Horticulture Principles and Practices

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FIGURE 12–27 Motorized ventilation inlet opening using the rack-and-pinion system. The opening area selected should ensure proper mixing of the incoming air with the greenhouse air. (Source: Dr. AJ Both, Bioresource Engineering, Department of Plant Biology and Pathology, Rutgers University, New Brunswick, NJ 08901). the greenhouse. Exhaust fans installed at one end of the greenhouse draw in fresh air through louvers installed at the opposite end (Figure 12–28). It should be pointed out that ventilation not only refreshes the greenhouse environment but also cools it. Greenhouse Cooling Systems Although heat is required in winter and cool periods of the growing season, greenhouses need cooling in summer and warm periods. On the average, the ambient temperature in a greenhouse is about 11°C (20°F) higher than the outside temperature. Plants are damaged by both excessive heat and cold. Excessive heat can cause low crop yield through high flower abortion and drop. Greenhouses have vents that help circulate fresh air and provide cooling. However, in certain situations venting is not sufficient to reduce temperatures and cooling systems must be installed. The most common way of cooling a greenhouse is by using an evaporative cooling system (Figure 12–29). This system involves drawing air through pads soaked with water, and hence is also called a fan-and-pad cooling system. The cooling pads are soaked with water dripping from above. These cross-fluted cellulose materials retain moisture quite well. Excelsior pads may also be used. The excess water is drained into a lower trough (sump) and recirculated by a pump. Warm air from outside is forced through the pads by the drawing action of fans at opposite ends of the greenhouse. In the process, some of the trickling water evaporates. Water evaporation removes heat from the air. The fan-and-pad cooling system uses the principle of evaporative cooling. To be effective, all incoming air should be drawn through the cooling pad. Cross-fluted cellulose pads, which look like corrugated cardboard, last longer than excelsior pads and are more popular. Controlling Temperature Controlling temperature should be distinguished from heating the greenhouse. Under conditions in which no heat is required, the temperature of the greenhouse should be maintained at an optimal level. The rule of thumb is to operate a greenhouse at a daytime temperature of 3 to 6°C (5 to 10°F) higher than the nighttime temperature on cloudy days and even higher (8°C or 15°F) on clear days. Since increasing the temperature accelerates growth, it must be done with care so as not to compromise the quality of the produce. Fast growth can cause spindly or thin stems and small flowers. Raising the temperature on a clear, bright day is necessary because light is not a limiting factor for photosynthesis under such conditions. Failure to raise the temperature may cause heat to become a limiting factor. 12.3.2 LIGHT Light is required for photosynthesis and other growth activities. As previously explained, the light required by plants is described in terms of intensity, quality, and duration (Chapter 4). 12.3 Internal Environmental Control 423
FIGURE 12–28 Electric-driven ventilation fans used in stages to provide the required ventilation rate necessary to maintain set point temperatures. (Source: Dr. AJ Both, Bioresource Engineering, Department of Plant Biology and Pathology, Rutgers University, New Brunswick, NJ 08901) FIGURE 12–29 Evaporative cooling pads used to cool the greenhouse when (mechanical) ventilation alone is not sufficient to maintain the desired set point temperature. The (wetted) pads are installed inside the ventilation inlet opening and outside air is drawn through them by ventilation fans installed in the opposite sidewall (not visible). Evaporative cooling is only successful when the relative humidity of the outside air is below saturation (100%). The drier the incoming air, the larger the temperature drop accomplished. Note that evaporative cooling increases the humidity of the greenhouse air. (Source: Dr. AJ Both, Bioresource Engineering, Department of Plant Biology and Pathology, Rutgers University, New Brunswick, NJ 08901). Intensity On a clear summer day, plants in a greenhouse may receive as many as 12,000 footcandles (or 129 kilolux) of light, an excessive amount for most crops, since by 3,000 footcandles (32.3 kilolux), most plant leaves in the direct path of incoming light are light saturated and cannot increase their photosynthetic rate. Whole plants can utilize about 10,000 foot-candles (108 kilolux). Sunlight intensity is also seasonal, being less in winter and more in summer. Crops have different preferences and tolerances for light intensity. For example, foliage (nonflowering) plants are scorched and fade in light intensities above 2,000 to 3,000 foot-candles (21.5 to 32.3 kilolux). African violets lose green color at an even lower light intensity (1,500 foot-candles). Poinsettia plants are a darker shade of green when light is reduced. Also, plants such as geranium and chrysanthemum require shading in cultivation to prevent petal burn. Shading to reduce light by about 40 percent from midspring to midfall is helpful to prevent chloroplast suppression in most greenhouse plants. Greenhouse light intensity can be manipulated in several ways. Shading In addition to fans and evaporative cooling systems, there are certain times during the year (early fall planting season and late spring harvesting period) when excessive heat buildup in detrimental to plant growth, fruit development, and ripening. Some modern greenhouses have retractable shade cloths that automatically deploy when radiation load on the greenhouse exceeds what the cooling systems can handle (Figure 12–30). In some designs the shade system is fixed (Figure 12–31). Shading the greenhouse to reduce excessive light is accomplished in several ways. Glass greenhouses may be sprayed with paint (whitewash) in summer to reflect light and reduce its intensity. Commercial shading paints may be purchased. A screen made from fabric may be more convenient to use if only a section of the greenhouse requires shading. Durable fabrics include polyester and polypropylene; they are available in different densities of 424 Chapter 12 Controlled-Environment Horticulture
