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F e r t i l i z e r B e s t M a n a g e m e n t P r a c t i c e s Fertilizer Best Management Practices General Principles, Strategy for their Adoption and Voluntary Initiatives vs Regulations Papers presented at the IFA International Workshop on Fertilizer Best Management Practices 7-9 March 2007, Brussels, Belgium International Fertilizer Industry Association Paris, France, 2007 The designation employed and the presentation of material in this information product do not imply the expression of any opinion whatsoever on the part of the International Fertilizer Industry Association. This includes matters pertaining to the legal status of any country, territory, city or area or its authorities, or concerning the delimitation of its frontiers or boundaries. Fertilizer Best Management Practices First edition, IFA, Paris, France, August 2007 Copyright 2007 IFA. All rights reserved ISBN 2-9523139-2-X The publication can be downloaded from IFA’s web site. To obtain paper copies, contact IFA. 28, rue Marbeuf, 75008 Paris, France Tel: +33 1 53 93 05 00 Fax: +33 1 53 93 05 45/ 47 [email protected] www.fertilizer.org III Contents Part 1. General principles of fertilizer best management practices Nutrient use effi ciency – measurement and management 1 A. Dobermann Right product, right rate, right time and right place … the foundation of best management practices for fertilizer 29 T.L. Roberts Balanced fertilization for sustainable use of plant nutrients 33 L. Cissé Site-specifi c nutrient management 47 R.J. Buresh and C. Witt Integrated farming and integrated plant nutrient management 57 C. Drummond "Teaspoon feeding": precise plant nutrition through advanced application methods 67 E. Barak and S. Raban Fertilizer best management practices in the context of product stewardship 71 J. Lammel Can we defi ne a global framework within which fertilizer best management practices can be adapted to local conditions? 77 P.E. Fixen Fertilizer best management practices: what level of adaptation to local conditions is realistic in a developing country context? 87 J. Ryan IV Fertilizer best management practices Part 2. Strategy for the adoption of fertilizer best management practices Adoption of fertilizer best management practices: the need for a sociological approach 99 F.G. Palis, R.J. Buresh, G.R. Singleton and R.J. Flor Changing farmers’ behavior in developing countries for a wider adoption of fertilizer best management practices – experience in Thailand 111 K. Soitong Farmers’ behavior and codes of fertiliser best management practices in India – viewpoint of Tata Chemicals Ltd 121 B.B. Singh Preliminary synthesis of farmers’ attitudes and preferences towards nutrient application in China and India 127 H. Magen, P. Imas and S.K. Bansal Stewardship of crop protection products: maximising benefi ts and minimising risks 139 K.A. Jones Part 3. Voluntary initiatives vs regulations An economic evaluation of best management practices for crop nutrients in Canadian agriculture 145 R. Larson Fertilizer best management practices in South America’s agricultural systems 153 R. Melgar and E. Daher Vountary farm management qualifi cation under the French offi cial “Agriculture Raisonnée” scheme 163 P. Eveillard Voluntary initiatives undertaken by the fertiliser industry of New Zealand 167 H. Furness Fertcare® – putting best practice into stewardship 177 N. Drew V Principles, dissemination and performance of fertilizer best management practices developed in China 193 F.S. Zhang, M.S. Fan and W.F. Zhang Voluntary initiatives and regulations for fertiliser best management practices in India 203 R.K. Tewatia Fertilizer best management practices in Pakistan 213 N. Ahmad Fertilizer best management practices in Southeast Asia 221 R.J. Buresh, C. Witt and J.M.C. Pasuquin Global assessment of the situation of fertilizer best management practices 231 A. Krauss Possible entry points for action, an FAO overview 239 J. Poulisse Strategies for controlling nitrogen emissions from agriculture: regulatory, voluntary and economic approaches 245 M.A. Sutton, J.W. Erisman and O. Oenema VI Fertilizer best management practices Acknowledgements Th e IFA Executive Committee decided in 2006 to launch an initiative on fertilizer best management practices (FBMPs). One component of that initiative was the organiza- tion of an International Workshop on Fertilizer Best Management Practices, which took place from 7 to 9 March 2007 