Nematicide Market Size
Study Period | 2017 - 2029 | |
Market Size (2024) | USD 2.94 Billion | |
Market Size (2029) | USD 3.54 Billion | |
Largest Share by Application Mode | Soil Treatment | |
CAGR (2024 - 2029) | 3.73 % | |
Largest Share by Region | South America | |
Major Players |
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*Disclaimer: Major Players sorted in no particular order |
Nematicide Market Analysis
The Nematicide Market size is estimated at 2.94 billion USD in 2024, and is expected to reach 3.54 billion USD by 2029, growing at a CAGR of 3.73% during the forecast period (2024-2029).
2.94 Billion
Market Size in 2024 (USD)
3.54 Billion
Market Size in 2029 (USD)
1.34 %
CAGR (2017-2023)
3.73 %
CAGR (2024-2029)
Largest Segment by Application Mode
70.35 %
value share, Soil Treatment, 2023
Soil treatment enables nematicides to be directly applied to the soil, where they can remain longer, allowing the chemical to reach the root systems.
Largest Segment by Crop Type
45.57 %
value share, Grains & Cereals, 2023
Grains and cereals crops occupy higher cultivation areas and are produced in greater quantities to fulfill the food needs of the growing population worldwide.
Largest Segment By Region
36.43 %
value share, South America, 2023
Various nematodes are causing major damage, including root-knot nematodes, root lesion nematodes, burrowing nematodes, and reniform nematodes.
Fastest-growing Segment by Country
5.23 %
Projected CAGR, Mexico, 2024-2029
Export-oriented farmers recognized the importance of managing nematodes effectively to meet the stringent standards of foreign markets, which drives the nematicides' usage.
Leading Market Player
24.12 %
market share, Syngenta Group, 2022
The company invests more than USD 1.3 billion annually in the research and development of innovative agrochemical products to address farmers' crop protection challenges.
Increasing early crop growth damage by soil-borne nematodes raises the soil treatment application mode of nematicides
- The growth of nematodes in agriculture is favored by changing climates like drought, heat waves, and warm and humid conditions. Monoculture practices, no-tillage, and sandy soils also favor their growth. Based on the types of nematodes, regions, and crops, farmers implement various nematicide application modes for better nematode management and enhancing crop production.
- Nematicide application via soil treatment held a majority market share of 70.3% in 2022, which was majorly attributed to the effectiveness of this method in reducing soil-borne nematode populations and improving crop productivity. These can be applied prior to planting and after planting by soil drenching, which helps in faster crop germination. The soil treatment mode of nematicide application is expected to increase by around 17.3 thousand metric ton during 2023-2029.
- The foliar method of nematicide application was the next most used application mode and fastest-growing segment, which is anticipated to register a CAGR of 3.4% during the forecast period. The foliar nematicide application effectively manages the foliar nematodes that feed on the foliage of the plant and reduces the yield of food crops. Advancements in foliar mode, like drone applications and other technical and digital improvements, raise the foliar mode of application.
- Effective management of water and nematicide quantity can be achieved through the chemigation mode, which occupied the market share of 8.5% in 2022. Advanced irrigation systems and increased water scarcity will raise the chemigation adoption rate, increasing the nematicide application.
- All the application modes aim to reduce nematode infestations and increase crop productivity, which is expected to drive the market.
Increased nematode infestations and the growing adoption of nematicides stood South America in prominent position
- Apart from climate changes and other pests and diseases, nematodes cause significant damage to the agriculture sector worldwide. More than 4100 plant parasitic nematodes were identified, causing damage to various crops across the world.
- According to the American Society of Phytopathology, nematodes cause around 14% of the global crop loss annually, which is equal to an economic loss of almost USD 125 billion. Among various nematode species root-knot nematodes (Meloidogyne spp.), cyst nematodes (Heterodera spp., Globodera spp.), root-lesion nematodes (Pratylenchus spp., Hirschmanniella spp., and Radopholus spp.), stem nematodes (Ditylenchus spp.), and pine wood nematodes (Bursaphlenchus spp.) majorly damage the crop growth and productivity by effecting the water and nutrients absorption.
- The consumption of nematicides in its cultivation is majorly dominated by South America, which represented 37.4% of the global nematicide market in 2022. This is majorly attributed to the crop losses by nematodes, which are recorded at around USD 6.5 billion every year. Soybean is the major crop grown, and South America produces more than 50% of the soybeans produced in the world. Nematodes cause around 30% of yield loss worth USD 3 billion in the region. During the historical period, the consumption of nematicides increased by around 7.6 thousand metric ton between 2017 and 2022, which is further expected to increase by more than 10.1 thousand metric ton between 2023-2029. This emphasized the nematicide's necessity in the South American agriculture industry.
- The global nematicide market is anticipated to grow during the forecast period (2023-2029) with an estimated CAGR of 3.7%, which will be driven by the growing adoption of nematicides for crop protection from various nematodes globally.
