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Figure No.
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Figure Title
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Figure 1-1
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Output and share of insecticides in China's pesticide industry, 2000-H1 2012
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Figure 1-2
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Geographical distribution of insecticide production in China by output, 2011
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Figure 1-3
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Demand structure of insecticides by volume in China, 2011
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Figure 2.1-1
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Number of chlorpyrifos registrations in China, 1987-August 2012
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Figure 2.1-2
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Capacity and output of chlorpyrifos technical in China, 2006-2011
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Figure 2.1-3
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Chemical principle of chlorpyrifos synthesis in China
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Figure 2.1-4
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STCP synthesis by trichloroacetyl chloride route
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Figure 2.1-5
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STCP synthesis by pyridine route
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Figure 2.1-6
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General production process of chlorpyrifos technical by trichloroacetyl chloride route
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Figure 2.1-7
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Manufacturing process of TCP from pyridine
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Figure 2.1-8
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Ex-work price of chlorpyrifos 95% technical in China, Jan. 2008-July 2012
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Figure 2.1-9
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Ex-work price of chlorpyrifos 480g/L EC in China, Jan. 2008-July 2012
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Figure 2.1-10
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Consumption structure of chlorpyrifos by crops in China, 2011
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Figure 2.1-11
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Forecast on output of chlorpyrifos technical in China, 2012-2016
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Figure 2.1-12
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Forecast on consumption volume (by 97% technical) and value of chlorpyrifos in China, 2012-2016
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Figure 2.2-1
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Process route of abamectin technical
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Figure 2.2-2
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Capacity and output of abamectin technical in China, 2009-2011
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Figure 2.2-3
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Ex-work price of abamectin 95% technical in China, Jan. 2008-Aug. 2012
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Figure 2.2-4
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Ex-work price of abamectin 18g/L EC in China, Jan. 2008-Aug. 2012
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Figure 2.2-5
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Consumption structure of abamectin in China, 2011
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Figure 2.2-6
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Consumption situation of abamectin in China, 2009-2011
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Figure 2.2-7
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Forecast on output of abamectin technical in China, 2012-2016
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Figure 2.2-8
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Forecast on consumption volume (by 95% tech.) and value of abamectin in China, 2012-2016
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Figure 2.3-1
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Capacity and output of imidacloprid technical in China, 2009-2011
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Figure 2.3-2
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CCMP synthesis by DCPD route
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Figure 2.3-3
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Process flow chart of imidacloprid technical by DCPD route
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Figure 2.3-4
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Average ex-work price of imidacloprid 95% technical in China, Jan. 2008-July 2012
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Figure 2.3-5
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Consumption volume of imidacloprid (calculated by 95% technical) in China, 2008-2011
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Figure 2.3-6
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Forecast on output of imidacloprid technical (95%) in China, 2012-2016
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Figure 2.3-7
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Forecast on consumption volume (by 95% technical) and value of imidacloprid in China, 2012-2016
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Figure 2.4-1
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Capacity and output of phoxim technical in China, 2008-2011
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Figure 2.4-2
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Ex-work price of phoxim 90% technical in China, 2008-Aug. 2012
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Figure 2.4-3
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Consumption structure of phoxim by crops in China, 2011
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Figure 2.4-4
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Forecast on output of phoxim technical (by 90% technical) in China, 2012-2016
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Figure 2.4-5
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Forecast on consumption volume (by 90% technical) and value of phoxim in China, 2012-2016
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Figure 2.5-1
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Capacity and output of triazophos technical in China, 2009-2011
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Figure 2.5-2
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First reaction process of triazophos production
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Figure 2.5-3
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Second reaction process of triazophos production
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Figure 2.5-4
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Third reaction process of triazophos production
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Figure 2.5-5
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Ex-work price of triazophos 85% technical in China, 2009-Aug. 2012
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Figure 2.5-6
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Consumption structure of triazophos by crops in China, 2011
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Figure 2.5-7
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Output forecast of triazophos technical (85%) in China, 2012-2016
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Figure 2.5-8
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Forecast on domestic consumption volume (by 85% technical) and its value of triazophos, 2012-2016
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Figure 2.6-1
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Capacity and output of bifenthrin technical in China, 2009-2011
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Figure 2.6-2
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Ex-work price of bifenthrin 97% technical in China, 2009-Aug. 2012
