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市場調查報告書

中國的農藥產業分析

Survey of Pesticide Industry in China

出版商 CCM 商品編碼 257228
出版日期 內容資訊 英文 384 Pages
商品交期: 最快1-2個工作天內
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中國的農藥產業分析 Survey of Pesticide Industry in China
出版日期: 2014年04月04日 內容資訊: 英文 384 Pages
簡介

中國是全球最大的農藥生產國,也是農藥消費國。中國的農藥生產量,從2007年到2013年間以年複合成長率(CAGR)10.7%擴大,2013年達到了319萬噸。還有2013年的農藥需求數量成為大約44萬4000噸,越來越多的企業進到中國的農藥市場。

本報告提供中國的農藥(殺蟲劑、除草劑、殺菌劑等)市場相關分析、整體產業結構、特徵、各種的影響要素、各部門、主要產品的市場規模的實際成果值、大企業的競爭力、今後的市場機會、主要企業簡介等調查評估,並將其結果依為您概述為以下內容。

摘要整理

定義、分析範圍、分析方法

第1章 中國的農藥產業概要

  • 發展歷史
  • 主要的特徵
  • 企業的企業合併、收購(M&A)
  • 市場分析
    • 需求與供給
    • 廠商
    • 典型性的農藥

第2章 農藥對產業的影響要素

  • 政策的要素
    • 農藥產業相關產業政策
    • 農藥廠商認證相關政策
    • 農藥登記事務相關政策
    • 農藥相關的污水排放相關法規
  • 社會環境
    • 農藥用戶的特徵
    • 都市化
    • 基因改造(GM)作物的安全性相關爭議
  • 經濟要素
  • 環境/自然地要素
    • 作物的栽培情形(結構、領域)
    • 基因改造農作物狀況
    • 無耕地作物狀況
    • 害蟲、疾病發生和抵抗力
  • 技術性要素

第3章 主要殺蟲劑的市場分析

  • 中國的殺蟲劑產業概要
  • 陶斯松(Chlorpyrifos)
  • 阿巴汀(Avermectin)
  • 益達胺(Imidacloprid)
  • 辛硫磷(Phoxim)
  • 三落松(Triazophos)
  • 畢芬寧(Bifenthrin)
  • 加保扶(Carbofuran)
  • 二氯松(Dichlorvos)
  • 三氯松(Trichlorfon)
  • 其他殺蟲劑(共3種)

第4章 主要除草劑的市場分析

  • 中國的除草劑產業概要
  • 嘉磷塞(Glyphosate)
  • 乙草胺(Acetochlor)
  • 巴拉刈(Paraquat)
  • 2,4-D
  • 草脫淨(Atrazine)
  • 苯磺隆(Tribenuron-methyl)
  • 免速隆(Bensulfuron-methyl)
  • 莫多草(Metolachlor)
  • 施得圃(Pendimethalin)
  • 其他除草劑(計3種)

第5章 主要殺菌劑的市場分析

  • 中國的殺菌劑產業概要
  • 鋅錳乃浦(mancozeb)
  • 貝芬替(Carbendazim)
  • 得克利(Tebuconazole)
  • 甲基多保淨(Thiophanate methyl)
  • 三泰芬(Triadimefon)
  • 待克利(Difenoconazole)
  • 三賽唑(Tricyclazole)
  • 亞賜圃(Isoprothiolane)
  • 四氯異苯腈(chlorothalonil)
  • 其他殺菌劑(共3種)

第6章 競爭環境和今後的供需預測

  • 全球市場的中國的農藥產業:主要的競爭力和弱點
  • 農藥產業發展的主要原因和推動因素
  • 農藥產業的未來預測(今後5年份)

第7章 代表性的10家農藥廠商的SWOT分析

第8章 中國農藥產業的商業機會

  • 對外資企業來說的優點
  • 農藥產業適當的地區
  • 商業機會

第9章 附錄:主要的農藥製造商簡介

  • Nanjing Redsun Co., Ltd.
  • Zhejiang Wynca Chemical Industry Group Co., Ltd.
  • Jiangsu Yangnong Chemical Group Co., Ltd.
  • Anhui Huaxing Chemical Industry Co., Ltd.
  • Shandong Weifang Rainbow Chemical Co., Ltd.
  • Zhejiang Jinfanda Bio-chemical Co., Ltd.
  • Hubei Sanonda Co., Ltd.
  • Nantong Jiangshan Agrochemical & Chemical Co., Ltd.
  • Shandong Binnong Technology Co., Ltd.
  • Jiangsu Changlong Chemical Co., Ltd.
  • Jiangsu Fengshan Group Co., Ltd.
  • Jiangsu Kwin Group Co., Ltd.
  • Shandong Qiaochang Chemical Co., Ltd.
  • Jiangsu Changqing Agrochemical Co., Ltd.
  • Jiangsu Huifeng Agrochemical Co., Ltd.
  • Hebei Veyong Bio-Chemical Co., Ltd.
  • Hunan Haili Chemical Industry Co., Ltd.
  • Jiangsu Good Harvest-Weien Agrochemical Co., Ltd.
  • ZhongShan Chemical Industries Group
  • Lier Chemical Co., Ltd.
  • Anhui Guangxin Agrochemical Co., Ltd.
  • Jiangsu Lanfeng Biochemical Co., Ltd.
  • Limin Chemical Co., Ltd.
  • Jiangsu Sevencontinent Green Chemical Co., Ltd.

圖表一覽

本網頁內容可能與最新版本有所差異。詳細情況請與我們聯繫。

目錄

Chinese government is now actively raising the overall industrial strength for domestic pesticide industry by means of releasing stricter environmental protection policies, heightening entrance threshold, phasing out highly toxic and highly residual pesticide varieties, etc.

China currently can produce 350 kinds of pesticide technical, and over 250 kinds have actual productive capacity, which are usually generic products. Traditional pesticide varieties like glyphosate and chlorpyrfos usually account for the largest proportion of the total in China's pesticide products.

China has been gradually endeavoring to heighten R&D capability of innovative pesticide creation. Up to now, about 30 new AI(s) have been developed. However, few of them have realized commercial production due to factors like capital shortage.

The registrations of traditional formulations EC and WP still keep dominant, but its share in terms of number of registrations kept decreasing from over 60% in the past to 51.5% in 2013. Along with the adjustment of formulation production and consumption, the proportion of environmentally friendly formulations such as WG, SC and EW is gradually increasing.

China's pesticide production is mainly concentrated in East China including Shandong, Jiangsu, Zhejiang and Hubei, in terms of both the number of producers and tonnage, with the subtotal output contributing nearly 70% to the nation's total pesticide output. Thereinto, Shandong and Jiangsu are the most important regions for China's pesticide production.

China's pesticide consumption structure has changed a little bit in recent years due to adjustment of planting structure, farmers' pesticide application habit, labor structure change, etc. For instance, China's insecticide consumption on cotton has reduced obviously since 1998 due to China's increasing promotion for cultivation of GM cotton with BT Gene. Domestic demand for insecticides sees a -1.1% CAGR during 2006-2013. But the total herbicide demand in China increases obviously along with the non-tillage cultivation area expansion, together with the reduction of rural labor forces, seeing a 11.1% CAGR during 2006-2013. As for fungicides, its domestic demand has increased slightly with a 2.6% CAGR during 2006-2013.

China exports pesticides to over 160 countries and regions all over the world. According to the General Administration of Customs, the export volume grows to 1.10 million tonnes in 2013 with a YoY growth rate of 22.1%, and the export value increases to USD3,745 million with a YoY growth rate of 31.0%. Herbicides keep the largest category for export, and its export volume accounts for 69.0% of the total volume in 2013.

China's pesticide import also sees uptrend, and the import volume reached 68,912 tonnes in 2012 and 76,200 tonnes in 2013 respectively.

Industrial affairs:

The global sales of agrochemicals kept increasing and reached 59.16 billion dollars in 2013, with a YoY growth rate of 10.1%.

China's position:

With over 60 years' development, China has become the biggest production base of pesticides in the world. China's pesticide output has continuously increased in the past few years with a CAGR (2007-2013) of 10.7%, and it reaches 3.19 million tonnes (by 100% technical) in 2013. The output value of pesticides in China hit about USD46.7 billion in 2013, seeing a 16.6% CAGR during 2007-2013.

Meanwhile, China is also a big pesticides consumer in the world. As one of the biggest agricultural countries in the world, China has maintained its crop area of over 160 million hectares including grain planting area of over 110 million hectares in the past four years, which is the rigid support for large domestic pesticide demand. China's total pesticide demand was around 444,000 tonnes (by technical) in 2013, attracting more and more companies entering China's pesticide market.

Purpose of report:

  • Present the latest data from aspects of registration, production, producer, price, consumption (till 2013)
  • Forecast the development of 36 key pesticides

Application user:

  • Pesticides producers;
  • Pesticides traders, distributors, etc.
  • Consulting companies
  • Investors

What to report:

  • Overall situation of China's pesticides industry
    • Supply, demand, producers
    • Competitive landscape
    • Future demand forecast
    • SWOT analysis of 10 typical pesticide manufacturers
    • Potential commercial opportunities
  • Market analysis of 36 key pesticides
    • Registration as of Mar. 2014
    • Production, producer 2009-2013
    • Price from Jan. 2008 (or Jan. 2009)-Feb. 2014
    • Technology
    • Consumption by volume and value 2009-2013
    • Future supply & demand forecast 2014-2018

Forecast on industry:

  • China will keep playing an important role in the global market;
  • The domestic consumption of herbicides, fungicides and other pesticides will keep increasing, while that of insecticides will decrease a little.