Global Nematicide Market Trends
Intensive agricultural practices have increased the need for nematicide application
- The average global consumption of chemical nematicides was 2.1 kg per hectare of agricultural land in 2022. Asia-Pacific was the largest consumer of nematicides, with a per-hectare consumption of 737.02 grams in 2022. Asian countries, including Japan, commonly adopt intensive farming practices like greenhouse cultivation and monocropping. Although these methods enhance productivity, they also heighten crop vulnerability to soil-borne pests like nematodes. Consequently, farmers frequently resort to nematicides to protect their crops.
- Europe was the second largest per-hectare consumer of nematicides, with 591.7 grams per hectare in 2022. European countries are expanding the cultivation of high-value crops, including vegetables, fruits, and ornamentals, which tend to be more susceptible to nematode damage. The plant-parasitic nematodes cause an annual yield loss of 21.3%, amounting to USD 1.58 billion in European countries. As a result, the use of nematicides becomes necessary to effectively manage and control these infestations in Europe.
- South America was the third largest per-hectare consumer of nematicides, with 570.14 grams per hectare in 2022. Root-knot nematodes attack the roots and tubers of various plants, including tomatoes, potatoes, and carrots in the region. Carrots are susceptible to considerable losses, averaging up to 20.0%, while potatoes can experience even higher losses of up to 33.0% due to infestations caused by these nematode species. The nematode population in North American countries is increasing with the increasing adoption of no-tillage practices, which reduce soil disturbance and increase the retention of crop residue. These circumstances are leading to the application of nematicides globally.
Changing climatic conditions and their effect on nematode infestations may raise the demand for nematicides and their prices simultaneously
- Nematicides play a crucial role in agriculture by effectively controlling plant-parasitic nematodes, protecting crops from root damage, and ensuring optimal yield and productivity.
- Flufensulfone is a nematicide belonging to the chemical class of arylsulfonates. It is used to control plant-parasitic nematodes, such as root-knot nematodes, cyst nematodes, lesion nematodes, and dagger nematodes in various agricultural crops. The mode of action of flufensulfone involves interfering with the nervous systems of nematodes, leading to paralysis and death. By targeting nematodes, flufensulfone helps reduce their populations and minimize the damage they can cause to crops. Flufensulfone was priced at USD 19.0 thousand metric ton in 2022.
- Abamectin is known for its nematocidal activity against several plant-parasitic nematodes, including the root lesion nematode (Pratylenchus penetrans), the reniform nematode (Rotylenchus reniformis), the root-knot nematode (Meloidogyne incognita), and the cyst nematodes (Heterodera schachtii). Its efficacy in controlling these nematodes makes it a valuable tool for nematode management in agricultural crops. As of 2022, the market value of abamectin was approximately USD 12.2 thousand per metric ton.
- Oxamyl is a widely used insecticide and nematicide belonging to the chemical class of carbamates. It is primarily used to control a variety of plant-parasitic nematodes in agricultural crops. Oxamyl's mode of action as an insecticide and nematicide involves inhibiting the activity of acetylcholinesterase, an enzyme essential for nerve function in insects and nematodes. By disrupting this enzyme, oxamyl causes nerve overstimulation, leading to paralysis and eventual death of the pests. It was priced at USD 8.8 thousand per metric ton in 2022.
Nematicide Industry Overview
The Nematicide Market is fairly consolidated, with the top five companies occupying 82.88%. The major players in this market are ADAMA Agricultural Solutions Ltd., Bayer AG, Corteva Agriscience, Syngenta Group and Upl Limited (sorted alphabetically).
Nematicide Market Leaders
ADAMA Agricultural Solutions Ltd.
Bayer AG
Corteva Agriscience
Syngenta Group
Upl Limited
Other important companies include Albaugh LLC, American Vanguard Corporation, Tessenderlo Kerley Inc. (Novasource), Vive Crop Protection.
*Disclaimer: Major Players sorted in alphabetical order.
Nematicide Market News
- January 2023: Bayer formed a new partnership with Oerth Bio to enhance crop protection technology and create more eco-friendly crop protection solutions.
- June 2022: AgriNova New Zealand Ltd was acquired by ADAMA Ltd. With this acquisition, ADAMA expanded its product line in the New Zealand market.
- May 2022: Corteva Agriscience in Brazil expanded its portfolio, services, and industrial infrastructure to commercial partners to strengthen its activities in the seed treatment industry. For instance, the company strengthened its operations in the area of seed treatment with the new global brands LumiGEN and Ampl.
Free with this Report
Along with the report, We also offer a comprehensive and exhaustive data pack with 50+ graphs on insecticide, fungicides, and herbicides consumption per hectare and the average price of active ingredients used in insecticides, fungicides, herbicides, nematicides, and molluscicides. The data pack includes Globe, North America, Europe, Asia-Pacific, South America, and Africa.