in Brussels, Belgium. Th e workshop gathered some 40 participants from all continents and relevant stakeholder categories. It was aimed at (i) defi ning the general principles of FBMPs and the strategy for their wider adop- tion; (ii) defi ning the role of the fertilizer industry in developing and promoting FBMPs and listing priority areas for action; (iii) exchanging information on experiences; (iv) reviewing achievements and identifying gaps; and (v) understanding the actors and identifying the key partners. Th e workshop was conducted under the leadership of the Convenor of the IFA Task Force on Fertilizer Best Management Practices, Mr. R. Sinha from DSCL, India. Th is book is a collection of all the papers submitted by the speakers. In addition to this book, all the papers and slides presented at the workshop are available in PDF format on IFA’s website at www.fertilizer.org/ifa/publicat/bap/2007_brussels_fb mp.asp. No paper has been received for three contributions presented at the workshop, but the correspon- ding slides can be downloaded online. Th e papers published in this book have been reviewed and edited by A. Krauss, K. Isherwood and P. Heff er. Many thanks to C. Aholou-Pütz and H. Ginet for the layout of the book and of the graphics in preparation for printing. Part 1. General principles of FBMPs 1 Nutrient use effi ciency – measurement and management A. Dobermann University of Nebraska-Lincoln, USA; [email protected] Nutrients in the global scheme Mineral fertilizers have sustained world agriculture and thus global population and wealth growth for more than 100 years (Smil, 2001; Stewart et al., 2005). Th eir contribu- tion to increasing crop yields has spared millions of hectares of natural ecosystems that otherwise would have been converted to agriculture (Balmford et al., 2005). However, lacking, imbalanced, inappropriate or excessive use of nutrients in agricultural systems remains a concern. Nutrient mining is a major cause for low crop yields in parts of the developing world, particularly Africa. In other situations, nutrients such as nitrogen (N) and phosphorus (P) oft en move beyond the bounds of the agricultural fi eld because the management practices used fail to achieve good congruence between nutrient sup- ply and crop nutrient demand (van Noordwijk and Cadisch, 2002). If left unchecked, such losses may bear signifi cant costs to society (Mosier et al., 2001). Hence, increasing nutrient use effi ciency continues to be a major challenge for world agriculture. Th is paper tries to summarize how the use effi ciency of N, P and potassium (K) from mineral fertilizer is commonly defi ned and measured, what needs to be considered for interpreting such values, and how it can be improved through soil, crop and fertili- zer management. It focuses on cereal systems because those consume the bulk of the world’s fertilizer, but the principles discussed are similar in all agricultural crops. Where possible, attempts are made to discuss diff erences between developed and developing countries. Two key messages emerge: (i) Nutrient use effi ciencies measured under prac- tical farming conditions are mostly lower than those reported from research experi- ments, but information on current levels of fertilizer use and nutrient use effi ciency by diff erent crops, cropping systems and world regions remains insuffi cient; (ii) Numerous technologies for increasing nutrient use effi ciency exist. Th ey have been evaluated tho- roughly, but adoption by farmers is lagging behind. Measuring nutrient use effi ciency Agronomic indices for short-term assessment of nutrient use effi ciency Table 1 summarizes a set of simple indices that are frequently used in agronomic re- search to assess the effi ciency of applied fertilizer (Novoa and Loomis, 1981; Cassman et al., 2002), mainly for assessing the short-term crop response to a nutrient. A practical example is illustrated in Figure 1. Other indices are sometimes used (Gourley et al., 1993; Huggins and Pan, 1993), but they have no additional advantages for understan- ding fertilizer best management practices (FBMPs). More detailed studies on the fate 2 Fertilizer best management practices Table 1. Indices of nutrient use effi ciency, their calculation using the difference method, and their interpretation. Index Calculation Interpretation Nitrogen in cereals RE = Apparent crop RE=(U – Uo)/F • RE depends on the 0.30–0.50 kg/kg; recovery effi ciency congruence between plant 