Value to client:

Deeply understand China's pesticides industry

Methodology:

  • Desk based research
  • Telephone interviews
  • Questionnaire surveys

Executive summary:

With over 60 years' development, China has become the biggest production base of pesticides in the world. China's pesticide output has continuously increased in the past few years with a CAGR (2007-2013) of XX%, and it reaches XX million tonnes (by 100% technical) in 2013. The output value of pesticides in China hit about USDXX billion in 2013, seeing XX% CAGR during 2007-2013.

Meanwhile, China is also a big pesticides consumer in the world. As one of the biggest agricultural countries in the world, China has maintained its crop area of over XX million hectares including grain planting area of over XX million hectares in the past four years, which is the rigid support for large domestic pesticide demand. China's total pesticide demand was around XX tonnes (by technical) in 2013, attracting more and more companies entering China's pesticide market.

However, there are many problems in China's pesticide industry, such as overcapacity for most pesticide varieties due to blind capacity expansion without proper management from related departments, too many small manufacturers with inefficient production technologies, few companies with international competitiveness due to capital shortage, few well-known brands, and serious environmental pollution problems.

Chinese government is now actively raising the overall industrial strength for domestic pesticide industry by means of releasing stricter environmental protection policies, heightening entrance threshold, phasing out highly toxic and highly residual pesticide varieties, etc.

China currently can produce XX kinds of pesticide technical, and over XX kinds have actual productive capacity, which are usually generic products. Traditional pesticide varieties like glyphosate and chlorpyrfos usually account for the largest proportion of the total in China's pesticide products. Uncomplicated production technologies, mature production processes, stable market demand and sufficient raw material supply as well as easier registration approval are major reasons for such a large proportion of traditional pesticides in China. However, most traditional pesticide varieties face overcapacity currently.

The share of herbicide output firstly exceeded XX% in 2012, and it kept increasing in 2013, reaching XX%, while that of insecticides decreased to XX%.

China has been gradually endeavoring to heighten R&D capability of innovative pesticide creation. Up to now, about XX new AI(s) have been developed. However, few of them have realized commercial production due to factors like capital shortage.

Table of Contents

Executive summary

Definition, scope and methodology

1 Overview of China's pesticide industry

  • 1-1 Development history
  • 1-2 Market characteristics
  • 1-3 Enterprise M&A
  • 1-4 Market analysis
    • 1-4-1 Supply and demand
    • 1-4-2 Producers
    • 1-4-3 Typical pesticides

2 Factors influencing on Chinese pesticide industry

  • 2-1 Policy factor
    • 2-1-1 Industrial policy for pesticide industry
    • 2-1-2 Pesticide manufacturer approval policies
    • 2-1-3 Pesticide registration administration policies
    • 2-1-4 Sewage discharge regulations related to pesticides
  • 2-2 Social environment
    • 2-2-1 Characteristics of pesticide users
    • 2-2-2 Urbanization
    • 2-2-3 Controversial issues on safety of GM crops
  • 2-3 Economic factors
  • 2-4 Environmental/natural factors
    • 2-4-1 Situation of crop cultivation (structure and area)
    • 2-4-2 Situation of GM crops
    • 2-4-3 Situation of non-tillage crops
    • 2-4-4 Pest and disease occurrence and resistance
  • 2-5 Technological factors

3 Market analysis of major insecticides in China

  • 3-1 Overview of Chinese insecticides industry
  • 3-2 Chlorpyrifos
  • 3-3 Abamectin
  • 3-4 Imidacloprid
  • 3-5 Phoxim
  • 3-6 Triazophos
  • 3-7 Bifenthrin
  • 3-8 Carbofuran
  • 3-9 Dichlorvos
  • 3-10 Trichlorfon
  • 3-11 Other insecticides
    • 3-11-1 Lambda-cyhalothrin
    • 3-11-2 Acephate
    • 3-11-3 Dimethoate

4 Market analysis of major herbicides in China

  • 4-1 Overview of Chinese herbicides industry
  • 4-2 Glyphosate
  • 4-3 Acetochlor
  • 4-4 Paraquat
  • 4-5 2,4-D
  • 4-6 Atrazine
  • 4-7 Tribenuron-methyl
  • 4-8 Bensulfuron-methyl
  • 4-9 Metolachlor
  • 4-10 Pendimethalin
  • 4-11 Other herbicides
    • 4-11-1 Fenoxaprop-P-ethyl
    • 4-11-2 Quizalofop-P-ethyl
    • 4-11-3 Dicamba

5 Market analysis of major fungicides in China

  • 5-1 Overview of Chinese fungicide industry
  • 5-2 Mancozeb
  • 5-3 Carbendazim
  • 5-4 Tebuconazole
  • 5-5 Thiophanate-methyl
  • 5-6 Triadimefon
  • 5-7 Difenoconazole
  • 5-8 Tricyclazole
  • 5-9 Isoprothiolane
  • 5-10 Chlorothalonil
  • 5-11 Other fungicides
    • 5-11-1 Prochloraz
    • 5-11-2 Dimethomorph
    • 5-11-3 Azoxystrobin

6 Competitive landscape and future demand forecast

  • 6-1 Key competitiveness and weakness of Chinese pesticide industry in global market
  • 6-2 Key factors and driving forces for development of pesticide industry in China
  • 6-3 Future forecast on pesticide industry 2014-2018

7 SWOT analysis of 10 typical pesticide manufacturers

8 Commercial opportunities in Chinese pesticide industry

  • 8-1 Benefits for foreign investors
  • 8-2 Preferred regions for agrochemicals
  • 8-3 Commercial opportunities

9 Appendix: Profiles of key pesticide manufacturers

  • 9-1 Nanjing Redsun Co., Ltd.
  • 9-2 Zhejiang Wynca Chemical Industry Group Co., Ltd.
  • 9-3 Jiangsu Yangnong Chemical Group Co., Ltd.
  • 9-4 Anhui Huaxing Chemical Industry Co., Ltd.
  • 9-5 Shandong Weifang Rainbow Chemical Co., Ltd.
  • 9-6 Zhejiang Jinfanda Bio-chemical Co., Ltd.
  • 9-7 Hubei Sanonda Co., Ltd.
  • 9-8 Nantong Jiangshan Agrochemical & Chemical Co., Ltd.
  • 9-9 Shandong Binnong Technology Co., Ltd.
  • 9-10 Jiangsu Changlong Chemical Co., Ltd.
  • 9-11 Jiangsu Fengshan Group Co., Ltd.
  • 9-12 Jiangsu Kwin Group Co., Ltd.
  • 9-13 Shandong Qiaochang Chemical Co., Ltd.
  • 9-14 Jiangsu Changqing Agrochemical Co., Ltd.
  • 9-15 Jiangsu Huifeng Agrochemical Co., Ltd.
  • 9-16 Hebei Veyong Bio-Chemical Co., Ltd.
  • 9-17 Hunan Haili Chemical Industry Co., Ltd.
  • 9-18 Jiangsu Good Harvest-Weien Agrochemical Co., Ltd.
  • 9-19 ZhongShan Chemical Industries Group
  • 9-20 Lier Chemical Co., Ltd.
  • 9-21 Anhui Guangxin Agrochemical Co., Ltd.
  • 9-22 Jiangsu Lanfeng Biochemical Co., Ltd.
  • 9-23 Limin Chemical Co., Ltd.
  • 9-24 Jiangsu Sevencontinent Green Chemical Co., Ltd.