Nematicide Market Report - Table of Contents
1. EXECUTIVE SUMMARY & KEY FINDINGS
2. REPORT OFFERS
3. INTRODUCTION
- 3.1 Study Assumptions & Market Definition
- 3.2 Scope of the Study
- 3.3 Research Methodology
4. KEY INDUSTRY TRENDS
- 4.1 Consumption Of Pesticide Per Hectare
- 4.2 Pricing Analysis For Active Ingredients
-
4.3 Regulatory Framework
- 4.3.1 Australia
- 4.3.2 Canada
- 4.3.3 China
- 4.3.4 France
- 4.3.5 Germany
- 4.3.6 India
- 4.3.7 Indonesia
- 4.3.8 Italy
- 4.3.9 Japan
- 4.3.10 Mexico
- 4.3.11 Myanmar
- 4.3.12 Netherlands
- 4.3.13 Pakistan
- 4.3.14 Philippines
- 4.3.15 Russia
- 4.3.16 South Africa
- 4.3.17 Spain
- 4.3.18 Thailand
- 4.3.19 Ukraine
- 4.3.20 United Kingdom
- 4.3.21 United States
- 4.3.22 Vietnam
- 4.4 Value Chain & Distribution Channel Analysis
5. MARKET SEGMENTATION (includes market size in Value in USD and Volume, Forecasts up to 2029 and analysis of growth prospects)
-
5.1 Application Mode
- 5.1.1 Chemigation
- 5.1.2 Foliar
- 5.1.3 Fumigation
- 5.1.4 Seed Treatment
- 5.1.5 Soil Treatment
-
5.2 Crop Type
- 5.2.1 Commercial Crops
- 5.2.2 Fruits & Vegetables
- 5.2.3 Grains & Cereals
- 5.2.4 Pulses & Oilseeds
- 5.2.5 Turf & Ornamental
-
5.3 Region
- 5.3.1 Africa
- 5.3.1.1 By Country
- 5.3.1.1.1 South Africa
- 5.3.1.1.2 Rest of Africa
- 5.3.2 Asia-Pacific
- 5.3.2.1 By Country
- 5.3.2.1.1 Australia
- 5.3.2.1.2 China
- 5.3.2.1.3 India
- 5.3.2.1.4 Indonesia
- 5.3.2.1.5 Japan
- 5.3.2.1.6 Myanmar
- 5.3.2.1.7 Pakistan
- 5.3.2.1.8 Philippines
- 5.3.2.1.9 Thailand
- 5.3.2.1.10 Vietnam
- 5.3.2.1.11 Rest of Asia-Pacific
- 5.3.3 Europe
- 5.3.3.1 By Country
- 5.3.3.1.1 France
- 5.3.3.1.2 Germany
- 5.3.3.1.3 Italy
- 5.3.3.1.4 Netherlands
- 5.3.3.1.5 Russia
- 5.3.3.1.6 Spain
- 5.3.3.1.7 Ukraine
- 5.3.3.1.8 United Kingdom
- 5.3.3.1.9 Rest of Europe
- 5.3.4 North America
- 5.3.4.1 By Country
- 5.3.4.1.1 Canada
- 5.3.4.1.2 Mexico
- 5.3.4.1.3 United States
- 5.3.4.1.4 Rest of North America
- 5.3.5 South America
- 5.3.5.1 By Country
- 5.3.5.1.1 Argentina
- 5.3.5.1.2 Brazil
- 5.3.5.1.3 Chile
- 5.3.5.1.4 Rest of South America
6. COMPETITIVE LANDSCAPE
- 6.1 Key Strategic Moves
- 6.2 Market Share Analysis
- 6.3 Company Landscape
-
6.4 Company Profiles (includes Global level Overview, Market level overview, Core Business Segments, Financials, Headcount, Key Information, Market Rank, Market Share, Products and Services, and analysis of Recent Developments)
- 6.4.1 ADAMA Agricultural Solutions Ltd.