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HORTICULTURE Principles and Practic
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HORTICULTURE Principles and Practic
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With love to Theresa, quarterback;
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Brief Contents Preface xxi PART 1 T
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Contents Preface xxi PART 1 THE UND
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5.3 PLANT GROWTH PROCESSES 160 5.4
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8.20 COMMON GREENHOUSE DISEASES 276
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12.3 INTERNAL ENVIRONMENTAL CONTROL
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PART 6 Summary 541 References and S
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22.18 INDOOR COMPOSTING SYSTEMS 668
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Preface Horticulture is the area of
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ACKNOWLEDGMENTS I am very grateful
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PART 1 THE UNDERLYING SCIENCE CHAPT
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1 What Is Horticulture? PURPOSE AND
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(a) (c) (b) (d) FIGURE 1-1 The many
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FIGURE 1 Bridge. The plaza view of
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CYCADS Many people mistake these pr
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FIGURE 2 The world's largest unbran
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FIGURE 2 Sold flowers are loaded on
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FIGURE 1-4 Formal landscaping featu
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1.4 ROLEOFTHENURSERY AND SEED INDUS
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1.5 HORTICULTURE AND SOCIETY Hortic
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TABLE 1-3 U.S. Horticultural Export
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Turfgrass Operation 1. Landscape te
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What Is Horticulture? This site pro
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Examples of botanical gardens http:
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2 Classifying and Naming Horticultu
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Eight major taxa are commonly used
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TABLE 2-3 The Divisions of the King
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HISTORY OF PLANT TAXONOMY PAUL R. F
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AGE OF HERBALISTS Two major events
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possible system of nomenclature. Ho
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TABLE 1 Type Categories for Plant N
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2.3 OTHER CLASSIFICATION SYSTEMS (O
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2. Shrubs. A shrub has no main trun
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Simple Fruits Fleshy Fruits Drupe B
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FIGURE 2-14 A pome, represented by
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2.3.5 CLASSIFICATION OF VEGETABLES
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(a) (b) FIGURE 2-22 (Source: George
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FIGURE 2-25 A narrowleaf plant. (So
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FIGURE 2-29 Parts of a typical gras
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such as rosemary, sage, thyme, marj
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c. Leaves d. Bulbs 2. Cut across (t
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Whole plant Organs FIGURE 3-1 Level
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ibonucleic acid (RNA), proteins, an
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called cristae; this extreme foldin
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By virtue of its position, the prim
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Phloem Tissue Structurally, phloem
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(a) Stalk (b) Culm FIGURE 3-5 Cross
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Scale Compressed stem (a) Whole bul
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Upper epidermis Palisade layer FIGU
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usually occur in xerophytes. In cer
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FIGURE 3-22 Selected common leaf ma
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FIGURE 3-25 Selected common leaf ti
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absorption of water and minerals fr
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Outer bark Inner bark FIGURE 3-37 T
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Anther Filament Stamen FIGURE 3-41
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Exocarp Parts of a typi- FIGURE 3-4
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PRACTICAL EXPERIENCE LABORATORY 1.