List of tables:

  • Table 1.1-1 Development history of China's pesticide industry
  • Table 1.3-1 Major M&A cases in China's pesticide industry, 2011-2013
  • Table 1.3-2 List of eight batches of M&A in China's pesticide industry, 2012
  • Table 1.3-3 List of seven batches of M&A in China's pesticide industry, 2013
  • Table 1.4.1-1 Output structure of pesticides by volume (calculated by 100% technical) in China, 1986-2013 ('000 tonne)
  • Table 1.4.1-2 Output value of pesticides in China (calculated by 100% technical), 2007-2013, million USD
  • Table 1.4.1-3 Sown area of main crops in China, 2007-2012, '000 ha.
  • Table 1.4.1-4 Consumption volume (by technical) of pesticides in China, 2007-2012, tonne
  • Table 1.4.1-5 Consumption volume (by technical) and value of pesticides in China, 2011-2013, volume: tonne; value: million USD
  • Table 1.4.3-1 Actual consumption of main pesticides in China (converted to technical), 2013, tonne
  • Table 1.4.3-2 Market value of main pesticides in China, 2013, million USD
  • Table 2.1-1 Major administrations and policies on pesticides or pesticide industry in China
  • Table 2.1.2-1 Restricted pesticides in Pesticide Production Entrance Conditions, 2011
  • Table 2.1.3-1 Basic registration policies in Chinese pesticide industry, as of Sept. 2012
  • Table 2.1.4-1 Components of effluent standards of pollutants for pesticide industry in China
  • Table 2.1.4-2 Integrated wastewater discharge standard, GB8978-1996, mg/L
  • Table 2.1.4-3 Environmental protection policies and environmental cost in pesticide industry in China, 2013
  • Table 2.4.2-1 Key regulations on GMO and GM technology in China, as of Mar. 2014
  • Table 2.4.3-1 Advantages of non-tillage cultivation technology
  • Table 2.4.4-1 Common pesticide-resistant insect pests and diseases in China, 2012
  • Table 2.5-1 Technologies promoted by Chinese government, as of Feb. 2013
  • Table 3.1-1 Major varieties of insecticides in China
  • Table 3.2-1 Valid registrations of chlorpyrifos in China, as of Mar. 2014
  • Table 3.2-2 Basic information on main chlorpyrifos technical producers in China
  • Table 3.2-3 Capacity and output of main chlorpyrifos technical producers in China, 2009-2013
  • Table 3.2-4 Comparison between trichloroacetyl chloride route and pyridine route in the production of STCP
  • Table 3.2-5 Apparent consumption of chlorpyrifos in China, 2006-2013, tonne
  • Table 3.2-6 Consumption volume and market value of chlorpyrifos in China, 2006-2013
  • Table 3.3-1 Valid registrations of abamectin formulations in China, as of Mar. 2014
  • Table 3.3-2 Comparison of two fermentation routes for abamectin production in China
  • Table 3.3-3 Basic information on main abamectin technical producers in China
  • Table 3.3-4 Capacity and output of main abamectin technical producers in China, 2009-2013
  • Table 3.3-5 Apparent consumption of abamectin in China, 2009-2013, tonne
  • Table 3.3-6 Consumption volume and market value of abamectin in China, 2009-2013
  • Table 3.4-1 Valid registrations of imidacloprid in China, as of Mar. 2014
  • Table 3.4-2 Basic information on main imidacloprid technical producers in China
  • Table 3.4-3 Capacity and output of main imidacloprid technical producers in China, 2009-2013
  • Table 3.4-4 Comparison of major imidacloprid production routes in China
  • Table 3.4-5 Apparent consumption of imidacloprid calculated by 97% technical in China, 2008-2013, tonne
  • Table 3.4-6 Consumption volume and market value of imidacloprid in China, 2008-2013
  • Table 3.5-1 Valid registrations of phoxim formulations in China, as of Mar. 2014
  • Table 3.5-2 Basic information on main phoxim technical producers in China
  • Table 3.5-3 Capacity and output of main phoxim technical producers in China, 2009-2013
  • Table 3.5-4 Apparent consumption of phoxim in China, 2008-2013, tonne
  • Table 3.5-5 Consumption volume and market value of phoxim in China, 2008-2013
  • Table 3.6-1 Valid registrations of triazophos formulations in China, as of Mar. 2014
  • Table 3.6-2 Basic information on main triazophos technical producers in China
  • Table 3.6-3 Capacity and output of main triazophos technical producers in China, 2009-2012
  • Table 3.6-4 Apparent consumption of triazophos in China, 2009-2013, tonne
  • Table 3.6-5 Consumption volume and market value of triazophos in China, 2009-2013
  • Table 3.7-1 Valid registrations of bifenthrin formulations in China, as of Mar. 2014
  • Table 3.7-2 Basic information on main bifenthrin technical producers in China
  • Table 3.7-3 Capacity and output of main bifenthrin technical producers in China, 2009-2013
  • Table 3.7-4 Apparent consumption of bifenthrin in China, 2009-2013, tonne
  • Table 3.7-5 Consumption volume and market value of bifenthrin in China, 2009-2013
  • Table 3.8-1 Valid registrations of carbofuran in China, as of Mar. 2014
  • Table 3.8-2 Basic information on main carbofuran technical producers in China
  • Table 3.8-3 Capacity and output of main carbofuran technical producers in China, 2009-2013
  • Table 3.8-4 Apparent consumption of carbofuran in China, 2008-2013, tonne
  • Table 3.8-5 Consumption volume and market value of carbofuran in China, 2008-2013
  • Table 3.9-1 Valid registrations of dichlorvos in China, as of Mar. 2014
  • Table 3.9-2 Basic information on main dichlorvos technical producers in China
  • Table 3.9-3 Capacity and output of main dichlorvos technical producers in China, 2009-2013
  • Table 3.9-4 Apparent consumption of dichlorvos in China, 2008-2013, tonne
  • Table 3.9-5 Consumption volume and market value of dichlorvos in China, 2008-2013
  • Table 3.10-1 Valid registrations of trichlorfon formulations in China, as of Mar. 2014
  • Table 3.10-2 Basic information on main trichlorfon technical producers in China
  • Table 3.10-3 Capacity and output of main trichlorfon technical producers in China, 2009-2013
  • Table 3.10-4 Apparent consumption of trichlorfon in China, 2009-2013, tonne
  • Table 3.10-5 Consumption volume and market value of trichlorfon in China, 2009-2013
  • Table 3.11.1-1 Valid registrations of lambda-cyhalothrin in China, as of Mar. 2014
  • Table 3.11.1-2 Basic information on main lambda-cyhalothrin technical producers in China
  • Table 3.11.1-3 Capacity and output of main lambda-cyhalothrin technical producers in China, 2009-2013
  • Table 3.11.1-4 Apparent consumption of lambda-cyhalothrin in China, 2009-2013, tonne
  • Table 3.11.1-5 Consumption volume and market value of lambda-cyhalothrin in China, 2009-2013
  • Table 3.11.2-1 Valid registrations of acephate in China, as of Mar. 2014
  • Table 3.11.2-2 Basic information on main acephate technical producers in China
  • Table 3.11.2-3 Capacity and output of main acephate technical producers in China, 2008-2013
  • Table 3.11.2-4 Apparent consumption of acephate in China, 2008-2013, tonne
  • Table 3.11.2-5 Consumption volume and market value of acephate (by 30% EC) in China, 2008-2013
  • Table 3.11.3-1 Valid registrations of dimethoate in China, as of Mar. 2014
  • Table 3.11.3-2 Basic information on main dimethoate technical producers in China
  • Table 3.11.3-3 Capacity and output of main dimethoate technical producers in China, 2009-2013
  • Table 3.11.3-4 Apparent consumption of dimethoate in China, 2008-2013, tonne
  • Table 3.11.3-5 Consumption volume and market value of dimethoate in China, 2008-2013
  • Table 4.1-1 Classifications of herbicides
  • Table 4.2-1 Registrations of glyphosate by specifications in China, as of Mar. 2014
  • Table 4.2-2 Basic information of main active glyphosate technical producers in China
  • Table 4.2-3 Capacity and output of main glyphosate technical producers in China, 2009-2013
  • Table 4.2-4 Comparison of different pathways in glyphosate technical production
  • Table 4.2-5 Apparent consumption of glyphosate in China, 2009-2013, tonne
  • Table 4.2-6 Consumption volume and market value of glyphosate in China, 2009-2013
  • Table 4.3-1 Valid acetochlor registrations in China, as of Mar. 2014
  • Table 4.3-2 Basic information of main acetochlor technical producers in China
