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Frontiers of Agricultural Science and Engineering

ISSN 2095-7505

ISSN 2095-977X(Online)

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Front. Agr. Sci. Eng.    2020, Vol. 7 Issue (1) : 28-44    https://doi.org/10.15302/J-FASE-2019299
REVIEW
Can crop science really help us to produce more better-quality food while reducing the world-wide environmental footprint of agriculture?
William J. DAVIES1(), Susan E. WARD1, Alan WILSON2
1. Lancaster Environment Centre, Lancaster University, Lancaster, LA1 4YQ, UK
2. Waitrose and Partners, Food Retailers, Waite House, Bracknell, RG12 8YA, UK
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Abstract

This paper reviews recent developments in crop science that can be the basis of a revolution in the global food system but it is also emphasized that such a revolution requires more than changes in food production and supply. We must more effectively feed a growing global population with a healthy diet while also defining and delivering the kinds of sustainable food systems that will minimise damage to our planet. There are exciting new developments in crop production biology but much existing crop science can be exploited to increase yields with the aid of a knowledge exchange (KE) framework requiring the use of new technology now available to most people across the globe. We discuss novel approaches at both the plant and the crop level that will enhance nutrient and water productivity and we also outline ways in which energy use and greenhouse gas (GHG) emissions can be reduced and labor shortages combatted. Exploitation of new biology and new engineering opportunities will require development of public-private partnerships and collaborations across the disciplines to allow us to move effectively from discovery science to practical application. It is also important that consumers contribute to the debate over proposed changes to food and farming and so effective KE mechanisms are required between all relevant communities.
Keywords food security      environmental sustainability      crop water use efficiency      crop science      diet and health     
Corresponding Author(s): William J. DAVIES   
Just Accepted Date: 19 December 2019   Online First Date: 17 January 2020    Issue Date: 02 March 2020
 Cite this article:   
William J. DAVIES,Susan E. WARD,Alan WILSON. Can crop science really help us to produce more better-quality food while reducing the world-wide environmental footprint of agriculture?[J]. Front. Agr. Sci. Eng. , 2020, 7(1): 28-44.
 URL:  
https://academic.hep.com.cn/fase/EN/10.15302/J-FASE-2019299
https://academic.hep.com.cn/fase/EN/Y2020/V7/I1/28
Fig.1  Schematic representation of a collaboration between the food market, industry practitioners, research providers and communication specialists to deliver effective knowledge exchange (KE) to those working within the UK Fresh Produce Supply Chain. Desirable changes in practice toward increased sustainability are identified by the farm assessment program and the training programmes, their effects assessed via the collaborative research program (CRP) and subsequent recommendations communicated to practitioners via a communications portal.
Fig.2  A schematic representation of a Science and Technology Backyard (STB) as conceived by researchers at China Agricultural University (CAU). STB is a hub that connects the science community and the farming community to facilitate knowledge exchange (KE). Potentially-beneficial management technologies are proposed and discussed with leading farmers to enable development of farm-applicable recommendations. Leading farmers test new practices and recommend appropriate innovation to other farmers. Through the hub, government and agribusinesses also engage and help extend innovation. Figure provided by Professors Jianbo Shen and Fusuo Zhang, CAU.
Fig.3  Grain yield, irrigation water use, and water use efficiency (WUE) of rice crops grown under traditional flooding irrigation (TF) and alternate wetting and drying irrigation (AWD) in 2010–2015. Compared with traditional irrigation, AWD increased grain yield by 8.1%–14.2%; AWD reduced water use by 22%–38%; AWD increased WUE by 35%–53%; WUE =Grain yield/Amount of irrigation water. Data provided by Prof. Jianchang Yang, Yangzhou University.
Fig.4  Impact of soil bacteria (Variovorax paradoxus 5C2) and soil drying on growth, yield, water relations, chemical signaling and nodulation of peas grown in field soil. UC indicates untreated controls and 5C2 indicates plants treated with bacteria. Data from Belimov et al.[64].
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