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4.1 CLIMATE, WEATHER, AND HORTICULT
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concentration in the atmosphere.A c
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TABLE 4-1 Climatic Adaptation of Se
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and upward. Another important gener
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Rate of photosynthesis mg/sq. dm/hr
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and plants that flower under only c
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times of the year. Growers start th
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content. This section is sometimes
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TABLE 4-7 Soil Mineral Nutrients Es
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Micronutrients (Trace Elements) Mic
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Neutral FIGURE 4-11 A representatio
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4.4 FERTILIZERS Fertilizer sources
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One of the most commonly used contr
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Chlorosis (the yellowing of green l
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Fertilizers may be applied before p
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It is neither practical nor safe to
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Solution: How much of ammonium nitr
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1°C (34°F), the optimum temperatu
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Cellulose sponge Perched water tabl
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Overhead Sprinkler Irrigation Water
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FIGURE 4-19 Furrow irrigation of le
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can self-install an underground irr
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1. Surface drainage. Surface draina
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Secondary Tillage Primary tillage i
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(a) (b) (c) (d) FIGURE 4-20 (Source
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texture. The most commonly used gra
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TABLE 4-11 Selected Standard Mixes
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Steam Pasteurization Steam pasteuri
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Maracher, H. 1986. Mineral nutritio
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5 Plant Physiology PURPOSE AND EXPE
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Growth in an organism follows a cer
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5.1.2 THE ROLE OF SIGNALS IN GROWTH
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waxes are embedded. Waxes consist o
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5.3.1 PHOTOSYNTHESIS Photosynthesis
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CO 2 FIGURE 5-6 The C 4 pathway of
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Growth and Development The general
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TABLE 5-2 Energy Produced from Aero
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Certain plants are adapted to dry e
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conditions exist to sustain growth
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Shoot Elongation In certain plants,
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for success, since high temperature
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FIGURE 5-13 Ripening of plantain sh
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Terminal bud removed Unbranched pla
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conditions—pertaining to light, m
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them to maturity. The major process
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6 Breeding Horticultural Plants PUR
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Similarly, there can be no plant br
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APPLICATION, CHALLENGES, AND PROSPE
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hit with target DNA. Therefore, it
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Generally, within ten days of exper
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Aziz A.N., Sauve R.J., Zhou S., 200
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(b) F 1 Rr Rr round round F 2 RR R
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e.g., Aa × Aa), the lethal allele
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eeder’s equation. Simply stated,
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Before the seed or product becomes
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6.18.2 THE GENERAL STEPS OF RDNA TE
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2. Political disagreement. There ar
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REFERENCES AND SUGGESTED READING Ac
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PART 2 PROTECTING HORTICULTURAL PLA
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7 Biological Enemies of Horticultur
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8. Weeds may clog drains, waterways
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is also a root parasite that obtain
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LEGISLATIVE Both state and federal
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Example Integrated cultural, physic
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7.4.2 IMPORTANT INSECT ORDERS Insec
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Egg FIGURE 7-3 Life cycle of an ins
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sucking insects (also found with so
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FIGURE 7-12 Corn earworm damage. (S
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TABLE 7-1 Selected Fungal Diseases
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7.6.1 SMALL ANIMALS Rabbits, mice,
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FIGURE 7-16 The disease triangle. P
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fungitoxic exudates in its leaves,
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SUMMARY Insects are a major class o
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For the home growers or those who c
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for consumers and the environment).