  • Table 4.3-3 Capacity and output of main acetochlor technical producers in China, 2009-2013
  • Table 4.3-4 Comparison on quality and yield coefficient of acetochlor between methylene route and ether route in China, 2012
  • Table 4.3-5 Apparent consumption of acetochlor in China, 2009-2013, tonne
  • Table 4.3-6 Consumption volume and market value of acetochlor in China, 2009-2013
  • Table 4.4-1 Valid registrations of paraquat in China, as of Mar. 2014
  • Table 4.4-2 Basic information of main paraquat technical producers in China
  • Table 4.4-3 Capacity and output of main paraquat technical producers in China, 2009-2013
  • Table 4.4-4 Current situation of paraquat technology in China, 2013
  • Table 4.4-5 Apparent consumption of paraquat in China, 2009-2013, tonne
  • Table 4.4-6 Consumption volume and market value of paraquat in China, 2009-2013
  • Table 4.5-1 Valid registrations of 2,4-D in China, as of Mar. 2014
  • Table 4.5-2 Difference in main raw materials' consumption between two methods for 2,4-D synthesis, 2013
  • Table 4.5-3 Consumption of energy between two methods for 2,4-D synthesis, 2013
  • Table 4.5-4 Basic information of main 2,4-D technical producers in China
  • Table 4.5-5 Capacity and output of main 2,4-D technical producers in China, 2009-2013
  • Table 4.5-6 Apparent consumption of 2,4-D in China, 2008-2013, tonne
  • Table 4.5-7 Consumption volume and market value of 2,4-D in China, 2008-2013
  • Table 4.6-1 Valid atrazine registrations in China, as of Mar. 2014
  • Table 4.6-2 Basic information of main active atrazine technical producers in China, 2013
  • Table 4.6-3 Capacity and output of active atrazine technical producers in China, 2009-2013
  • Table 4.6-4 Comparison of solvent route and water route for atrazine production
  • Table 4.6-5 Apparent consumption of atrazine in China, 2009-2013, tonne
  • Table 4.6-6 Consumption volume and market value of atrazine in China, 2009-2013
  • Table 4.7-1 Valid tribenuron-methyl registration in China, as of Mar. 2014
  • Table 4.7-2 Basic information of main tribenuron-methyl technical producers in China
  • Table 4.7-3 Capacity and output of tribenuron-methyl technical producers in China, 2010-2013
  • Table 4.7-4 Consumption of tribenuron-methyl in China, 2010-2013, tonne
  • Table 4.7-5 Consumption volume and market value of tribenuron-methyl in China, 2010-2013
  • Table 4.8-1 Valid bensulfuron-methyl registrations in China, as of Mar. 2014
  • Table 4.8-2 Basic information of main bensulfuron-methyl technical producers in China
  • Table 4.8-3 Capacity and output of main bensulfuron-methyl technical producers in China, 2010-2013
  • Table 4.8-4 Apparent consumption of bensulfuron-methyl in China, 2010-2013, tonne
  • Table 4.8-5 Consumption volume and market value of bensulfuron-methyl in China, 2010-2013
  • Table 4.9-1 Valid metolachlor registrations in China, as of Mar. 2014
  • Table 4.9-2 Basic information on main metolachlor technical producers in China
  • Table 4.9-3 Capacity and output of main metolachlor technical producers in China, 2009-2013
  • Table 4.9-4 Comparison on advantages and disadvantages of metolachlor technical production routes in China, 2012
  • Table 4.9-5 Apparent consumption of metolachlor in China, 2009-2013, tonne
  • Table 4.9-6 Market volume and value of metolachlor by formulation types in China, 2009-2013
  • Table 4.10-1 Valid registrations of pendimethalin in China, as of Mar. 2014
  • Table 4.10-2 Basic information of main pendimethalin technical producers in China
  • Table 4.10-3 Key Chinese producers of pendimethalin technical, 2009-2013
  • Table 4.10-4 Apparent consumption of pendimethalin in China, 2009-2013, tonne
  • Table 4.10-5 Consumption volume and market value of pendimethalin in China, 2009-2013
  • Table 4.11.1-1 Valid registrations of fenoxaprop-P-ethyl in China, as of Mar. 2014
  • Table 4.11.1-2 Basic information of main fenoxaprop-P-ethyl technical producers in China
  • Table 4.11.1-3 Capacity and output of main fenoxaprop-P-ethyl technical producers in China, 2009-2013
  • Table 4.11.1-4 Apparent consumption of fenoxaprop-P-ethyl in China, 2009-2013, tonne
  • Table 4.11.1-5 Consumption volume and market value of fenoxaprop-P-ethyl in China, 2009-2013
  • Table 4.11.2-1 Valid registration of quizalofop-P-ethyl in China, as of Mar. 2014
  • Table 4.11.2-2 Basic information of main quizalofop-P-ethyl technical producers in China
  • Table 4.11.2-3 Capacity and output of quizalofop-P-ethyl technical producers in China, 2009-2013
  • Table 4.11.2-4 Apparent consumption of quizalofop-P-ethyl in China, 2009-2013, tonne
  • Table 4.11.2-5 Consumption volume and market value of quizalofop-P-ethyl in China, 2009-2013
  • Table 4.11.3-1 Valid registration of dicamba in China, as of Mar. 2014
  • Table 4.11.3-2 Basic information of main dicamba technical producers in China
  • Table 4.11.3-3 Capacity and output of main dicamba technical producers in China, 2009-2013
  • Table 4.11.3-4 Apparent consumption of dicamba in China, 2008-2013, tonne
  • Table 4.11.3-5 Consumption volume and market value of dicamba in China, 2008-2013
  • Table 5.1-1 Classification and major products of fungicides in China
  • Table 5.2-1 Valid registrations of mancozeb in China, as of Mar. 2014
  • Table 5.2-2 Basic information on main mancozeb technical producers in China
  • Table 5.2-3 Capacity and output of main mancozeb technical producers in China, 2009-2013
  • Table 5.2-4 Apparent consumption of mancozeb in China, 2008-2013, tonne
  • Table 5.2-5 Consumption volume and market value of mancozeb in China, 2008-2013
  • Table 5.3-1 Valid registrations of carbendazim in China, as of Mar. 2014
  • Table 5.3-2 Basic information on main carbendazim technical producers in China
  • Table 5.3-3 Capacity and output of main carbendazim technical producers in China, 2009-2013
  • Table 5.3-4 Apparent consumption of carbendazim in China, 2009-2013, tonne
  • Table 5.3-5 Consumption volume and market value of carbendazim in China (by formulation), 2009-2013
  • Table 5.4-1 Valid registrations of tebuconazole in China, as of Mar. 2014
  • Table 5.4-2 Basic information on main tebuconazole technical producers in China
  • Table 5.4-3 Capacity and output of main tebuconazole technical producers in China, 2009-2013
  • Table 5.4-4 Apparent consumption of tebuconazole in China, 2008-2013, tonne
  • Table 5.4-5 Consumption volume and market value of tebuconazole in China, 2008-2013
  • Table 5.5-1 Valid registrations of thiophanate-methyl in China, as of Mar. 2014
  • Table 5.5-2 Basic information on main thiophanate-methyl technical producers in China
  • Table 5.5-3 Capacity and output of main thiophanate-methyl technical producers in China, 2009-2013
  • Table 5.5-4 Apparent consumption of thiophanate-methyl, 2008-2013, tonne
  • Table 5.5-5 Consumption volume and market value of thiophanate-methyl in China, 2008-2013
  • Table 5.6-1 Valid registrations of triadimefon in China, as of Mar. 2014
  • Table 5.6-2 Basic information on main triadimefon technical producers in China
  • Table 5.6-3 Capacity and output of main triadimefon technical producers in China, 2008-2013
  • Table 5.6-4 Apparent consumption of triadimefon in China, 2008-2013, tonne
  • Table 5.6-5 Consumption volume and market value of triadimefon in China, 2008-2013
  • Table 5.7-1 Valid registrations of difenoconazole in China, as of Mar. 2014
  • Table 5.7-2 Basic information on main difenoconazole technical producers in China
  • Table 5.7-3 Capacity and output of main difenoconazole technical producers in China, 2009-2013
  • Table 5.7-4 Apparent consumption of difenoconazole in China, 2008-2013, tonne
  • Table 5.7-5 Consumption volume and market value of difenoconazole in China, 2008-2013
  • Table 5.8-1 Valid registrations of tricyclazole in China, as of Mar. 2014
  • Table 5.8-2 Basic information on main tricyclazole technical producers in China
  • Table 5.8-3 Capacity and output of main tricyclazole technical producers in China, 2009-2013
