiotic constraints (water, nutrients and weather). Strategies to achieve sustainable intensification include developing tools to evaluate crop growth potential under more extreme climatic conditions and introducing new crops and cropping systems that are more productive and robust under conditions with abiotic stress. This paper presents some examples of sustainable intensification management of intercropping systems that proved to be tolerant to extreme climate conditions.
Abstract The rapidly growing demand for food, feed and fuel requires further improvements of land and water management, crop productivity and resource-use efficiencies. Combined field experimentation and crop growth modelling during the past five decades made a great leap forward in the understanding of factors that determine actual and potential yields of monocrops. The research field of production ecology developed concepts to integrate biological and biophysical processes with the aim to explore crop growth potential in contrasting environments. To understand the potential of more complex systems (multi-cropping and intercropping) we need an agro-ecosystem approach that integrates knowledge derived from various disciplines: agronomy, crop physiology, crop ecology, and environmental sciences (soil, water and climate). Adaptation of cropping systems to climate change and a better tolerance to biotic and abiotic stresses by genetic improvement and by managing diverse cropping systems in a sustainable way will be of key importance in food security. To accelerate sustainable intensification of agricultural production, it is required to develop intercropping systems that are highly productive and stable under conditions with abiotic constraints (water, nutrients and weather). Strategies to achieve sustainable intensification include developing tools to evaluate crop growth potential under more extreme climatic conditions and introducing new crops and cropping systems that are more productive and robust under conditions with abiotic stress. This paper presents some examples of sustainable intensification management of intercropping systems that proved to be tolerant to extreme climate conditions.
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Received: 16 March 2015
Accepted:
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| Fund: The project was funded by the International Cooperation and Exchange of the National Science Foundation of China (31461143025, 31210103906, 51209220), the National Basic Research Program of China (973 Program, 2011CB100405) and the Special Fund for Agro-Scientific Research in the Public Interest, China (201003043). |
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Corresponding Authors:
ZHANG Li-zhen, Tel: +86-10-62731423,E-mail: Zhanglizhen@cau.edu.cn; ZHANG Si-ping,Tel: +86-372-2525355, E-mail: zhangsp@cricaas.com.cn
E-mail: Zhanglizhen@cau.edu.cn;zhangsp@cricaas.com.cn
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| About author: MAO Li-li, E-mail: maolili6666@163.com; |
Cite this article:
MAO Li-li, ZHANG Li-zhen, ZHANG Si-ping, Jochem B Evers, Wopke van der Werf, WANG Jingjing, SUN Hong-quan, SU Zhi-cheng, Huub Spiertz.
2015.
Resource use efficiency, ecological intensification and sustainability of intercropping systems. Journal of Integrative Agriculture, 14(8): 1542-1550.
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| Baldé A B, Scopel E, Affolder F, Corbeels M, Da Silva F A M,Xavier J H V, Wery J. 2011. Agronomic performance ofno-tillage relay intercropping with maize under smallholderconditions in Central Brazil. Field Crops Research, 124,240-251Baumann D T, Bastiaans L, Goudriaan J, van Laar H H, KropffM J. 2002. Analysing crop yield and plant quality in anintercropping system using an eco-physiological model forinterplant competition. Agricultural Systems, 73, 173-203Baumann D T, Bastiaans L, Kropff M J. 2004. Analysisand design of a leek-celery intercropping system usingmechanistic and descriptive models. Acta Horticulture,638, 59-68Caviglia O P, Sadras V O, Andrade F H. 2004. Intensification ofagriculture in the south-eastern Pampas - I. Capture