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TABLE 8-1 Strategy 4: Strategies an
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gibberellic acid spray overcomes st
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In a competitive industry, a variet
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Chemicals gain access to humans thr
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2. Pesticide management. Controllin
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Every organism has its natural enem
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TABLE 8-3 Selected Examples of Biol
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1 2 YEAR 3 4 FIGURE 8-5 cycle. A cr
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6. Heat treatment. In the greenhous
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Organic Compounds (Organics) Organi
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under enclosed conditions (e.g., wa
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FIGURE 8-9 A tractor-mounted spraye
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8.11.9 LANDSCAPE PESTS AND THEIR CO
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application, a particular herbicide
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Further, they do not provide unifor
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SUMMARY Herbicides are chemicals us
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Sulfur may be applied for both prev
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8.23 PREVENTING GREENHOUSE DISEASES
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PART 3 PROPAGATING HORTICULTURAL PL
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9 Sexual Propagation PURPOSE AND EX
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Anther Microspore Megaspore mother
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Lettuce seeds Red light Darkness Fa
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FEDERAL AND STATE SEED LAWS Federal
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Germination Test In laboratory prac
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FIGURE 15 The essential structures
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processing into flour or meal). How
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physiologically immature seeds must
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seeds may be treated in this way be
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The two basic modes of seedling eme
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locations in the field. Home garden
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FIGURE 9-9 A plastic flat. (Source:
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(a) (b) FIGURE 9-12 (a) Sowing seed
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y the gardener or grower. Whatever
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REFERENCES AND SUGGESTED READING Co
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species enables vegetative propagat
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for rapid rooting. There are two ba
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Cutting involving one node (e.g., s
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This practice is especially importa
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10.6.4 STICKING THE CUTTING Cutting
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(a) Indexing by budding Diseased pl
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10.11 M ETHODS OF GRAFTING Grafting
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Scion Wax FIGURE 10-17 Steps in bar
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MODULE 3 BUDDING 10.12 TYPES OF BUD
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MODULE 4 LAYERING 10.13 TYPES OF LA
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Buried part of shoot is nicked FIGU
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variety of ways. In air layering, a
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FIGURE 10-34 by using cormels. Prop
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Psuedobulbs In the Dendrobium orchi
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The technique is used widely in cro
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PART 4 GROWING PLANTS INDOORS CHAPT
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11 Growing Houseplants PURPOSE AND
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TABLE 11-1 Common houseplants Commo
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Saddle leaf Philodendron selloum To
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Window Displays Plants in windows e
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CONTAINER GARDENS DR. TERRI W. STAR
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annuals and hardy perennial species
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of the large container filled with
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perfection about four to six weeks
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FIGURE 11-6 Flowers displayed on th
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TABLE 11-5 Plant Selected Plants fo
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The lighting condition near these w
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Fluorescent Lights Fluorescent ligh
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may be used for one pot or a group
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garden rooms, atriums, or a large c
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Page 412 and 413: amount and quality of light. If sup
Page 414 and 415: 12 Controlled-Environment Horticult
Page 416 and 417: 6. Curvilinear 7. Curved eave 8. Do
Page 418 and 419: Detached greenhouses have several a
Page 420 and 421: 12.2.3 FRAME DESIGN There are two b
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Page 426 and 427: source of heat for times when the t
Page 428 and 429: FIGURE 12-17 Greenhouse production
Page 430 and 431: FIGURE 12-21 Moving tables allowing
Page 432 and 433: Research program on greenhouse engi
Page 434 and 435: greenhouses equipped with a variety
Page 436 and 437: FIGURE 1 Annual energy required per
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Page 440 and 441: FIGURE 6 Amounts of waste energy ut
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Page 450 and 451: FIGURE 12-30 Movable internal shade
Page 452 and 453: FIGURE 12-33 A high pressure sodium
Page 454 and 455: Source of Water The quality of loca
Page 456 and 457: FIGURE 12-37 Overhead sprinkler irr
Page 458 and 459: Intermittent Feed Greenhouse plants
Page 460 and 461: However, in winter, greenhouse vent
Page 462 and 463: OUTCOMES ASSESSMENT 1. Explain the
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Page 466 and 467: 2. Labor. The size of the labor for
Page 468 and 469: FIGURE 13-1 Greenhouse production o
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Page 472 and 473: 13.8.4 AGGREGATE HYDROPONIC SYSTEMS
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Page 476 and 477: 14 Growing Succulents PURPOSE AND E