  • Table 5.8-4 Apparent consumption of tricyclazole in China, 2008-2013, tonne
  • Table 5.8-5 Consumption volume and market value of tricyclazole in China, 2008-2013
  • Table 5.9-1 Valid registrations of isoprothiolane in China, as of Mar. 2014
  • Table 5.9-2 Basic information on main isoprothiolane technical producers in China
  • Table 5.9-3 Capacity and output of main isoprothiolane technical producers in China, 2009-2013
  • Table 5.9-4 Apparent consumption of isoprothiolane in China, 2009-2013, tonne
  • Table 5.9-5 Consumption volume and market value of isoprothiolane in China, 2009-2013
  • Table 5.10-1 Valid registrations of chlorothalonil in China, as of Mar. 2014
  • Table 5.10-2 Basic information on main chlorothalonil technical producers in China
  • Table 5.10-3 Capacity and output of main chlorothalonil technical producers in China, 2009-2013
  • Table 5.10-4 Apparent consumption of chlorothalonil in China, 2009-2013, tonne
  • Table 5.10-5 Consumption volume and market value of chlorothalonil in China, 2009-2013
  • Table 5.11.1-1 Valid registrations of prochloraz in China, as of Mar. 2014
  • Table 5.11.1-2 Basic information on main prochloraz technical producers in China
  • Table 5.11.1-3 Capacity and output of main prochloraz technical producers in China, 2009-2013
  • Table 5.11.1-4 Apparent consumption of prochloraz in China, 2008-2013, tonne
  • Table 5.11.1-5 Consumption volume and market value of prochloraz in China, 2008-2013
  • Table 5.11.2-1 Valid registrations of dimethomorph in China, as of Mar. 2014
  • Table 5.11.2-2 Basic information on main dimethomorph technical producers in China
  • Table 5.11.2-3 Capacity and output of main dimethomorph technical producers in China, 2009-2013
  • Table 5.11.2-4 Apparent consumption of dimethomorph in China, 2009-2013, tonne
  • Table 5.11.2-5 Consumption volume and market value of dimethomorphin China, 2009-2013
  • Table 5.11.3-1 Valid registrations of Azoxystrobin in China, as of Mar. 2014
  • Table 5.11.3-2 Basic information on azoxystrobin technical producers in China
  • Table 5.11.3-3 Capacity and output of major azoxystrobin technical producers in China, 2010-2013
  • Table 5.11.3-4 Comparison between two different production methods in China, 2013
  • Table 5.11.3-5 Apparent consumption of azoxystrobin technical in China, 2010-2013, tonne
  • Table 5.11.3-6 Consumption volume and value of azoxystrobin formulations in China, 2010-2013
  • Table 6.2-1 China's policies to boost farmers' income in recent years
  • Table 6.2-2 Comparison of labor supply and cost between China and the US in 2013
  • Table 7-1 SWOT analysis of Nanjing Redsun Co., Ltd., 2013
  • Table 7-2 SWOT analysis of Anhui Huaxing Chemical Industry Co., Ltd., 2013
  • Table 7-3 SWOT analysis of Jiangsu Yangnong Chemical Group Co., Ltd., 2013
  • Table 7-4 SWOT analysis of Zhejiang Wynca Chemical Industry Group Co., Ltd., 2013
  • Table 7-5 SWOT analysis of Shandong Binnong Technology Co., Ltd., 2013
  • Table 7-6 SWOT analysis of Nantong Jiangshan Agrochemical & Chemical Co., Ltd., 2013
  • Table 7-7 SWOT analysis of Shandong Weifang Rainbow Chemical Co., Ltd., 2013
  • Table 7-8 SWOT analysis of Jiangsu Changlong Chemical Co., Ltd., 2013
  • Table 7-9 SWOT analysis of Hubei Sanonda Co., Ltd., 2013
  • Table 7-10 SWOT analysis of Shandong Qiaochang Chemical Co., Ltd., 2013
  • Table 8.2-1 Some multinational pesticide producers in China
  • Table 9.1-1 Basic info of Nanjing Redsun, 2013
  • Table 9.1-2 Major pesticide technical of Nanjing Redsun, 2013
  • Table 9.1-3 Major pesticide products in Nanjing Redsun, 2011-2013
  • Table 9.2-1 Basic info of Zhejiang Wynca, 2013
  • Table 9.2-2 Major pesticide species of Zhejiang Wynca, 2013
  • Table 9.2-3 Major pesticide products in Zhejiang Wynca, 2011-2013
  • Table 9.3-1 Basic info of Jiangsu Yangnong, 2013
  • Table 9.3-2 Major pesticide species of Jiangsu Yangnong, 2013
  • Table 9.3-3 Major pesticide products in Jiangsu Yangnong, 2011-2013
  • Table 9.4-1 Basic info of Anhui Huaxing, 2013
  • Table 9.4-2 Major technical species of Anhui Huaxing, 2013
  • Table 9.4-3 Major formulation species of Anhui Huaxing, 2013
  • Table 9.4-4 Major pesticide products in Anhui Huaxing, 2011-2013
  • Table 9.5-1 Basic info of Shandong Rainbow, 2013
  • Table 9.5-2 Major herbicide species of Shandong Rainbow, 2013
  • Table 9.5-3 Major insecticide species of Shandong Rainbow, 2012
  • Table 9.5-4 Major fungicide species of Shandong Rainbow, 2013
  • Table 9.5-5 Major pesticide products in Shandong Rainbow, 2011-2013
  • Table 9.6-1 Basic info of Zhejiang Jinfanda, 2013
  • Table 9.6-2 Major products species of Zhejiang Jinfanda, 2013
  • Table 9.6-3 Major pesticide products in Zhejiang Jinfanda, 2011-2013
  • Table 9.7-1 Basic info of Hubei Sanonda, 2013
  • Table 9.7-2 Major pesticide species of Hubei Sanonda, 2013
  • Table 9.7-3 Major pesticide products in Hubei Sanonda, 2011-2013
  • Table 9.8-1 Basic info of Nantong Jiangshan, 2013
  • Table 9.8-2 Major pesticide's species of Nantong Jiangshan, 2013
  • Table 9.8-3 Major pesticide products in Nantong Jiangshan, 2011-2013
  • Table 9.9-1 Basic info of Shandong Binnong, 2013
  • Table 9.9-2 Major pesticide's species of Shandong Binnong, 2013
  • Table 9.9-3 Major pesticide products in Shandong Binnong, 2011-2013
  • Table 9.10-1 Basic info of Jiangsu Changlong, 2013
  • Table 9.10-2 Major products species of Jiangsu Changlong, 2013
  • Table 9.10-3 Major pesticide products in Jiangsu Changlong, 2011-2013
  • Table 9.11-1 Basic info of Jiangsu Fengshan, 2013
  • Table 9.11-2 Major insecticide species of Jiangsu Fengshan, 2013
  • Table 9.11-3 Major pesticide products in Jiangsu Fengshan, 2011-2013
  • Table 9.12-1 Basic info of Jiangsu Kwin, 2013
  • Table 9.12-2 Major pesticide species of Jiangsu Kwin, 2013
  • Table 9.12-3 Major pesticide products in Jiangsu Kwin, 2011-2013
  • Table 9.13-1 Basic info of Shandong Qiaochang, 2013
  • Table 9.13-2 Major pesticide's species of Shandong Qiaochang, 2013
  • Table 9.13-3 Major pesticide products in Shandong Qiaochang, 2011-2013
  • Table 9.14-1 Basic info of Jiangsu Changqing, 2013
  • Table 9.14-2 Major pesticide's species of Jiangsu Changqing, 2013
  • Table 9.14-3 Major Species of pesticide formulation in Jiangsu Changqing, 2013
  • Table 9.14-4 Major pesticide products in Jiangsu Changqing, 2011-2013
  • Table 9.15-1 Basic info of Jiangsu Huifeng, 2013
  • Table 9.15-2 Product species of Jiangsu Huifeng, 2013
  • Table 9.15-3 Major pesticide products in Jiangsu Huifeng, 2011-2013
  • Table 9.16-1 Basic info of Hebei Veyong, 2013
  • Table 9.16-2 Product species of Hebei Veyong, 2012
  • Table 9.16-3 Major pesticide products in Hebei Veyong, 2011-2013
  • Table 9.17-1 Basic info of Hunan Haili, 2013
  • Table 9.17-2 Major pesticide products in Hunan Haili, 2011-2013
  • Table 9.18-1 Basic info of Good Harvest-Weien, 2013
  • Table 9.18-2 Situation of major products in Jiangsu Good Harvest-Weien Agrochemical Co., Ltd., 2011
  • Table 9.18-3 Major pesticide products in Jiangsu Good Harvest-Weien, 2011-2013
  • Table 9.19-1 Basic info of Zhongshan Chemical, 2013
  • Table 9.19-2 Major pesticide products in Zhongshan Chemical, 2011-2013
  • Table 9.20-1 Basic info of Lier Chemical, 2013
  • Table 9.20-2 Major pesticide products in Lier Chemical, 2011-2013
  • Table 9.21-1 Basic info of Anhui Guangxin, 2013
  • Table 9.21-2 Product species of Anhui Guangxin, 2013
  • Table 9.21-3 Major pesticide products in Anhui Guangxin, 2011-2013
  • Table 9.22-1 Basic info of Jiangsu Lanfeng, 2013
  • Table 9.22-2 Product species of Jiangsu Lanfeng, 2013
  • Table 9.22-3 Major pesticide products in Jiangsu Lanfeng, 2011-2013
  • Table 9.23-1 Basic info of Limin Chemical, 2013
  • Table 9.23-2 Product species of Limin Chemical, 2013
  • Table 9.23-3 Major pesticide products in Limin Chemical, 2011-2013
  • Table 9.24-1 Basic info of Jiangsu Sevencontinent, 2013
  • Table 9.24-2 Product species of Jiangsu Sevencontinent, 2013
  • Table 9.24-3 Major pesticide products in Sevencontinent Green, 2011-2013