0.50–0.80 kg/kg of applied nutrient demand and nutrient release in well-managed (kg increase in N from fertilizer. systems, at low uptake per kg N • RE is affected by the ap- levels of N use, applied) plication method (amount, or at low soil N timing, placement, N form) supply and factors that determine the size of the crop nutrient sink (genotype, climate, plant density, abiotic/biotic stresses). PE = Physiological PE=(Y– Yo)/(U– Uo) • Ability of a plant to trans- 40–60 kg/kg; effi ciency of ap- form nutrients acquired >50 kg/kg in plied N from fertilizer into economic well-managed (kg yield increase yield (grain). systems, at low per kg increase in • Depends on genotype, levels of N use, N uptake from fer- environment and manage- or at low soil N tilizer) ment. supply • Low PE suggests sub-op- timal growth (nutrient de- fi ciencies, drought stress, heat stress, mineral toxici- ties, pests). IE = Internal utili- IE=Y/U • Ability of a plant to trans- 30–90 kg/kg; zation effi ciency of form nutrients acquired 55-65 kg/kg is a nutrient from all sources (soil, fer- the optimal ran- (kg yield per kg nu- tilizer) into economic yield ge for balanced trient uptake) (grain). nutrition at high • Depends on genotype, yield levels environment and manage- ment. • A very high IE suggests de- fi ciency of that nutrient. • Low IE suggests poor inter- nal nutrient conversion due to other stresses (nutrient defi ciencies, drought stress, heat stress, mineral toxici- ties, pests). Part 1. General principles of FBMPs 3 AE = Agronomic AE=(Y – Yo)/F or • Product of nutrient reco- 10–30 kg/kg; effi ciency of ap- AE=RE x PE very from mineral or organic >25 kg/kg in plied nutrient fertilizer (RE) and the effi - well-managed (kg yield increase ciency with which the plant systems, at low per kg nutrient ap- uses each additional unit of levels of N use, plied) nutrient (PE). or at low soil N • AE depends on manage- supply ment practices that affect RE and PE. PFP = Partial fac- PFP=Y/F or • Most important for farmers 40–80 kg/kg; tor productivity of PFP=(Yo/F) + AE because it integrates the use >60 kg/kg in applied nutrient effi ciency of both indigenous well-managed (kg harvested pro- and applied nutrients. systems, at low duct per kg nu- • High indigenous soil nu- levels of N use, trient applied) trient supply (Yo) and high or at low soil N AE are equally important for supply PFP. F – amount of (fertilizer) nutrient applied (kg/ha) Y – crop yield with applied nutrients (kg/ha) Yo – crop yield (kg/ha) in a control treatment with no N U – total plant nutrient uptake in aboveground biomass at maturity (kg/ha) in a plot that received fertilizer U – total nutrient uptake in aboveground biomass at maturity (kg/ha) in a plot that received no fertilizer of nutrients in agro-ecosystems oft en involve isotopes, which are particularly useful for understanding loss, immobilization, fi xation and release mechanisms. In fi eld studies, nutrient use effi ciencies are either calculated based on diff erences in crop yield and/or nutrient uptake between fertilized plots and an unfertilized control (‘diff erence method’, Table 1), or by using isotope-labeled fertilizers to estimate crop and soil recovery of applied nutrients. Time scale is usually one cropping season. Spatial sca- le for measurement is mostly a fi eld or plot. For the same soil and cropping conditions, nutrient use effi ciency generally decreases with increasing nutrient amount added (Fi- gure 1). Crop yield (Y) and plant nutrient accumulation/uptake (U) typically increase with increasing nutrient addition (F) and gradually approach a ceiling (Figures 1a and 1c). Th e level of this ceiling is determined by the climatic-genetic yield potential. At low levels of nutrient supply, rates of increase in yield and nutrient uptake are large because the nutrient of interest is the primary factor limiting growth (de Wit, 1992). As nutrient supply increases, incremental yield gains become smaller because yield determinants other than that nutrient become more limiting as the yield potential is approached. Because each of the indices in Table 1 has a diff erent interpretation value, fertilizer research should include measurements of several indices to understand the factors go- verning nutrient uptake and fertilizer effi ciency, to compare short-term nutrient use ef- fi ciency in diff erent environments, and to evaluate diff erent management strategies. Th e

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