Page 478 and 479: FIGURE 14-3 Leaf succulent represen
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Page 482 and 483: TABLE 14-1 Plant Selected Popular S
Page 484 and 485: (a) (b) FIGURE 14-12 Typical bromel
Page 486 and 487: 14.7.1 WHAT ARE CACTI? 14.7 CACTI C
Page 488 and 489: FIGURE 14-16 Opuntia. (Source: Crai
Page 490 and 491: FIGURE 14-23 Mammillaria. (Source:
Page 492 and 493: FIGURE 14-28 Both desert and jungle
Page 494 and 495: Growing mix Gravel Cacti (a) (b) FI
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15 Principles of Landscaping PURPOS
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8. Create recreational grounds. Suc
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knowledge, with concern for resourc
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(a) (b) (c) FIGURE 15-2 The occurre
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GUIDELINES FOR LANDSCAPE DESIGN DAV
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the landscape. Some very successful
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Rhythm and Line Panoramic view of a
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FIGURE 15-10 A formal garden. The e
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How frequently do they entertain? A
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the patio should be located on the
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15.7.1 SELECTING PLANTS A homeowner
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Plant Arrangement in the Landscape
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Shadow FIGURE 15-15 Planting a tree
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SUMMARY Landscaping enhances the su
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3. Supply materials on a timely bas
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such as preparation rooms (for mixi
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of environmental fluctuations. Furt
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FIGURE 16-4 A bare-root tree seedli
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17 Installation of the Landscape PU
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for walks, driveways, and patios (F
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Planting may be limited to accentin
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17.3.3 PREPARING THE BED The soil s
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FIGURE 17-4 Bedding plants raised i
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SUMMARY Bedding plants are largely
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TABLE 17-6 Selected Ground Covers T
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TABLE 17-7 Selected Ornamental Gras
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they determine the success and surv
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12. Wildlife attraction. Trees in t
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pennsylvanica), hackberry (Celtis s
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y winds. A stake, which is often a
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TABLE 17-8 Selected Narrowleaf Ever
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TABLE 17-11 Selected Deciduous Shru
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Blooming bushes 1. Blue mist shrub
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Planting Bulblets and Bulbils Speci
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may be divided such that each secti
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FIGURE 18-1 (Source: George Acquaah
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Cool-Season (Temperate) Grasses In
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Growth Habit Turfgrasses are the mo
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Heavy Use Lawns on playgrounds and
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The seed should be free from weeds
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Source of Sod As with seed, sod sup
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A plug of sod FIGURE 18-7 Plugging
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way, plants are able to adapt to th
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form of a can placed on the lawn wi
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TABLE 18-3 Some Common Lawn and Tur
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even surface soil surface for layin
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MacCaskey, M. 1987. All about lawns
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Pruning is sometimes done in conjun
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4. Pruning may be done to reduce th
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19.4.2 SAWS A saw may be designed t
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defeat the purpose of pruning. The
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Bud withers as cut end dries back d
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19.6 STRATEGIES FOR PRUNING ABOVEGR
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Rejuvenation Pruning Cut canes to a
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3. In the third and subsequent year
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(a) Cut Prune (b) FIGURE 19-16 Step
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Eucalyptus and Paulownia are amenab
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TRAINING & PRUNING DECIDUOUS FRUIT
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Summer pruning eliminates an energy
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a) b) FIGURE 2 Newly planted apple
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FIGURE 6 Wooden limb spreaders can
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FIGURE 9. An apple tree trained to
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years to promote continued lateral
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Horizontal Espalier The horizontal
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19.16.1 CANE FRUITS Cane fruits are
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FIGURE 19-26 Shearing of Christmas
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pyramid-like form that is wider at
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After selecting the appropriate spe
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PART 6 GROWING PLANTS OUTDOORS: VEG
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20 Growing Vegetables Outdoors PURP
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The National Agricultural Statistic
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(This item omitted from WebBook edi
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growers should take to determine an
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pests and reduce/ eliminate hail da
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square yard (10 to 68 grams per squ
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High tunnels help increase the prof
