CULTURAL TURF MANAGEMENT PRACTICES Lesson 2 of Self-Guided

CULTURAL TURF MANAGEMENT PRACTICES Lesson 2 of Self-Guided Educational Module

Learning Objectives 2 1. Understand cultural turf management practices including: a. Mowing b. Fertilization c. Irrigation d. Soil Analysis e. Aeration f. Overseeding

Mowing 3 Keep mower blades sharp to provide a clean cut, this minimizes disease Minimize scalping and soil compaction and rutting of playfields by rotating the direction of mowing each time the lawn is clipped Keep mowers in good repair; leaking oil, gasoline fuel, leaky hydraulic lines and grease can damage or kill turf

Mowing 4 The One-Third Rule To sustain vigorous turf, remove no more than one-third of height of the grass from soil level at any one mowing event Mowing height Mow tall to encourage deeper rooting, which will improve tolerance to environmental stress and reduce the need for fertilizer and pesticides Most non-athletic turfgrasses used on school lawns can be mowed at a height of 2 ½ -3 inches (there are exceptions) For example,

Mowing 5 To adhere to the 1/3 rule, mow your turf at least once a week If possible mow high priority areas such as athletic fields twice a week during periods of heavy growth Increased mowing frequency will increase turf density, wear tolerance and decrease weed encroachment

Mowing 6 6” 4.5” 4” 3” 3” 2” Height prior to mowing The one-third rule Height after mowing 1.5” 1” Alec Kowaleski, Oregon State University

Mowing 7 High Cut Low Cut The picture depicts the effect of mowing height on root growth A lower cut produces shorter roots, less stress tolerance and allows more

When to Mow 8 Mow when the lawn is dry to minimize the chance of spreading diseases Dry clippings almost never need to be removed from turf Clippings do not contribute to thatch Clippings return nutrients to the soil decreasing fertility requirements

Fertilization 9 A basic soil test will identify the soil pH/lime requirements, as well as phosphorus, potassium and secondary nutrient deficiencies Soil test labs may provide recommendations Alec Kowaleski, Oregon State

1. Fertilization 10 All grasses require certain nutrients, including nitrogen (N), phosphorus (P) and potassium (K) There are no generic N fertilization recommendations that apply to all situations Fertilizing with P should be based on a soil test Fertilizing with N should be based on turfgrasses present, site and use of turf Use a fertilizer that supplies a higher concentration of nitrogen and low

Fertilization 11 In several states (WA, MN, WI and others), fertilizers containing phosphorus cannot be applied unless a soil test documents a deficiency, to protect lakes, rivers and streams Soil test results will provide specifics on the phosphorus rates

Fertilization 12 There are two basic forms of nitrogen contained in fertilizer products Water-soluble nitrogen (WSN) which is readily available to the plant Slow-release nitrogen (SRN) which is available in the form of waterinsoluble nitrogen (WIN) or controlled-release nitrogen Manufactured turf fertilizers are often formulated with a mixture of

Fertilization 13 The percentages of WSN and SRN in a fertilizer product will affect the Nrelease rate, price and other factors Characteristics of WSN and SRN sources may be considered either advantageous or disadvantageous depending on the specific management situation

Fertilization 14 Use the lowest product rate possible that will meet your expectations for growth, appearance, and produce healthy turf Slow-release fertilizers will: Prolong the availability of nutrients throughout the growing season Reduce the risk of water pollution Compost, depending on the parent materials, can also be a source of P

When to Use Fertilizer 15 Timing and rate of fertilizer applications depend on: The requirements of the turfgrass species Your expectations for turf quality and turf density Seasonal limitations and the use of the area Application rates range from 0.5 to 1.5 lbs N per 1,000 ft2, split applications so that no more than ¼ lb of water-soluble N is applied in any one application

Irrigation Frequency 16 Water deeply but infrequently, based on need, to encourage a deep root system How frequently you irrigate depends on the soil type, weather conditions, species of grass and the mowing height and use of the turf Delay irrigation in the spring to encourage

Irrigation Amount 17 Supplement rainfall to provide a total of one inch of water per week It takes 620 gallons of water to apply one inch of water to 1000 ft2 of turf, it’s best applied in several applications to avoid runoff and saturation Overwatering reduces root growth, promotes compaction and disease activity and decreases overall wear

1. Irrigation Timing 18 Water turf just before it begins to wilt, signs of wilting include: A bluish-green or purplish color to the grass Rolling or folding blades of grass Footprints that remain on the lawn for several minutes after passage Soil that is dry at the soil surface; penetration with a screwdriver is

Irrigation Timing Continued 19 Water turf very early in the morning, this can limit evaporation and reduces disease problems Extended periods of leaf wetness caused by high humidity, excessive watering and standing water encourages fungal diseases All areas of the lawn should receive adequate coverage and low spots should be leveled or drained to

Soil Analysis 20 An uninformed approach to soil and nutrient management is neither economically viable nor environmentally responsible Basic soil test results can dictate approaches to soil management, assessment of overall plant health, refinement of a fertility program, prevention of nutrient losses to the environment and other aspects of

