1. Characteristics of Pesticides Basic concepts relating to the names, chemistry, behavior and fate of Pesticides including a review of the R8 Label Book summary pages

2. Pesticide Names Chemical name * Common name * Product name * There are three names associated with every pesticide Skip definitions

3. Pesticide Names: Chemical Name The systematic Name of a Chemical Compound according to the rules of nomenclature of the International Union of Pure and Applied Chemistry as adapted for indexing in Chemical Abstracts For example: 3,5,6-trichloro-2- pyridinyloxyacetic acid.. is a chemical name Return

4. Pesticide Names: Common Name A generic name for a chemical compound (see the Weed Science Society of America list of herbicide nomenclature) For example: The common name for 3,5,6- trichloro-2-pyridinoxyacetic acid.. is triclopyr The common name is the name generally used in discussing pesticidal toxicology and environmental behavior and fate Return

5. Pesticide Names: Product Name The trade name of a pesticide; that is the name on the container you purchase. It is also the name to which the EPA registration number is applied at the time of registration Triclopyr alone is sold as: Garlon 3A or Garlon 4

6. Names in the R8 Label Book Summary Sheets Common names Brand names (If the chemical name is needed – see the label not the summary sheet)

7. Another Caution --- Pronunciation of Names FORAY 4-AA PHORATE

8. Some quick definitions Solution * Suspension * - Emulsion * - Invert Emulsion * Bypass definitions

9. Some quick definitions Solution A liquid or solid chemical which is dispersed completely (not suspended) in water or another fluid. For our purposes this includes water solutions and ester or other oil- soluble chemical dissolved in oil Return

10. Some quick definitions Suspension Finely divided solid particles or liquid droplets dispersed (but not dissolved) in another solid, a liquid or a gas. Return

11. Some quick definitions Emulsion A suspension of small droplets of an oil- based or an ester pesticide in water Return

12. Some quick definitions Invert Emulsion A suspension of small droplets of water in an oil. Some chemicals are now produced as invert emulsions

13. Some quick definitions Invert Emulsion Generally the formation of an invert emulsions is undesirable. Without special precautions during mixing and use they commonly form resulting, in a sludge of the approximate consistency of mayonnaise that clogs hoses and nozzles and creates a major problem of clean-up

14. Some quick definitions Solution Suspension EmulsionInvert emulsion Oil droplets in water Water droplets in oil Dissolved –Does not separate Mixed – can separate

15. Types of Product Formulation Liquids –Solutions –Emulsifiable concentrates –Ultra Low Volume Concentrates –Low Volume Concentrates –Aerosols –Liquified gas Solids –Dusts –Granules –Pellets –Soluble Powders – Wettable Powders –Flowables –Baits

16. Gross Classification of Pesticides by Chemistry Inorganic pesticides * Organic pesticides * Biological pesticides * Skip definitions

17. Gross Classification of Pesticides by Chemistry Inorganics –Molecules do not contain carbon Heavy metals – lead and arsenic Copper products Sulfur products Return

18. Gross Classification of Pesticides by Chemistry Organics –Molecules contain carbon May be chains or rings Return

19. Gross Classification of Pesticides by Chemistry Biologicals –Viruses, bacteria, fungi, and plants –Nematodes, insects and other parasites or predators

20. Classification of Organic Herbicides by Chemistry Phenoxy herbicides * Triazines * Imidazolinone * Sulfonylureas * Bypass details

21. Classification of Organic Herbicides by Chemistry Phenoxy herbicides – 2,4-D, 2,4-DP, 2,4,5-T – Behaves as an auxin causing hypertrophy – Sample structure Return

22. Classification of Organic Herbicides by Chemistry Triazines – Hexazinone – Have extreme soil mobility – Structure Return

23. Classification of Organic Herbicides by Chemistry Imidazolinone – Imazapyr – Structure Return

24. Classification of Organic Herbicides by Chemistry Sulfonylureas – Metsulfuron & sulfometuron methyl – Sample structure

25. Classification of Organic Insecticides by Chemistry Chlorinated hydrocarbons * Organophosphates * Carbamates * Skip definitions

26. Classification of Organic Insecticides by Chemistry Chlorinated hydrocarbons – Dieldrin, aldrin, DDT, mirex, chlordane – Sample structure Return

27. Classification of Organic Insecticides by Chemistry Organophosphates – Malathion, azinphos-methyl, naled – Sample structure Return

28. Classification of Organic Insecticides by Chemistry Carbamates – Carbaryl (Sevin) – Structure

29. 2 Basic Chemical Groups for Herbicides Amines * Esters * Skip details

30. Amine General Characteristics Organic salt Water soluble Low volatility Low in its toxicity to fish Used for injection & cut-surface treatments Return

31. Esters (General Characteristics) Oil based Oil soluble / can be emulsified in water Generally highly volatile Highly toxic to fish Used for bark & foliar applications

32. Amine Ester Organic salt Oil based Injection & cut-surface treatments Low toxicity for fish Low volatility Water soluble Bark or foliar applications High toxicity for fish High volatility Oil soluble or can be emulsified in water

33. LD 50 s of field formulations Garlon 4 --LD 50 1,419 mg/kg Triclopyr – LD 50 630 mg/kg

34. LD 50 s of field formulations Garlon 4 --LD 50 1,419 mg/kg Streamline uses a 17% solution of Garlon 4 => 1,419 / 0.17 = 8,347 mg/kg Foliar spray is normally done as a 3% solution => 1,419 / 0.03 = 47,300 mg/kg

35. Environmental behavior: Several categories of environmental behavior are included in the summaries which precede each chemical presented in the Region-8 Label Book Information includes: Mode of action Selectivity Soil activity and mobility Persistence and breakdown Toxicity to humans and wildlife Application timing Weaknesses or limitations