andefficiency in the use of water and radiation in double croppedwheat-soybean. Field Crops Research, 87, 117-129Challinor A J, Ewert F, Arnold S, Simelton E, Fraser E.2009. Crops and climate change: Progress, trends, andchallenges in simulating impacts and informing adaptation.Journal of Experimental Botany, 60, 2775-2789Chen C, Wang E, Yu Q. 2010. Modelling the effects of climatevariability and water management on crop water productivityand water balance in the North China Plain. AgriculturalWater Management, 97, 1175-1184Coll L, Cerrudo A, Monzon J P, Andrade F H. 2012. Captureand use of water and radiation in summer intercrops in thesouth-east Pampas of Argentina. Field Crops Research,134, 105-113Davies W J, Zhang J, Yang J, Dodd I C. 2011. Novel cropscience to improve yield and resource use efficiency inwater-limited agriculture. Journal of Agricultural Science,149, 123-131Evers J B, Vos J, Yin X, Romero P, van der Putten P E L, StruikP C. 2010. Simulation of wheat growth and developmentbased on organ-level photosynthesis and assimilateallocation. Journal of Experimental Botany, 61, 2203-2216Foulkes M J, Hawkesford M J, Barreclough P B, Holdsworth MJ, Kerr S, Kightley S, Shewry P R. 2009. Identifying traits toimprove the nitrogen economy of wheat: Recent advancesand future prospects. Field Crops Research, 114, 329-342Gao Y, Duan A, Sun J, Li F, Liu Z, Liu H, Liu Z. 2009. Cropcoefficient and water-use efficiency of winter wheat/springmaize strip intercropping. Field Crops Research, 111,65-73Gebbers R, Adamchuk V I. 2010. Precision agriculture and foodsecurity. Science, 327, 828-831Gu S, Evers J B, Zhang L, Mao L, Zhang S, Zhao X, Liu S, vander Werf W, Li Z. 2014. Modelling the structural responseof cotton plants to mepiquat chloride and population density.Annals of Botany, 114, 877-887Hammer G L, Nicholls N, Mitchell C. 2000. Applications ofSeasonal Climate Forecasting in Agriculture and NaturalEcosystems: The Australian Experience. Kluwer Academy,Dordrecht, The Netherlands. p. 469.Hatfield J L, Boote K J, Kimball B A, Ziska L H, Izaurralde RC, Ort D, Thomson A M, Wolfe D. 2011. Climate impactson agriculture: Implications for crop production. AgronomyJournal, 103, 351-370Hauggaard-Nielsen H, Gooding M, Ambus P, Corre-Hellou G,Crozat Y, Dahlmann C, Dibet A, von Fragstein P, PristeriA, Monti M, Jensen E S. 2009. Pea-barley intercropping forefficient symbiotic N2-fixation, soil N acquisition and use ofother nutrients in European organic cropping systems. FieldCrops Research, 113, 64-71van Ittersum M K, Rabbinge R. 1997. Concepts in productionecology for analysis and quantification of agricultural inputoutputcombinations. Field Crops Research, 52, 197-208Keating B A, Carberry P S, Hammer G L, Probert M E,Robertson M J, Holzworth D, Huth N I, Hargreaves J N G, Meinke H, Hochman Z, McLean G, Verburg K, SnowV, Dimes J P, Silburn M, Wang E, Brown S, Bristow K L,Asseng S, Chapman S, et al. 2003. An overview of APSIM,a model designed for farming systems simulation. EuropeanJournal of Agronomy, 18, 267-288Kropff M J, van Laar H H. 1993. Modelling Crop-WeedInteractions. CAB International, Wallingford Oxon, UK. p.274.Launay M, Brisson N, Satger S, Hauggaard-Nielsen H, Corre-Hellou G, Kasynova E, Ruske R, Jensen E S, Gooding MJ. 2009. Exploring options for managing strategies for peabarleyintercropping using a modelling approach. EuropeanJournal of Agronomy, 31, 85-98Li H, Huang G, Meng Q, Ma L, Yuan L, Wang F, Zhang W, Cui Z,Shen J, Chen X, Jiang R, Zhang F. 2011. Integrated soil andplant phosphorus management for crop and environmentin China. Plant Soil, 349, 157-167Li L, Yang S, Li X, Zhang F, Christie P. 1999. Interspecificcomplementary and competitive interactions betweenintercropped maize and faba bean. Plant Soil, 212,105-114Li L, Zhang L, Zhang F. 2013. Crop mixtures and the mechanismsof overyielding. In: Levin S A, ed., Encyclopedia ofBiodiversity. 