- 6.4.2 Albaugh LLC
- 6.4.3 American Vanguard Corporation
- 6.4.4 Bayer AG
- 6.4.5 Corteva Agriscience
- 6.4.6 Syngenta Group
- 6.4.7 Tessenderlo Kerley Inc. (Novasource)
- 6.4.8 Upl Limited
- 6.4.9 Vive Crop Protection
7. KEY STRATEGIC QUESTIONS FOR CROP PROTECTION CHEMICALS CEOS
8. APPENDIX
-
8.1 Global Overview
- 8.1.1 Overview
- 8.1.2 Porter’s Five Forces Framework
- 8.1.3 Global Value Chain Analysis
- 8.1.4 Market Dynamics (DROs)
- 8.2 Sources & References
- 8.3 List of Tables & Figures
- 8.4 Primary Insights
- 8.5 Data Pack
- 8.6 Glossary of Terms
List of Tables & Figures
- Figure 1:
- NEMATICIDE CONSUMPTION PER HECTARE, GRAMS, GLOBAL, 2017 - 2022
- Figure 2:
- ACTIVE INGREDIENT PRICE PER METRIC TON, USD, GLOBAL, 2017 - 2022
- Figure 3:
- NEMATICIDE VOLUME METRIC TON, GLOBAL, 2017 - 2029
- Figure 4:
- NEMATICIDE VALUE USD, GLOBAL, 2017 - 2029
- Figure 5:
- NEMATICIDE MARKET BY APPLICATION MODE, METRIC TON, GLOBAL, 2017 - 2029
- Figure 6:
- NEMATICIDE MARKET BY APPLICATION MODE, USD, GLOBAL, 2017 - 2029
- Figure 7:
- VALUE SHARE OF NEMATICIDE BY APPLICATION MODE, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 8:
- VOLUME SHARE OF NEMATICIDE BY APPLICATION MODE, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 9:
- CROP PROTECTION CHEMICALS APPLIED THROUGH CHEMIGATION, METRIC TON, GLOBAL, 2017 - 2029
- Figure 10:
- CROP PROTECTION CHEMICALS APPLIED THROUGH CHEMIGATION, USD, GLOBAL, 2017 - 2029
- Figure 11:
- VALUE SHARE OF CHEMIGATION BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 12:
- CROP PROTECTION CHEMICALS APPLIED THROUGH FOLIAR, METRIC TON, GLOBAL, 2017 - 2029
- Figure 13:
- CROP PROTECTION CHEMICALS APPLIED THROUGH FOLIAR, USD, GLOBAL, 2017 - 2029
- Figure 14:
- VALUE SHARE OF FOLIAR BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 15:
- CROP PROTECTION CHEMICALS APPLIED THROUGH FUMIGATION, METRIC TON, GLOBAL, 2017 - 2029
- Figure 16:
- CROP PROTECTION CHEMICALS APPLIED THROUGH FUMIGATION, USD, GLOBAL, 2017 - 2029
- Figure 17:
- VALUE SHARE OF FUMIGATION BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 18:
- CROP PROTECTION CHEMICALS APPLIED THROUGH SEED TREATMENT, METRIC TON, GLOBAL, 2017 - 2029
- Figure 19:
- CROP PROTECTION CHEMICALS APPLIED THROUGH SEED TREATMENT, USD, GLOBAL, 2017 - 2029
- Figure 20:
- VALUE SHARE OF SEED TREATMENT BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 21:
- CROP PROTECTION CHEMICALS APPLIED THROUGH SOIL TREATMENT, METRIC TON, GLOBAL, 2017 - 2029
- Figure 22:
- CROP PROTECTION CHEMICALS APPLIED THROUGH SOIL TREATMENT, USD, GLOBAL, 2017 - 2029
- Figure 23:
- VALUE SHARE OF SOIL TREATMENT BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 24:
- NEMATICIDE MARKET BY CROP TYPE, METRIC TON, GLOBAL, 2017 - 2029
- Figure 25:
- NEMATICIDE MARKET BY CROP TYPE, USD, GLOBAL, 2017 - 2029
- Figure 26:
- VALUE SHARE OF NEMATICIDE BY CROP TYPE, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 27:
- VOLUME SHARE OF NEMATICIDE BY CROP TYPE, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 28:
- NEMATICIDE CONSUMED BY COMMERCIAL CROPS, METRIC TON, GLOBAL, 2017 - 2029
- Figure 29:
- NEMATICIDE CONSUMED BY COMMERCIAL CROPS, USD, GLOBAL, 2017 - 2029
- Figure 30:
- VALUE SHARE OF COMMERCIAL CROPS BY APPLICATION MODE, %, GLOBAL, 2022 VS 2029
- Figure 31:
- NEMATICIDE CONSUMED BY FRUITS & VEGETABLES, METRIC TON, GLOBAL, 2017 - 2029
- Figure 32:
- NEMATICIDE CONSUMED BY FRUITS & VEGETABLES, USD, GLOBAL, 2017 - 2029
- Figure 33:
- VALUE SHARE OF FRUITS & VEGETABLES BY APPLICATION MODE, %, GLOBAL, 2022 VS 2029
- Figure 34:
- NEMATICIDE CONSUMED BY GRAINS & CEREALS, METRIC TON, GLOBAL, 2017 - 2029
- Figure 35:
- NEMATICIDE CONSUMED BY GRAINS & CEREALS, USD, GLOBAL, 2017 - 2029
- Figure 36:
- VALUE SHARE OF GRAINS & CEREALS BY APPLICATION MODE, %, GLOBAL, 2022 VS 2029
- Figure 37:
- NEMATICIDE CONSUMED BY PULSES & OILSEEDS, METRIC TON, GLOBAL, 2017 - 2029
- Figure 38:
- NEMATICIDE CONSUMED BY PULSES & OILSEEDS, USD, GLOBAL, 2017 - 2029
- Figure 39:
- VALUE SHARE OF PULSES & OILSEEDS BY APPLICATION MODE, %, GLOBAL, 2022 VS 2029
- Figure 40:
- NEMATICIDE CONSUMED BY TURF & ORNAMENTAL, METRIC TON, GLOBAL, 2017 - 2029
- Figure 41:
- NEMATICIDE CONSUMED BY TURF & ORNAMENTAL, USD, GLOBAL, 2017 - 2029