36. The following slides discuss these and several other properties of pesticides in general Discussion in the “R-8 Label Book” section (later this week) presents chemical specific information

37. Mode of Action: Herbicides Movement in the plant –Contact * –Translocated * Action in the plant –Inhibit protein synthesis, photosynthesis, or growth Bypass definitions

38. Mode of Action: Contact Herbicide One which causes injury to only the plant tissue to which it is applied, or one which is not appreciably translocated within a plant Return

39. Mode of Action: Translocated Herbicide One which is moved within a plant from the point of application to the point of action; may be either phloem-mobile or xylem- mobile The term is often misapplied to include only foliar applied herbicides which move downward from the leaves to the roots Return

40. Mode of Action: Animal Poisons (incl.Insecticides) Contact poison * Systemic poison * Attractants * Pheromones Baits Repellants * Bypass definitions

41. Mode of Action: Contact Insecticide Pesticide which causes injury or death of insect through the touch rather than through inhalation or ingestion Return

42. Mode of Action: Systemic Insecticide Pesticide which is moved within a plant from the point of application to the point where the insect will contact or ingest it Return

43. Mode of Action: Attractants Pesticide which lures animals to a predetermined spot –Pheromones are biochemicals either released by the animal or synthesized which are sex attractants –Baits are chemicals which entice animals for reasons other than sex (smells like food) Return

44. Mode of Action: Repellants Pesticide which discourages animals from coming to a specific area –Many chemicals unrelated to sexual activity (due to smell or other physical characteristic) are repellant to animals –Pheromones in low concentration are attractive to animals but, often, in high concentration become repellant

45. Mode of Action: Life Stage Affected Ovicide * Larvicide * Adulticide * Bypass Definitions

46. Mode of Action: Life Stage Affected Ovicide –Kills eggs Return

47. Mode of Action: Life Stage Affected Larvicide –Kills larval stage (immature) insects Return

48. Mode of Action: Life Stage Affected Adulticide –Kills adult insects

49. Mode of Action: Selectivity Many products express a degree of selectivity –Extremely variable from product to product –Biologicals often more selective than chemicals Despite claims, selectivity is generally limited –Often based on rate Many newer products are more selective Application method also influences selectivity

50. Soil Activity Soil Active Herbicide: applied to or present in the soil, these chemicals are readily absorbed by plant roots and subsequently negatively affects the plant in some manner

51. Soil Activity Non Soil Active Herbicide: applied to or present in the soil, these chemicals are bound to soil particles or organic matter and are essentially unavailable to affect plants

52. Soil Mobility A major contributor to offsite movement Leaching vs. lateral movement Affected by the soil’s –Sand content –Clay content –Organic matter content Affects chemical half-life but not the degradation

53. Persistence and Degradation Persistence – The resistance of a herbicide to metabolic or environmental degradation or removal; a measure of the duration of retention of activity by a pesticide in the environment Degradation – The breakdown of a substance into simpler molecular or atomic components through chemical reaction(s) either in a plant or animal (metabolic degradation) or in the environment (environmental degradation)

54. Persistence/Degradation: Process Drivers Temperature Relative humidity / Rainfall pH Insolation Soil or water biota –Macrophytes –Microbial populations –Worms and microfauna

55. Persistence and Degradation: Half-Life The time required for half the amount of a substance (such as a herbicide) present in or introduced into a system (living or ecological) to be eliminated, whether by excretion, metabolic degradation, off-site transport, or other natural process

56. Toxicity to Humans and Wildlife Varies by chemical Based on the target biochemistry of the product Much more later in this session

57. Primary Forestry Uses Discussion of silvicultural and other uses And, of methods of application Appropriate for the formulation(s) of the pesticide available for use Much more later

58. Application timing Product specific May also relate to formulation Gives a measure of selectivity Discussed for each pesticide and formulation Summarized in the Label Book in a comparative table for all herbicides

59. Weaknesses and Limitations Repeats environmental concerns Toxicological/health concerns Lists formulation specific concerns such as flammability Lists use restrictions

60. Environmental behavior: More thoughts not in specific categories in the label book

61. Off-site movement Lots of differing processes involved

62. Pesticide Movement & Degrade Runoff * Leaching * Degradation –Microbial * –Physical –Hydrolysis * –Photolysis * –Pyrolysis * Volatilization * Bypass definitions

63. Pesticide Movement & Degrade Runoff –movement of pesticide aboveground in water – generally occurs downslope but can also occur on flat or even slightly uphill ground after a flloding rain Return

64. Pesticide Movement & Degrade Leaching –Also called percolation – the process whereby pesticide is moved down through the soil profile Return

65. Pesticide Movement & Degrade Microbial Degradation –Breakdown of pesticides by fungi, bacteria and other microscopic organisms Return

66. Pesticide Movement & Degrade Physical Degradation –Hydrolysis -- Breakdown of a pesticide by water Return

67. Pesticide Movement & Degrade Physical Degradation –Photolysis – breakdown of a pesticide by sun or other light Return

68. Pesticide Movement & Degrade Physical Degradation –Pyrolysis – the breakdown of a pesticide by heat or fire Return

69. Pesticide Movement & Degrade Volatilization – evaporation of a heated pesticide

70. Breakdown generalizations Hotter temperature = faster breakdown Higher relative humidity = faster breakdown More microbes = faster breakdown pH effect = chemical dependant More slope = more runoff

71. Off-site movement generalizations More clay and organics = less leaching Higher temperature = more volatilization Lower relative humidity = more volatilization Higher wind speed = more volatilization and drift Nearer to moving water = higher probability of contamination and off-site movement Finer droplets = more movement