List of figures:

  • Figure 1.4.1-1 Pesticide technical structure by output, 2003-2013
  • Figure 1.4.1-2 Valid registrations of pesticide formulations (number and share) by types in China, as of Mar. 2014
  • Figure 1.4.1-3 Output share of pesticide technical in major regions of China, 2013
  • Figure 2.3-1 Per capita disposable income of urban residents in China, 2000-2013
  • Figure 2.3-2 Per capita net income of rural residents in China, 2000-2013
  • Figure 2.4.1-1 Annual cultivation area of crops in China, 2000-2012
  • Figure 2.4.1-2 Planting structure of crops in China, 2012
  • Figure 2.4.2-1 GM crop planting area in China, 2000-2013
  • Figure 2.4.4-1 Structure of grain loss caused by plant diseases, insect pests and weeds, 2013
  • Figure 3.1-1 Output and share of insecticides in China's pesticide industry, 2000-2013
  • Figure 3.1-2 Geographical distribution of insecticides production in China by volume, 2013
  • Figure 3.1-3 Demand structure of insecticides by volume in China, 2013
  • Figure 3.2-1 Registration number of chlorpyrifos in China, 1987-July 2013
  • Figure 3.2-2 Capacity and output of chlorpyrifos technical in China, 2006-2013
  • Figure 3.2-3 Chemical principle of chlorpyrifos synthesis in China
  • Figure 3.2-4 STCP synthesis by trichloroacetyl chloride route
  • Figure 3.2-5 STCP synthesis by pyridine route
  • Figure 3.2-6 General production process of chlorpyrifos technical by trichloroacetyl chloride route
  • Figure 3.2-7 Manufacturing process of TCP from pyridine
  • Figure 3.2-8 Ex-work price of chlorpyrifos 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 3.2-9 Ex-work price of chlorpyrifos 480g/L EC in China, Jan. 2008-Feb. 2014
  • Figure 3.2-10 Consumption structure of chlorpyrifos by crops in China, 2013
  • Figure 3.2-11 Forecast on output of chlorpyrifos technical in China, 2014-2018
  • Figure 3.2-12 Forecast on consumption (97% TC) and market value of chlorpyrifos in China, 2014-2018
  • Figure 3.3-1 Process route of abamectin technical
  • Figure 3.3-2 Capacity and output of abamectin technical in China, 2009-2013
  • Figure 3.3-3 Ex-work price of abamectin 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 3.3-4 Ex-work price of abamectin 18g/L EC in China, Jan. 2008-Feb. 2013
  • Figure 3.3-5 Consumption structure of abamectin in China, 2013
  • Figure 3.3-6 Forecast on output of abamectin technical in China, 2014-2018
  • Figure 3.3-7 Forecast on consumption (by 95% TC) and market value of abamectin in China, 2014-2018
  • Figure 3.4-1 Capacity and output of imidacloprid technical in China, 2009-2013
  • Figure 3.4-2 CCMP synthesis by DCPD route
  • Figure 3.4-3 Process flow chart of imidacloprid technical by DCPD route
  • Figure 3.4-4 Average ex-work price of imidacloprid 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 3.4-5 Consumption structure of imidacloprid by crops in China, 2013
  • Figure 3.4-6 Forecast on output of imidacloprid (97% TC) in China, 2014-2018
  • Figure 3.4-7 Forecast on consumption (97% TC) and market value of imidacloprid in China, 2014-2018
  • Figure 3.5-1 Capacity and output of phoxim technical in China, 2008-2013
  • Figure 3.5-2 Ex-work price of phoxim 90% technical in China, Jan. 2008-Feb. 2014
  • Figure 3.5-3 Consumption structure of phoxim by crops in China, 2013
  • Figure 3.5-4 Forecast on output of phoxim technical in China, 2014-2018
  • Figure 3.5-5 Forecast on consumption (by 90% TC) and market value of phoxim in China, 2014-2018
  • Figure 3.6-1 Capacity and output of triazophos technical in China, 2009-2013
  • Figure 3.6-2 First reaction process of triazophos production
  • Figure 3.6-3 Second reaction process of triazophos production
  • Figure 3.6-4 Third reaction process of triazophos production
  • Figure 3.6-5 Ex-work price of triazophos 85% technical in China, Jan. 2009-Feb. 2014
  • Figure 3.6-6 Consumption structure of triazophos by crops in China, 2013
  • Figure 3.6-7 Forecast on output of triazophos technical in China, 2014-2018
  • Figure 3.6-8 Forecast on consumption (by 85% TC) and market value of triazophos in China, 2014-2018
  • Figure 3.7-1 Capacity and output of bifenthrin technical in China, 2009-2013
  • Figure 3.7-2 Ex-work price of bifenthrin 97% technical in China, Jan. 2009-Feb. 2014
  • Figure 3.7-3 Consumption structure of bifenthrin by crops in China, 2013
  • Figure 3.7-4 Forecast on output of bifenthrin technical in China, 2014-2018
  • Figure 3.7-5 Forecast on consumption (by 95% TC) and market value of bifenthrin in China, 2014-2018
  • Figure 3.8-1 Capacity and output of carbofuran technical in China, 2008-2013
  • Figure 3.8-2 Average ex-work price of carbofuran 98% technical in China, 2008-2013
  • Figure 3.8-3 Consumption structure of carbofuran by crops in China, 2013
  • Figure 3.8-4 Forecast on output of carbofuran technical in China, 2014-2018
  • Figure 3.8-5 Forecast on consumption (by 98% TC) and market value of carbofuran in China, 2014-2018
  • Figure 3.9-1 Capacity and output of dichlorvos technical in China, 2009-2013
  • Figure 3.9-2 New method of dichlorvos production developed by E.Beriger
  • Figure 3.9-3 Dichlorvos synthesis by dipterex route
  • Figure 3.9-4 Dichlorvos synthesis by trimethyl phosphite route
  • Figure 3.9-5 Average ex-work price of dichlorvos 95% technical in China, 2008-2013
  • Figure 3.9-6 Consumption structure of dichlorvos by crops in China, 2013
  • Figure 3.9-7 Forecast on output of dichlorvos (95% technical) in China, 2014-2018
  • Figure 3.9-8 Forecast on consumption (by 95% TC) and market value of dichlorvos in China, 2014-2018
  • Figure 3.10-1 Capacity and output of trichlorfon technical in China, 2009-2013
  • Figure 3.10-2 Ex-work price of trichlorfon 90% technical in China, 2006-2013
  • Figure 3.10-3 Consumption structure of trichlorfon in China, 2013
  • Figure 3.10-4 Forecast on output of trichlorfon technical in China, 2014-2018
  • Figure 3.10-5 Forecast on consumption (by 90% TC) and market value of trichlorfon in China, 2014-2018
  • Figure 3.11.1-1 Registration structure of lambda-cyhalothrin by formulations types in China, as of Mar. 2014
  • Figure 3.11.1-2 Capacity and output of lambda-cyhalothrin technical in China, 2009-2013
  • Figure 3.11.1-3 Ex-work price of lambda-cyhalothrin 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 3.11.1-4 Ex-work price of lambda-cyhalothrin 25g/L EC in China, Jan. 2008-Aug. 2013
  • Figure 3.11.1-5 Consumption structure of lambda-cyhalothrin in China, 2013
  • Figure 3.11.1-6 Forecast on output of lambda-cyhalothrin technical in China, 2014-2018
  • Figure 3.11.1-7 Forecast on consumption (by 95% TC) and market value of lambda-cyhalothrin in China, 2014-2018
  • Figure 3.11.2-1 Capacity and output of acephate technical in China, 2008-2013
  • Figure 3.11.2-2 Isomerization chemical reaction in acephate production
  • Figure 3.11.2-3 Chemical equation of making acephate, adopting acetic anhydride as acidylating agent
  • Figure 3.11.2-4 Chemical equation of making acephate, adopting acetyl chloride acylation as acidylating agents
  • Figure 3.11.2-5 Chemical equation of making acephate, adopting acetic acid and phosphorus trichloride as acidylating agents
  • Figure 3.11.2-6 Process flow of acephate production
  • Figure 3.11.2-7 Average ex-work price of acephate 97% technical in China, 2006-2013
  • Figure 3.11.2-8 Consumption structure of acephate by crops in China, 2013
  • Figure 3.11.2-9 Forecast on output of acephate technical (by 97% TC) in China, 2014-2018
  • Figure 3.11.2-10 Forecast on consumption (by 97% TC) and market value of acephate in China, 2014-2018
  • Figure 3.11.3-1 Capacity and output of dimethoate technical in China, 2008-2013
  • Figure 3.11.3-2 Average ex-work price of dimethoate 98% technical in China, 2007-2013
  • Figure 3.11.3-3 Consumption structure of dimethoate by crops in China, 2013
  • Figure 3.11.3-4 Forecast on output of dimethoate technical in China, 2014-2018
  • Figure 3.11.3-5 Forecast on consumption (by 98% TC) and market value of dimethoate in China, 2014-2018
  • Figure 4.1-1 Output and share of herbicides in China's pesticide industry, 2000-2013
  • Figure 4.1-2 Output structure of main herbicide products, 2013
  • Figure 4.1-3 Output structure of main herbicide products in China, 2008
  • Figure 4.1-4 Geographical distribution of herbicides production in China by volume, 2013
  • Figure 4.1-5 Market value share of herbicides by category in China, 2013
  • Figure 4.1-6 Consumption structure of major herbicides in China by volume, 2013