2nd ed. vol. 2. Academic Press, MA, Waltham.pp. 382-395Liu C A, Jin S L, Zhou L M, Jia Y, Li F M, Xiong Y C, Li X G.2009. Effects of plastic film mulch and tillage on maizeproductivity and soil parameters. European Journal ofAgronomy, 31, 241-249Lobell D B. 2007. Changes in diurnal temperature rangeand national cereal yields. Agricultural and ForestryMeteorology, 145, 229-238Ma L, Ma W Q, Velthof G L, Wang F H, Qin W, Zhang F S,Oenema O. 2010. Modeling nutrient flows in the food chainof China. Journal of Environmental Quality, 39, 1279-1289Mao L, Zhang L, Li W, van der Werf W, Spiertz J H J, Li L. 2012.Yield advantage and water saving in maize/pea intercrop.Field Crops Research, 138, 11-20Meinke H, Stone R C. 2005. Seasonal and inter-annual climateforecasting: The new tool for increasing preparedness toclimate variability and change in agricultural planning andoperations. Climate Change, 70, 221-253Meinke H, Nelson R, Kokic P, Stone R, Selvaraju R, BaethgenW. 2006. Actionable climate knowledge-from analysis tosynthesis. Climate Research, 33, 101-110Nelson R, Kokic P, Meinke H. 2007. From rainfall to farmincomes-transforming advice for Australian drought policy:Part II - Forecasting farm incomes. Australian Journal ofAgricultural Research, 58, 1004-1012Nelson R A, Holzworth D P, Hammer G L, Hayman P T.2002. Infusing the use of seasonal climate forecasting intocrop management practice in North East Australia usingdiscussion support software. Agricultural Systems, 74,393-414Poorter H, Anten N P R, Marcelis L F M. 2013. Physiologicalmechanisms in plant growth models: Do we need asupra-cellular systems biology approach? Plant, Cell andEnvironment, doi: 10.1111/pce.12123Pronk A A, Goudriaan J, Stilma E, Challa H. 2003. A simplemethod to estimate radiation interception by nursery stockconifers: A case study of eastern white cedar. NetherlandsJournal of Agricultural Sciences, 51, 279-295Reynolds M P, Trethowan R M. 2007. Physiological interventionsin breeding for adaptation to abiotic stress. In: Spiertz J HJ, Struik P C, van Laar H H, eds., Scale and Complexityin Plant Systems Research. Gene-Plant-Crop RelationsPublisher, Springer, Dordrecht, The Netherlands. pp.129-146Rusinamhodzi L, Corbeels M, Nyamangara J, Giller K E. 2012.Maize-grain legume intercropping is an attractive optionfor ecological intensification that reduces climatic risk forsmallholder farmers in central Mozambique. Field CropsResearch, 136, 12-22Twomlow S, Mugabe F T, Mwale M, Delve R, Nanja D, CarberryP, Howden M. 2008. Building adaptive capacity to copewith increasing vulnerability due to climatic change inAfrica - A new approach. Physics and Chemistry of theEarth, 33, 780-787Vos J, Evers J B, Buck-Sorlin G H, Andrieu B, Chelle M, deVisser P H B. 2010. Functional-structural plant modelling: Anew versatile tool in crop science. Journal of ExperimentalBotany, 61, 2101-2115van der Werf W, Keesman K, Burgess P, Graves A, Pilbeam D,Incoll L D, Metselaar K, Mayus M, Stappers R, van Keulen H,Palma J, Dupraz C. 2007. Yield-SAFE: A parameter-sparse,process-based dynamic model for predicting resourcecapture, growth, and production in agroforestry systems.Ecological Engineering, 29, 419-433Yuan M, Zhang L, Gou F, Su Z, Spiertz J H J, van der Werf W.2013. Assessment of crop growth and water productivityfor five C3 species in semi-arid Inner Mongolia. AgriculturalWater Management, 122, 28-38Zhao H, Xiong Y C, Li F M, Wang RY, Qiang S C, Yao T F, Mo F.2012. Plastic film mulch for half growing-season maximizedWUE and yield of potato via moisture-temperatureimprovement in a semi-arid agroecosystem. AgriculturalWater Management, 104, 68-78Zhang F, Shen J, Li L, Liu X. 2004. An overview of rhizosphereprocesses related with plant nutrition in major croppingsystems in China. Plant Soil, 260, 89-99Zhang L, Spiertz J H J, Zhang S, Li B, van der Werf W. 2008a.Nitrogen economy in relay intercropping systems of wheatand cotton. Plant Soil, 303, 55-68Zhang L, van der Werf W, Bastiaans L, Zhang S, Li B, Spiertz JH J. 2008b. Light interception and radiation use efficiency inrelay intercrops of wheat and cotton. Field Crops Research,107, 29-42Zhu J, Vos J, van der Werf W, van der Putten P E L, EversJ B. 2014. Early competition shapes maize whole plantdevelopment in mixed stands. Journal of ExperimentalBotany, 65, 641-653 |
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