- Figure 42:
- VALUE SHARE OF TURF & ORNAMENTAL BY APPLICATION MODE, %, GLOBAL, 2022 VS 2029
- Figure 43:
- NEMATICIDE MARKET BY REGION, METRIC TON, GLOBAL, 2017 - 2029
- Figure 44:
- NEMATICIDE MARKET BY REGION, USD, GLOBAL, 2017 - 2029
- Figure 45:
- VALUE SHARE OF NEMATICIDE BY REGION, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 46:
- VOLUME SHARE OF NEMATICIDE BY REGION, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 47:
- NEMATICIDE MARKET BY COUNTRY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 48:
- NEMATICIDE MARKET BY COUNTRY, USD, GLOBAL, 2017 - 2029
- Figure 49:
- VALUE SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 50:
- VOLUME SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 51:
- NEMATICIDE CONSUMED BY SOUTH AFRICA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 52:
- NEMATICIDE CONSUMED BY SOUTH AFRICA, USD, GLOBAL, 2017 - 2029
- Figure 53:
- VALUE SHARE OF SOUTH AFRICA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 54:
- NEMATICIDE CONSUMED BY REST OF AFRICA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 55:
- NEMATICIDE CONSUMED BY REST OF AFRICA, USD, GLOBAL, 2017 - 2029
- Figure 56:
- VALUE SHARE OF REST OF AFRICA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 57:
- NEMATICIDE MARKET BY COUNTRY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 58:
- NEMATICIDE MARKET BY COUNTRY, USD, GLOBAL, 2017 - 2029
- Figure 59:
- VALUE SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 60:
- VOLUME SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 61:
- NEMATICIDE CONSUMED BY AUSTRALIA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 62:
- NEMATICIDE CONSUMED BY AUSTRALIA, USD, GLOBAL, 2017 - 2029
- Figure 63:
- VALUE SHARE OF AUSTRALIA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 64:
- NEMATICIDE CONSUMED BY CHINA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 65:
- NEMATICIDE CONSUMED BY CHINA, USD, GLOBAL, 2017 - 2029
- Figure 66:
- VALUE SHARE OF CHINA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 67:
- NEMATICIDE CONSUMED BY INDIA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 68:
- NEMATICIDE CONSUMED BY INDIA, USD, GLOBAL, 2017 - 2029
- Figure 69:
- VALUE SHARE OF INDIA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 70:
- NEMATICIDE CONSUMED BY INDONESIA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 71:
- NEMATICIDE CONSUMED BY INDONESIA, USD, GLOBAL, 2017 - 2029
- Figure 72:
- VALUE SHARE OF INDONESIA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 73:
- NEMATICIDE CONSUMED BY JAPAN, METRIC TON, GLOBAL, 2017 - 2029
- Figure 74:
- NEMATICIDE CONSUMED BY JAPAN, USD, GLOBAL, 2017 - 2029
- Figure 75:
- VALUE SHARE OF JAPAN BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 76:
- NEMATICIDE CONSUMED BY MYANMAR, METRIC TON, GLOBAL, 2017 - 2029
- Figure 77:
- NEMATICIDE CONSUMED BY MYANMAR, USD, GLOBAL, 2017 - 2029
- Figure 78:
- VALUE SHARE OF MYANMAR BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 79:
- NEMATICIDE CONSUMED BY PAKISTAN, METRIC TON, GLOBAL, 2017 - 2029
- Figure 80:
- NEMATICIDE CONSUMED BY PAKISTAN, USD, GLOBAL, 2017 - 2029
- Figure 81:
- VALUE SHARE OF PAKISTAN BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 82:
- NEMATICIDE CONSUMED BY PHILIPPINES, METRIC TON, GLOBAL, 2017 - 2029
- Figure 83:
- NEMATICIDE CONSUMED BY PHILIPPINES, USD, GLOBAL, 2017 - 2029
- Figure 84:
- VALUE SHARE OF PHILIPPINES BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 85:
- NEMATICIDE CONSUMED BY THAILAND, METRIC TON, GLOBAL, 2017 - 2029
- Figure 86:
- NEMATICIDE CONSUMED BY THAILAND, USD, GLOBAL, 2017 - 2029
- Figure 87:
- VALUE SHARE OF THAILAND BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 88:
- NEMATICIDE CONSUMED BY VIETNAM, METRIC TON, GLOBAL, 2017 - 2029
- Figure 89:
- NEMATICIDE CONSUMED BY VIETNAM, USD, GLOBAL, 2017 - 2029
- Figure 90:
- VALUE SHARE OF VIETNAM BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 91:
- NEMATICIDE CONSUMED BY REST OF ASIA-PACIFIC, METRIC TON, GLOBAL, 2017 - 2029
- Figure 92:
- NEMATICIDE CONSUMED BY REST OF ASIA-PACIFIC, USD, GLOBAL, 2017 - 2029
- Figure 93:
- VALUE SHARE OF REST OF ASIA-PACIFIC BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 94:
- NEMATICIDE MARKET BY COUNTRY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 95:
- NEMATICIDE MARKET BY COUNTRY, USD, GLOBAL, 2017 - 2029
- Figure 96:
- VALUE SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 97:
- VOLUME SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 98:
- NEMATICIDE CONSUMED BY FRANCE, METRIC TON, GLOBAL, 2017 - 2029
- Figure 99:
- NEMATICIDE CONSUMED BY FRANCE, USD, GLOBAL, 2017 - 2029
- Figure 100:
- VALUE SHARE OF FRANCE BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 101:
- NEMATICIDE CONSUMED BY GERMANY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 102:
- NEMATICIDE CONSUMED BY GERMANY, USD, GLOBAL, 2017 - 2029
- Figure 103:
- VALUE SHARE OF GERMANY BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 104:
- NEMATICIDE CONSUMED BY ITALY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 105:
- NEMATICIDE CONSUMED BY ITALY, USD, GLOBAL, 2017 - 2029
- Figure 106:
- VALUE SHARE OF ITALY BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 107:
- NEMATICIDE CONSUMED BY NETHERLANDS, METRIC TON, GLOBAL, 2017 - 2029
- Figure 108:
- NEMATICIDE CONSUMED BY NETHERLANDS, USD, GLOBAL, 2017 - 2029
- Figure 109:
- VALUE SHARE OF NETHERLANDS BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 110:
- NEMATICIDE CONSUMED BY RUSSIA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 111:
- NEMATICIDE CONSUMED BY RUSSIA, USD, GLOBAL, 2017 - 2029
- Figure 112:
- VALUE SHARE OF RUSSIA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 113:
- NEMATICIDE CONSUMED BY SPAIN, METRIC TON, GLOBAL, 2017 - 2029
- Figure 114:
- NEMATICIDE CONSUMED BY SPAIN, USD, GLOBAL, 2017 - 2029
- Figure 115:
- VALUE SHARE OF SPAIN BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 116:
- NEMATICIDE CONSUMED BY UKRAINE, METRIC TON, GLOBAL, 2017 - 2029
- Figure 117:
- NEMATICIDE CONSUMED BY UKRAINE, USD, GLOBAL, 2017 - 2029
- Figure 118:
- VALUE SHARE OF UKRAINE BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 119:
- NEMATICIDE CONSUMED BY UNITED KINGDOM, METRIC TON, GLOBAL, 2017 - 2029
- Figure 120:
- NEMATICIDE CONSUMED BY UNITED KINGDOM, USD, GLOBAL, 2017 - 2029
- Figure 121:
- VALUE SHARE OF UNITED KINGDOM BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 122:
- NEMATICIDE CONSUMED BY REST OF EUROPE, METRIC TON, GLOBAL, 2017 - 2029
- Figure 123:
- NEMATICIDE CONSUMED BY REST OF EUROPE, USD, GLOBAL, 2017 - 2029
- Figure 124:
- VALUE SHARE OF REST OF EUROPE BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 125:
- NEMATICIDE MARKET BY COUNTRY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 126:
- NEMATICIDE MARKET BY COUNTRY, USD, GLOBAL, 2017 - 2029
- Figure 127:
- VALUE SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 128:
- VOLUME SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 129:
- NEMATICIDE CONSUMED BY CANADA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 130:
- NEMATICIDE CONSUMED BY CANADA, USD, GLOBAL, 2017 - 2029
- Figure 131:
- VALUE SHARE OF CANADA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 132:
- NEMATICIDE CONSUMED BY MEXICO, METRIC TON, GLOBAL, 2017 - 2029
- Figure 133:
- NEMATICIDE CONSUMED BY MEXICO, USD, GLOBAL, 2017 - 2029
- Figure 134:
- VALUE SHARE OF MEXICO BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 135:
- NEMATICIDE CONSUMED BY UNITED STATES, METRIC TON, GLOBAL, 2017 - 2029
- Figure 136:
- NEMATICIDE CONSUMED BY UNITED STATES, USD, GLOBAL, 2017 - 2029
- Figure 137:
- VALUE SHARE OF UNITED STATES BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 138:
- NEMATICIDE CONSUMED BY REST OF NORTH AMERICA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 139:
- NEMATICIDE CONSUMED BY REST OF NORTH AMERICA, USD, GLOBAL, 2017 - 2029
- Figure 140:
- VALUE SHARE OF REST OF NORTH AMERICA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 141:
- NEMATICIDE MARKET BY COUNTRY, METRIC TON, GLOBAL, 2017 - 2029
- Figure 142:
- NEMATICIDE MARKET BY COUNTRY, USD, GLOBAL, 2017 - 2029
- Figure 143:
- VALUE SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 144:
- VOLUME SHARE OF NEMATICIDE BY COUNTRY, %, GLOBAL, 2017 VS 2023 VS 2029
- Figure 145:
- NEMATICIDE CONSUMED BY ARGENTINA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 146:
- NEMATICIDE CONSUMED BY ARGENTINA, USD, GLOBAL, 2017 - 2029
- Figure 147:
- VALUE SHARE OF ARGENTINA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 148:
- NEMATICIDE CONSUMED BY BRAZIL, METRIC TON, GLOBAL, 2017 - 2029
- Figure 149:
- NEMATICIDE CONSUMED BY BRAZIL, USD, GLOBAL, 2017 - 2029
- Figure 150:
- VALUE SHARE OF BRAZIL BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 151:
- NEMATICIDE CONSUMED BY CHILE, METRIC TON, GLOBAL, 2017 - 2029
- Figure 152:
- NEMATICIDE CONSUMED BY CHILE, USD, GLOBAL, 2017 - 2029
- Figure 153:
- VALUE SHARE OF CHILE BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 154:
- NEMATICIDE CONSUMED BY REST OF SOUTH AMERICA, METRIC TON, GLOBAL, 2017 - 2029
- Figure 155:
- NEMATICIDE CONSUMED BY REST OF SOUTH AMERICA, USD, GLOBAL, 2017 - 2029
- Figure 156:
- VALUE SHARE OF REST OF SOUTH AMERICA BY CROP TYPE, %, GLOBAL, 2022 VS 2029
- Figure 157:
- MOST ACTIVE COMPANIES BY NUMBER OF STRATEGIC MOVES, GLOBAL, 2017-2022
- Figure 158:
- MOST ACTIVE COMPANIES BY NUMBER OF STRATEGIC MOVES, GLOBAL, 2017-2022
- Figure 159:
- MARKET SHARE OF MAJOR PLAYERS, %, GLOBAL 2023
Nematicide Industry Segmentation
Chemigation, Foliar, Fumigation, Seed Treatment, Soil Treatment are covered as segments by Application Mode. Commercial Crops, Fruits & Vegetables, Grains & Cereals, Pulses & Oilseeds, Turf & Ornamental are covered as segments by Crop Type. Africa, Asia-Pacific, Europe, North America, South America are covered as segments by Region.
- The growth of nematodes in agriculture is favored by changing climates like drought, heat waves, and warm and humid conditions. Monoculture practices, no-tillage, and sandy soils also favor their growth. Based on the types of nematodes, regions, and crops, farmers implement various nematicide application modes for better nematode management and enhancing crop production.
- Nematicide application via soil treatment held a majority market share of 70.3% in 2022, which was majorly attributed to the effectiveness of this method in reducing soil-borne nematode populations and improving crop productivity. These can be applied prior to planting and after planting by soil drenching, which helps in faster crop germination. The soil treatment mode of nematicide application is expected to increase by around 17.3 thousand metric ton during 2023-2029.
- The foliar method of nematicide application was the next most used application mode and fastest-growing segment, which is anticipated to register a CAGR of 3.4% during the forecast period. The foliar nematicide application effectively manages the foliar nematodes that feed on the foliage of the plant and reduces the yield of food crops. Advancements in foliar mode, like drone applications and other technical and digital improvements, raise the foliar mode of application.
- Effective management of water and nematicide quantity can be achieved through the chemigation mode, which occupied the market share of 8.5% in 2022. Advanced irrigation systems and increased water scarcity will raise the chemigation adoption rate, increasing the nematicide application.
- All the application modes aim to reduce nematode infestations and increase crop productivity, which is expected to drive the market.
Application Mode | Chemigation | ||
Foliar | |||
Fumigation | |||
Seed Treatment | |||
Soil Treatment | |||
Crop Type | Commercial Crops | ||
Fruits & Vegetables | |||
Grains & Cereals | |||
Pulses & Oilseeds | |||
Turf & Ornamental | |||
Region | Africa | By Country | South Africa |
Rest of Africa | |||
Region | Asia-Pacific | By Country | Australia |
China | |||
India | |||
Indonesia | |||
Japan | |||
Myanmar | |||
Pakistan | |||
Philippines | |||
Thailand | |||
Vietnam | |||
Rest of Asia-Pacific | |||
Region | Europe | By Country | France |
Germany | |||
Italy | |||
Netherlands | |||
Russia | |||
Spain | |||
Ukraine | |||
United Kingdom | |||
Rest of Europe | |||
Region | North America | By Country | Canada |
Mexico | |||
United States | |||
Rest of North America | |||
Region | South America | By Country | Argentina |
Brazil | |||
Chile | |||
Rest of South America |
Market Definition
- Function - Nematicides are chemicals used to control or prevent nematodes from damaging the crop and prevent yield loss.