  • Figure 4.2-1 Capacity and output of glyphosate technical in China, 2009-2013
  • Figure 4.2-2 Various production pathways of glyphosate technical in China
  • Figure 4.2-3 Ex-work price of glyphosate 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.2-4 Ex-work price of glyphosate 41% IPA in China, Jan. 2008-Feb. 2014
  • Figure 4.2-5 Consumption structure of glyphosate by crops in China, 2013
  • Figure 4.2-6 Forecast on output of glyphosate technical in China, 2014-2018
  • Figure 4.2-7 Forecast on consumption (95% TC) and market value of glyphosate in China, 2014-2018
  • Figure 4.3-1 Capacity and output of acetochlor technical in China, 2009-2013
  • Figure 4.3-2 Methylene route of acetochlor technical in China, 2012
  • Figure 4.3-3 Ether route of acetochlor technical in China, 2012
  • Figure 4.3-4 Average ex-work price of acetochlor 92% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.3-5 Average ex-work price of acetochlor 900g/L EC in China, 2007-2013
  • Figure 4.3-6 Average ex-work price of acetochlor 900g/L EC in China, Jan. 2011-Dec. 2012
  • Figure 4.3-7 Consumption structure of acetochlor by crops in China, 2013
  • Figure 4.3-8 Forecast on output of acetochlor technical in China, 2014-2018
  • Figure 4.3-9 Forecast on consumption (92% TC) and market value of acetochlor in China, 2014-2018
  • Figure 4.4-1 Capacity and output of paraquat technical in China, 2009-2013
  • Figure 4.4-2 Chemical principle of MC process for paraquat production
  • Figure 4.4-3 Flowchart of AC process for paraquat production
  • Figure 4.4-4 Ex-work price of paraquat 42% TK in China, Jan. 2008-Feb. 2014
  • Figure 4.4-5 Ex-work price of paraquat 200g/L AS in China, Jan. 2008-Feb. 2014
  • Figure 4.4-6 Consumption structure of paraquat by crops in China, 2013
  • Figure 4.4-7 Forecast on output of paraquat by 42% TK in China, 2014-2018
  • Figure 4.4-8 Forecast on consumption (42% TK) and market value of paraquat in China, 2014-2018
  • Figure 4.5-1 Flowchart of the first method for 2,4-D (chlorination first and then condensation)
  • Figure 4.5-2 Flowchart of the second method for 2,4-D (condensation first and then chlorination)
  • Figure 4.5-3 Capacity and output of 2,4-D technical in China, 2008-2013
  • Figure 4.5-4 Ex-work price of 2,4-D technical (96%) in China, 2007-2013
  • Figure 4.5-5 Ex-work price of 2,4-D technical (96%) in China, Jan. 2011-Feb. 2014
  • Figure 4.5-6 Ex-work price of 2,4-D amine salt 720g/L SL in China, 2007-2013
  • Figure 4.5-7 Ex-work price of 2,4-D amine salt 720g/L SL in China, Jan. 2011-Feb. 2014
  • Figure 4.5-8 Ex-work price of 2,4-D butylate 57% EC in China, 2007-2012
  • Figure 4.5-9 Consumption structure of 2,4-D by crops in China, 2013
  • Figure 4.5-10 Forecast on output of 2,4-D technical in China, 2014-2018
  • Figure 4.5-11 Forecast on consumption (96% TC) and market value of 2,4-D in China, 2014-2018
  • Figure 4.6-1 Capacity and output of atrazine technical in China, 2008-2013
  • Figure 4.6-2 Flowchart of solvent route in atrazine technical production
  • Figure 4.6-3 Ex-work price of atrazine 97% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.6-4 Consumption structure of atrazine by crops in China, 2013
  • Figure 4.6-5 Forecast on output of atrazine (97% TC) in China, 2014-2018
  • Figure 4.6-6 Forecast on consumption (by 97% TC) and market value of atrazine in China, 2014-2018
  • Figure 4.7-1 Capacity and output of tribenuron-methyl technical in China, 2010-2013
  • Figure 4.7-2 Ex-work price of tribenuron-methyl 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.7-3 Ex-work price of tribenuron-methyl 75% WDG in China, Jan. 2011-Jan. 2013
  • Figure 4.7-4 Consumption structure of tribenuron-methyl by crops in China, 2013
  • Figure 4.7-5 Forecast on output of tribenuron-methyl (95% TC) in China, 2014-2018
  • Figure 4.7-6 Forecast on consumption (95% TC) and market value of tribenuron-methyl in China, 2014-2018
  • Figure 4.8-1 Capacity and output of bensulfuron-methyl technical in China, 2010-2013
  • Figure 4.8-2 Ex-work price of bensulfuron-methyl 95% technical in China, Jan. 2009-Feb. 2014
  • Figure 4.8-3 Ex-work price of bensulfuron-methyl 60% WDG in China, Jan. 2011-Jan. 2013
  • Figure 4.8-4 Consumption structure of bensulfuron-methyl by crops in China, 2013
  • Figure 4.8-5 Forecast on output of bensulfuron-methyl (95% technical) in China, 2014-2018
  • Figure 4.8-6 Forecast on consumption (95% TC) and market value of bensulfuron-methyl in China, 2014-2018
  • Figure 4.9-1 Capacity and output of metolachlor technical in China, 2009-2013
  • Figure 4.9-2 Methoxyacetone route of metolachlor technical, 2012
  • Figure 4.9-3 2-Chlorine propanol route of metolachlor technical, 2012
  • Figure 4.9-4 2-Bromo-1-methoxyl propane route of metolachlor technical, 2012
  • Figure 4.9-5 Average ex-work prices of metolachlor 97% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.9-6 Average ex-work prices of metolachlor 720g/L EC in China, Jan. 2008-Feb. 2014
  • Figure 4.9-7 Consumption structure of metolachlor by crops in China, 2013
  • Figure 4.9-8 Forecast on output of metolachlor technical in China, 2014-2018
  • Figure 4.9-9 Forecast on consumption (by 97% TC) and market value of metolachlor in China, 2014-2018
  • Figure 4.10-1 Capacity and output of pendimethalin technical in China, 2009-2013
  • Figure 4.10-2 Ex-work price of pendimethalin 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.10-3 Consumption structure of pendimethalin by crops in China, 2013
  • Figure 4.10-4 Forecast on output of pendimethalin technical in China, 2014-2018
  • Figure 4.10-5 Forecast on consumption (by 95% TC) and market value of pendimethalin in China, 2014-2018
  • Figure 4.11.1-1 Capacity and output of fenoxaprop-P-ethyl technical in China, 2009-2013
  • Figure 4.11.1-2 Ex-work price of fenoxaprop-P-ethyl 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.11.1-3 Consumption structure of fenoxaprop-P-ethyl by crops in China, 2013
  • Figure 4.11.1-4 Forecast on output of fenoxaprop-P-ethyl technical (by 95% technical) in China, 2014-2018
  • Figure 4.11.1-5 Forecast on consumption (95% TC) and market value of fenoxaprop-P-ethyl in China, 2014-2018
  • Figure 4.11.2-1 Capacity and output of quizalofop-P-ethyl technical in China, 2009-2013
  • Figure 4.11.2-2 Ex-work price of quizalofop-P-ethyl 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.11.2-3 Ex-work price of quizalofop-P-ethyl 5% EC in China, Jan. 2009-May 2013
  • Figure 4.11.2-4 Consumption structure of quizalofop-P-ethyl by crops in China, 2013
  • Figure 4.11.2-5 Forecast on output of quizalofop-P-ethyl technical in China, 2014-2018
  • Figure 4.11.2-6 Forecast on consumption (by 95% TC) and market value of quizalofop-P-ethyl in China, 2014-2018
  • Figure 4.11.3-1 Capacity and output of dicamba technical in China, 2008-2013
  • Figure 4.11.3-2 Ex-work price of dicamba 98% technical in China, Jan. 2008-Feb. 2014
  • Figure 4.11.3-3 Ex-work price of dicamba 48% AS in China, Jan. 2008-Feb. 2014
  • Figure 4.11.3-4 Consumption structure of dicamba by crops in China, 2013
  • Figure 4.11.3-5 Forecast on output of dicamba (98% TC) in China, 2014-2018
  • Figure 4.11.3-6 Forecast on consumption (98% TC) and market value of dicamba in China, 2014-2018
  • Figure 5.1-1 Output and share of fungicides in China's pesticide industry, 2000-2013
  • Figure 5.1-2 Geographical distribution of fungicides production in China by volume, 2013
  • Figure 5.1-3 Market share of fungicides by category and consumption volume in China, 2013
  • Figure 5.2-1 Capacity and output of mancozeb technical in China, 2008-2013
  • Figure 5.2-2 Flowchart of mancozeb synthesis
  • Figure 5.2-3 Chemical principle of mancozeb synthesis in China
  • Figure 5.2-4 Average ex-work price of mancozeb 90% technical in China, Jan. 2009-Feb. 2014
  • Figure 5.2-5 Consumption structure of mancozeb by crops in China, 2013
  • Figure 5.2-6 Forecast on output of mancozeb technical in China, 2014-2018
  • Figure 5.2-7 Forecast on consumption (by 85% TC) and market value of mancozeb in China, 2014-2018
  • Figure 5.3-1 Capacity and output of carbendazim technical in China, 2009-2013
  • Figure 5.3-2 Main reaction in carbendazim manufacture
  • Figure 5.3-3 Flow chart of carbendazim manufacture
  • Figure 5.3-4 Ex-work price of carbendazim 98% technical in China, Jan. 2009-Feb. 2014
  • Figure 5.3-5 Ex-work price of carbendazim 500g/L SC in China, Jan. 2009-Feb. 2013
  • Figure 5.3-6 Consumption structure of carbendazim by crops in China, 2013