Soil Analysis 21 Sample soil and conduct chemical and physical soils analysis prior to establishment, renovation or at the beginning of assuming management responsibility for a site where limited history is available

Soil Analysis 22 Soil Chemical Properties E.g., pH, fertility, nutrient reserves, heavy metals, salinity Provides information about the growing conditions plants will be exposed to Soil Physical Properties E.g., texture, particle size distribution, percent organic matter Provides information about soil health Helps indicate drainage

Soil Analysis 23 For established, healthy turf, conduct soil chemical analyses at least every three years and monitor pH annually Test soil conditioners, Soil profile topdressing materials, composts and other turf amendments separately to ensure suitability for use

Soil Analysis 24 Learn how to correctly interpret soil test results Soil test results are of little value without an appropriate interpretation As the soil test level for a nutrient increases, plant growth increases to a point where the nutrient is no longer limiting; this point is known as the critical soil test level The critical soil test level is defined as the extractable nutrient concentration

Soil Analysis 25 Nutrient levels are considered sufficient when the concentration is just above the critical soil test level This is known as the optimum soil test range

Soil Analysis 26 When levels are below the optimum range (very low or low), the addition of more nutrients will usually improve turf performance When soil test levels are in the optimum range turf response to application of that nutrient is unlikely, but some amount may be recommended to maintain soil levels over time

Soil Analysis 27 Factors other than nutrients may limit turfgrass growth, and simply adding more nutrients may not improve turf performance To optimize turf performance and maximize response to fertilizer, sound management practices must be used including cultivar selection, establishment, irrigation management and pest and stress

Interpretation of Soil Test Categories 28 Categori Interpretation es Very Low Substantial amounts of additional nutrients required to achieve optimum growth Fertilizer rates should be based on plant response and are designed to gradually increase soil nutrient levels to the optimum range over several years Low Moderate amounts of additional nutrients needed to achieve optimum growth Recommendations based on plant response and are intended to gradually increase soil nutrient levels to the optimum range Optimu m Most desirable soil test range on economic and environmental basis To maintain this range for successive years, nutrients must be retained in the system, or those nutrients lost or consumed must be replaced Above optimu m The nutrient is considered more than adequate and will not limit the plants At the top end of this range, there is the possibility of a

Aeration 29 Aeration is the process of making holes in the turf to improve air exchange, help water penetrate and drain and decrease the soil density and organic matter Soil compaction occurs when lawns are used heavily and the pore spaces that allow water and air to pass through the soil collapse, creating poor conditions for root growth Aeration promotes growth, helps manage thatch buildup and relieves soil

Aeration 30 Hollow tine core cultivation Unlike other aerification methods, this method improves drainage, reduces organic matter and relieves compaction by pulling cores from soil Aeration of turf - David Kopec, University of Arizona

Aeration 31 Pulverize and distribute the cores over the field with a steel drag mat to distribute the soil, this is a great time to overseed Top dressing with compost (ideally over aeration holes) and rotating mowing patterns also helps relieve soil compaction

When to Aerate 32 The soil must be moist enough to allow good penetration but not too moist that machinery will rut or compact the soil Irrigate area at least one day before aerating and check depth and amount of soil moisture Time aeration efforts to avoid periods when weeds are producing seed or when the grass will not

When to Aerate 33 Practice fields should be aerated one to three times a year Lawns should be aerated one time a year or less depending on use Heavily used turf may require Turf shoot growth - Alec Kowaleski, Oregon State University

1. Overseeding 34 Overseeding generally means: Introducing more seed of the same grass type into the established turf or Spreading seed of a different type as environmental conditions change For example, when cool-season turf is seeded into warm-season turf during the winter

1. Overseeding 35 Overseeding helps: Thicken the turf stand Avoid excessive compaction Minimize soil erosion Prevent weed seed germination Overseeding is usually performed using a spreader which may be a drop or rotary design

Overseeding 36 Slit seeding or drilling places the seed directly in the soil Usually a single pass is sufficient, but bare areas require multiple passes in two to three directions to provide sufficient seed Spot seeding with a fast germinating turf should be done any time there is an open area caused by weed control, turf removal or winter damage, grubs, etc. Broadcast seeding is performed a variety of ways and may be combined with aeration Spikers, hollow-tine aerifiers or vertical mowers

Check In! 37 This lesson you learned: 1. Cultural turf management practices including: Mowing Fertilization Irrigation Soil Analysis Aeration Overseeding Next you will learn more about common turfgrass weeds and insects!

Resource List 38 Iowa State University. (2010). Plant and Insect Diagnostic Clinic. http://www.ipm.iastate.edu/ipm/info/plant-diseases/turfgrass-rust Maine Department of Agriculture, Conservation and Forestry. School IPM. http://www.maine.gov/dacf/php/integrated pest manageme nt/school/index.shtml Rutgers Cooperative Extension. IPM Report Card for School Grounds: General Requirements. http://entomology.osu.edu/schoolipm/IPMfiles/ReportCardGe neral.pdf Texas A&M Agrilife Extension. Landscape IPM Module 6. http://schoolipm.tamu.edu/videodvd/ Umass Extension Center for Agriculture. Best Management