- Application Mode - Foliar, Seed Treatment, Soil Treatment, Chemigation, and Fumigation are the different type of application modes through which crop protection chemicals are applied to the crops.
- Crop Type - This represents the consumption of crop protection chemicals by Cereals, Pulses, Oilseeds, Fruits, Vegetables, Turf, and Ornamental crops.
Keyword | Definition |
---|---|
IWM | Integrated weed management (IWM) is an approach to incorporate multiple weed control techniques throughout the growing season to give producers the best opportunity to control problematic weeds. |
Host | Hosts are the plants that form relationships with beneficial microorganisms and help them colonize. |
Pathogen | A disease-causing organism. |
Herbigation | Herbigation is an effective method of applying herbicides through irrigation systems. |
Maximum residue levels (MRL) | Maximum Residue Limit (MRL) is the maximum allowed limit of pesticide residue in food or feed obtained from plants and animals. |
IoT | The Internet of Things (IoT) is a network of interconnected devices that connect and exchange data with other IoT devices and the cloud. |
Herbicide-tolerant varieties (HTVs) | Herbicide-tolerant varieties are plant species that have been genetically engineered to be resistant to herbicides used on crops. |
Chemigation | Chemigation is a method of applying pesticides to crops through an irrigation system. |
Crop Protection | Crop protection is a method of protecting crop yields from different pests, including insects, weeds, plant diseases, and others that cause damage to agricultural crops. |
Seed Treatment | Seed treatment helps to disinfect seeds or seedlings from seed-borne or soil-borne pests. Crop protection chemicals, such as fungicides, insecticides, or nematicides, are commonly used for seed treatment. |
Fumigation | Fumigation is the application of crop protection chemicals in gaseous form to control pests. |
Bait | A bait is a food or other material used to lure a pest and kill it through various methods, including poisoning. |
Contact Fungicide | Contact pesticides prevent crop contamination and combat fungal pathogens. They act on pests (fungi) only when they come in contact with the pests. |
Systemic Fungicide | A systemic fungicide is a compound taken up by a plant and then translocated within the plant, thus protecting the plant from attack by pathogens. |
Mass Drug Administration (MDA) | Mass drug administration is the strategy to control or eliminate many neglected tropical diseases. |
Mollusks | Mollusks are pests that feed on crops, causing crop damage and yield loss. Mollusks include octopi, squid, snails, and slugs. |
Pre-emergence Herbicide | Preemergence herbicides are a form of chemical weed control that prevents germinated weed seedlings from becoming established. |
Post-emergence Herbicide | Postemergence herbicides are applied to the agricultural field to control weeds after emergence (germination) of seeds or seedlings. |
Active Ingredients | Active ingredients are the chemicals in pesticide products that kill, control, or repel pests. |
United States Department of Agriculture (USDA) | The Department of Agriculture provides leadership on food, agriculture, natural resources, and related issues. |
Weed Science Society of America (WSSA) | The WSSA, a non-profit professional society, promotes research, education, and extension outreach activities related to weeds. |
Suspension concentrate | Suspension concentrate (SC) is one of the formulations of crop protection chemicals with solid active ingredients dispersed in water. |
Wettable powder | A wettable powder (WP) is a powder formulation that forms a suspension when mixed with water prior to spraying. |
Emulsifiable concentrate | Emulsifiable concentrate (EC) is a concentrated liquid formulation of pesticide that needs to be diluted with water to create a spray solution. |
Plant-parasitic nematodes | Parasitic Nematodes feed on the roots of crops, causing damage to the roots. These damages allow for easy plant infestation by soil-borne pathogens, which results in crop or yield loss. |
Australian Weeds Strategy (AWS) | The Australian Weeds Strategy, owned by the Environment and Invasives Committee, provides national guidance on weed management. |
Weed Science Society of Japan (WSSJ) | WSSJ aims to contribute to the prevention of weed damage and the utilization of weed value by providing the chance for research presentation and information exchange. |
Research Methodology
Mordor Intelligence follows a four-step methodology in all our reports.
- Step-1: Identify Key Variables: In order to build a robust forecasting methodology, the variables and factors identified in Step-1 are tested against available historical market numbers. Through an iterative process, the variables required for market forecast are set and the model is built on the basis of these variables.
- Step-2: Build a Market Model: Market-size estimations for the forecast years are in nominal terms. Inflation is not a part of the pricing, and the average selling price (ASP) is kept constant throughout the forecast period.
- Step-3: Validate and Finalize: In this important step, all market numbers, variables and analyst calls are validated through an extensive network of primary research experts from the market studied. The respondents are selected across levels and functions to generate a holistic picture of the market studied.
- Step-4: Research Outputs: Syndicated Reports, Custom Consulting Assignments, Databases & Subscription Platforms