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Figure 2.6-3
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Consumption structure of bifenthrin by crops in China, 2011
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Figure 2.6-4
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Forecast on output of bifenthrin technical (calculated to 97% technical) in China, 2012-2016
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Figure 2.6-5
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Forecast on consumption volume (by 97% technical) and value of bifenthrin in China, 2012-2016
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Figure 2.7-1
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Capacity and output of carbofuran technical in China, 2008-2011
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Figure 2.7-2
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Average ex-work price of carbofuran 98% technical in China, 2008-2011
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Figure 2.7-3
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Consumption structure of carbofuran by crops in China, 2011
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Figure 2.7-4
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Forecast on output of carbofuran (by 98% technical) in China, 2012-2016
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Figure 2.7-5
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Forecast on consumption volume (by 98% technical) and value of carbofuran in China, 2012-2016
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Figure 2.8-1
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Capacity and output of dichlorvos technical in China, 2008-2011
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Figure 2.8-2
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New method of dichlorvos production developed by E.Beriger
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Figure 2.8-3
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Dichlorvos synthesis by dipterex route
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Figure 2.8-4
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Dichlorvos synthesis by trimethyl phosphite route
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Figure 2.8-5
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Average ex-work price of dichlorvos 95% technical in China, 2008-2011
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Figure 2.8-6
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Consumption structure of dichlorvos by crops in China, 2011
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Figure 2.8-7
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Forecast on output of dichlorvos (95% technical) in China, 2012-2016
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Figure 2.8-8
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Forecast on consumption volume (by 95% technical) and value of dichlorvos in China, 2012-2016
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Figure 2.9-1
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Capacity and output of trichlorfon technical in China, 2009-2011
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Figure 2.9-2
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Ex-work price of trichlorfon 90% technical in China, 2006-2011
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Figure 2.9-3
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Consumption structure of trichlorfon in China, 2011
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Figure 2.9-4
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Forecast on output of trichlorfon technical (by 90% technical) in China, 2012-2016
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Figure 2.9-5
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Forecast on consumption volume (by 90% technical) and value of trichlorfon in China, 2012-2016
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Figure 2.10-1
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Registration structure of lambda-cyhalothrin by formulations types in China, as of Aug. 2012
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Figure 2.10-2
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Capacity and output of lambda-cyhalothrin technical in China, 2008-2011
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Figure 2.10-3
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Ex-work price of lambda-cyhalothrin 95% technical in China, Jan. 2008-Aug. 2012
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Figure 2.10-4
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Ex-work price of lambda-cyhalothrin 25g/L EC in China, Jan. 2008-Aug. 2012
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Figure 2.10-5
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Consumption structure of lambda-cyhalothrin in China, 2011
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Figure 2.10-6
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Forecast on output of lambda-cyhalothrin technical in China, 2012-2016
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Figure 2.10-7
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Forecast on consumption volume (by 95% technical) and value of lambda-cyhalothrin in China, 2012-2016
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Figure 2.11-1
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Capacity and output of acephate technical in China, 2008-2011
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Figure 2.11-2
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Isomerization chemical reaction in acephate production
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Figure 2.11-3
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Chemical equation of making acephate, adopting acetic anhydride as acidylating agent
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Figure 2.11-4
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Chemical equation of making acephate, adopting acetyl chloride acylation as acidylating agents
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Figure 2.11-5
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Chemical equation of making acephate, adopting acetic acid and phosphorus trichloride as acidylating agents
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Figure 2.11-6
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Process flow of acephate production
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Figure 2.11-7
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Average ex-work price of acephate 97% technical in China, 2006-2011
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Figure 2.11-8
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Consumption structure of acephate by crops in China, 2011
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Figure 2.11-9
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Forecast on output of acephate technical (by 97% technical) in China, 2012-2016
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Figure 2.11-10
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Forecast on consumption volume (by 97% technical) and value of acephate in China, 2012-2016
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Figure 2.12-1
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Capacity and output of dimethoate technical in China, 2008-2011
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Figure 2.12-2
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Average ex-work price of dimethoate 98% technical in China, 2007-2011
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Figure 2.12-3
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Consumption structure of dimethoate by crops in China, 2011
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Figure 2.12-4
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Forecast on output of dimethoate technical (by 98% technical) in China, 2012-2016
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Figure 2.12-5
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Forecast on consumption volume (by 98% technical) and value of dimethoate in China, 2012-2016
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