  • Figure 5.3-7 Forecast on output of carbendazim (by 98% technical) in China, 2014-2018
  • Figure 5.3-8 Forecast on consumption (by 98% technical) and market value of carbendazim in China, 2014-2018
  • Figure 5.4-1 Capacity and output of tebuconazole technical in China, 2008-2013
  • Figure 5.4-2 Production route of tebuconazole technical
  • Figure 5.4-3 Flow chart of tebuconazole technical production
  • Figure 5.4-4 Ex-work price of tebuconazole 97% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.4-5 Ex-work price of tebuconazole 25% EC in China, Jan. 2008-Dec. 2012
  • Figure 5.4-6 Consumption structure of tebuconazole by crops in China, 2013
  • Figure 5.4-7 Forecast on output of tebuconazole 97% technical in China, 2014-2018
  • Figure 5.4-8 Forecast on consumption (by 97% TC) and market value of tebuconazole in China, 2014-2018
  • Figure 5.5-1 Capacity and output of thiophanate-methyl technical in China, 2008-2013
  • Figure 5.5-2 Main chemical reaction equation in the production of thiophanate-methyl
  • Figure 5.5-3 Basic chemical reaction equation of sulfur cyanide in the production of thiophanate-methyl
  • Figure 5.5-4 Ex-work price of thiophanate-methyl 96% technical in China, Jan. 2009-Feb. 2014
  • Figure 5.5-5 Ex-work price of thiophanate-methyl 70% WP in China, Aug. 2009-Dec. 2012
  • Figure 5.5-6 Consumption structure of thiophanate-methyl by crops in China, 2013
  • Figure 5.5-7 Forecast on output of thiophanate-methyl technical in China, 2014-2018
  • Figure 5.5-8 Forecast on consumption (by 95% TC) and market value of thiophanate-methyl in China, 2014-2018
  • Figure 5.6-1 Capacity and output of triadimefon technical in China, 2008-2013
  • Figure 5.6-2 Production route of triadimefon technical
  • Figure 5.6-3 Flow chart of triadimefon technical production
  • Figure 5.6-4 Ex-work price of triadimefon 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.6-5 Ex-work price of triadimefon 15% WP in China, Jan. 2009-Feb. 2013
  • Figure 5.6-6 Consumption structure of triadimefon by crops in China, 2013
  • Figure 5.6-7 Forecast on output of triadimefon technical in China, 2014-2018
  • Figure 5.6-8 Forecast on consumption (by 95% TC) and market value of triadimefon in China, 2014-2018
  • Figure 5.7-1 Capacity and output of difenoconazole technical in China, 2008-2013
  • Figure 5.7-2 Production route of difenoconazole technical
  • Figure 5.7-3 Flow chart of difenoconazole technical production
  • Figure 5.7-4 Ex-work price of difenoconazole 95% technical in China, Aug. 2008-Feb. 2014
  • Figure 5.7-5 Ex-work price of difenoconazole 250g/L EC in China, Jan. 2008-Dec. 2012
  • Figure 5.7-6 Consumption structure of difenoconazole by crops in China, 2013
  • Figure 5.7-7 Forecast on output of difenoconazole technical in China, 2014-2018
  • Figure 5.7-8 Forecast on consumption (by 95% TC) and market value of difenoconazole in China, 2014-2018
  • Figure 5.8-1 Capacity and output of tricyclazole technical in China, 2008-2013
  • Figure 5.8-2 Ex-work price of tricyclazole 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.8-3 Forecast on output of tricyclazole technical in China, 2014-2018
  • Figure 5.8-4 Forecast on consumption (by 95% TC) and market value of tricyclazole in China, 2014-2018
  • Figure 5.9-1 Capacity and output of isoprothiolane technical in China, 2009-2013
  • Figure 5.9-2 Ex-work price of isoprothiolane 97% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.9-3 Ex-work price of isoprothiolane 40% EC in China, Jan. 2011-Feb. 2013
  • Figure 5.9-4 Consumption structure of isoprothiolane by crops in China, 2013
  • Figure 5.9-5 Forecast on output of isoprothiolane technical in China, 2014-2018
  • Figure 5.9-6 Forecast on consumption (by 97% TC) and market value of isoprothiolane in China, 2014-2018
  • Figure 5.10-1 Capacity and output of chlorothalonil technical in China, 2008-2013
  • Figure 5.10-2 Flow chart of chlorothalonil production
  • Figure 5.10-3 Catalytic chemical reaction in chlorothalonil production
  • Figure 5.10-4 Replacement chemical reaction in chlorothalonil production
  • Figure 5.10-5 Ex-work price of chlorothalonil 98% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.10-6 Ex-work price of chlorothalonil 75% WP in China, Jan. 2009-Feb. 2013
  • Figure 5.10-7 Consumption structure of chlorothalonil by crops in China, 2013
  • Figure 5.10-8 Forecast on output of chlorothalonil technical in China, 2014-2018
  • Figure 5.10-9 Forecast on consumption (by 98% TC) and market value of chlorothalonil in China, 2014-2018
  • Figure 5.11.1-1 Capacity and output of prochloraz technical in China, 2008-2013
  • Figure 5.11.1-2 Main chemical reaction in prochloraz production
  • Figure 5.11.1-3 Flow chart of prochloraz production process
  • Figure 5.11.1-4 Ex-work price of prochloraz 97% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.11.1-5 Ex-work price of prochloraz 25% EC in China, Jan. 2011-Dec. 2012
  • Figure 5.11.1-6 Consumption structure of prochloraz by crops in China, 2013
  • Figure 5.11.1-7 Forecast on output of prochloraz technical in China, 2014-2018
  • Figure 5.11.1-8 Forecast on consumption (by 97% TC) and market value of prochloraz in China, 2014-2018
  • Figure 5.11.2-1 Capacity and output of dimethomorph technical in China, 2009-2013
  • Figure 5.11.2-2 Ex-work price of dimethomorph 95% technical in China, Jan. 2008-Feb. 2014
  • Figure 5.11.2-3 Ex-work price of dimethomorph 50% WP in China, Jan. 2009-Dec. 2012
  • Figure 5.11.2-4 Consumption structure of dimethomorph by crops in China, 2013
  • Figure 5.11.2-5 Forecast on output of dimethomorph technical in China, 2014-2018
  • Figure 5.11.2-6 Forecast on consumption (by 95% TC) and market value of dimethomorph in China, 2014-2018
  • Figure 5.11.3-1 Production situation of azoxystrobin technical in China, 2010-2013
  • Figure 5.11.3-2 A Production route of intermediate of azoxystrobin technical in China
  • Figure 5.11.3-3 B Production route of intermediate of azoxystrobin technical in China
  • Figure 5.11.3-4 C Production route of intermediate in azoxystrobin technical in China
  • Figure 5.11.3-5 Process route of azoxystrobin technical production in China
  • Figure 5.11.3-6 Ex-work price of azoxystrobin 95% technical in China, Jan. 2011-Feb. 2014
  • Figure 5.11.3-7 Ex-work price of azoxystrobin 250g/L SC in China, Jan. 2011-Feb. 2013
  • Figure 5.11.3-8 Consumption structure of azoxystrobin by crop in China, 2013
  • Figure 5.11.3-9 Forecast on output of azoxystrobin by 95% technical in China, 2014-2018
  • Figure 5.11.3-10 Forecast on consumption (95% technical) and market value of azoxystrobin in China, 2014-2018
  • Figure 6.2-1 Per capita annual net income of rural households in China, 2000-2013
  • Figure 6.2-2 Engel's Coefficient in China, 2001-2013
  • Figure 6.2-3 Population structure in China, 2001-2013
  • Figure 6.2-4 Government's investiment on agriculture in China, 2004-2013
  • Figure 6.3-1 Forecast on domestic demand for pesticides by category (by 100% TC), 2014-2018
  • Figure 8.2-1 Investment suggestions on new pesticide production line in pesticide industrial parks, 2014-2020
  • Figure 9.1-1 Ownership structure of Nanjing Redsun, 2013
  • Figure 9.2-1 Ownership structure of Zhejiang Wynca, 2013
  • Figure 9.3-1 Ownership structure of Jiangsu Yangnong, 2013
  • Figure 9.4-1 Ownership structure of Anhui Huaxing, 2013
  • Figure 9.5-1 Ownership structure of Shandong Weifang Rainbow Chemical Co., Ltd., 2013
  • Figure 9.6-1 Ownership structure of Zhejiang Jinfanda, 2013
  • Figure 9.7-1 Ownership structure of Hubei Sanonda, 2013
  • Figure 9.8-1 Ownership structure of Nantong Jiangshan, 2013
  • Figure 9.9-1 Ownership structure of Shandong Binnong, 2013
  • Figure 9.10-1 Ownership structure of Jiangsu Changlong, 2013
  • Figure 9.11-1 Ownership structure of Jiangsu Fengshan, 2013
  • Figure 9.12-1 Ownership structure of Jiangsu Kwin, 2013
  • Figure 9.13-1 Ownership structure of Shandong Qiaochang, 2013
  • Figure 9.14-1 Ownership structure of Jiangsu Changqing, 2013
  • Figure 9.15-1 Ownership structure of Jiangsu Huifeng, 2013
  • Figure 9.16-1 Ownership structure of Hebei Veyong, 2012
  • Figure 9.17-1 Ownership structure of Hunan Haili, 2013
  • Figure 9.20-1 Ownership structure of Lier Chemical, 2013
  • Figure 9.21-1 Ownership structure of Anhui Guangxin, 2013
  • Figure 9.22-1 Ownership structure of Jiangsu Lanfeng, 2013
  • Figure 9.24-1 Ownership structure of Sevencontinent Green, 2013
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