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(This item omitted from WebBook edi
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20.4 VEGETABLE MARKET TYPES Fresh V
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Establishing the Crop Planting into
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home water supply from the tap. Thi
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Cole crop Cabbage Root Potato Bean
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6. Adequate nutrition. While overfe
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variable, ranging from creamy yello
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There are two general production pr
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This toxin is heat resistant and no
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large, or jumbo. The bulb may be sw
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REFERENCES Growing selected vegetab
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TABLE 21-1 Popular Herbs and Their
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(a) (b) (c) (d) (e) (f) FIGURE 21-1
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22 Organic Farming PURPOSE AND EXPE
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22.3 PRINCIPLES OF ORGANIC FARMING
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and the specific materials to be us
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22.8 MANAGING SOIL PHYSICAL QUALITY
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preemergent or early postemergent o
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Composting is a deliberate activity
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22.14.5 THE CARBON-TO-NITROGEN RATI
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Moisture Supply Water is required b
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Compost materials FIGURE 22-4 a wir
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As microbial decomposition proceeds
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Establishment and Management of an
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night, freezing can occur in spring
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accomplished by stratification. It
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transmitted by the dagger nematode
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PART 7 SPECIAL TECHNIQUES AND HANDL
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24 Cut Flowers and Floral Design PU
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to more than four-fold in standard
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Temperature and Humidity Wilting re
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FLORAL DESIGN: AN OVERVIEW BY WM. J
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Principle Definition Types (or Uses
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pH value-a measure of the acidity o
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FIGURE 6 Parallel Design-Parallel d
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24.3.2 TOOLS AND MATERIALS The tool
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3. Establish the focal point. 4. Ad
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Natural Drying To dry naturally, fl
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24.4.3 DRIED FLOWER ARRANGEMENTS Dr
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25 Terrarium Culture PURPOSE AND EX
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FIGURE 25-3 Terrarium containers ar
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FIGURE 25-5 Assortment of tools use
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25.6.7 ENHANCING THE DISPLAY Certai
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(a) (b) FIGURE 26-1 Bonsai can be c
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TABLE 26-3 Plant A Selection of Pop
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26.3.1 COLLECTING BONSAI PLANTS FRO
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Strip bark Bare branch FIGURE 26-9
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26.5.2 SANITATION It is critical to
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27 Postharvest Handling and Marketi
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whereas oranges are picked (they ha
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(b) (a) (c) (d) (e1) (e2) (f) FIGUR
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To reduce packaging injury, contain
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is replaced by the by-product of re
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Stored produce may lose some color,
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with pricing. When selling by volum
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(a) (b) FIGURE 27-5 Horticultural p
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APPENDIX A Temperature: Converting
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APPENDIX B Metric Conversion Chart
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APPENDIX D Common and Scientific Na
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Pecan (Carya illinoensis) Peony (Pa
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GLOSSARY A Abaxial Turned away from
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Cellulose A complex carbohydrate th
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Floriculture The science and practi
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M Macronutrient An essential elemen
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Root cap A mass of hard cells cover
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INDEX A-frame, 395 A-horizon, 108 A
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defined, 390 fertilization, 432-434
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Radiant heaters, 378 Radicle, 90 Re
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color plate 1 (a) (b) (c) (d) (e) M
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color plate 3 (b) (a) (c) (d) (e) (
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color plate 5 (a) (b) (d) (c) (e) (
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color plate 7 (b) (c) (d) (a) (e) (
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color plate 9 (a) (b) (c) (d) (e) (
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color plate 11 (a) (c) (b) (d) Grow
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color plate 13 (a) (b) (c) (d) (e)
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color plate 21 (a) (b) (c) (e) (d)
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color plate 23 (c) (b) (a) (d) (e)
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color plate 25 (c) (a) (b) (d) (e)
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color plate 27 (a1) (a2) (b2) (b1)
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color plate 31 (a) (b) (c) Floral d
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Horticulture Principles and Practices

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