Horticulture Principles and Practices

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2. Political disagreement. There are political positions on the social and economic impacts of biotechnology on society, the pendulum swinging in favor of the dominant political ideology of the day. 3. Religious, ethical, and philosophical disagreements. These are faith-based issues about morality and whether scientists are playing God, or whether biotechnology is natural. In a pluralistic society, consensus is often difficult to achieve, leading some to pursue extremist acts of vigilantism (e.g., destroying biotech research labs). There are perceptions and fears about biotechnology in society. Some think the technology is alien, unnatural, and too radical. The normal direction of genetic information transfer (central dogma) is from DNA to RNA to proteins; genetic engineering can reverse this process, synthesizing DNA from protein. The transfer of DNA across natural biological boundaries is deemed playing God, as well. It should be pointed out that such a transfer occurs in nature whereby the bacterium Agrobacterium tumifaciens causes tumors in plants by transferring bacterial DNA into cells upon infection. In fact, this bacterium is widely used in genetic engineering in this natural role. There is the concern of the unknown, the possibility of creating monsters and superweeds. These and many other concerns prevail, keeping the debate alive. Biotechnology is a very highly regulated industry. In the United States, the USDA (United States Department of Agriculture), EPA (Environmental Protection Agency), and the FDA (Food and Drug Administration) are all engaged. The USDA focuses on plant pests, plants, and veterinary biologics; the EPA on microbial/plant pesticides, novel microorganisms, and existing pesticide; and the FDA on food, feed, food additives, veterinary drugs, human drugs, and medical devices. GM products are evaluated and labeled as such before commercialization. 6.23 TISSUE CULTURE IN PLANT BREEDING Tissue culture or micropropagation, as it is sometimes called, is a technology that is useful to plant breeders. The premise of this technology is that the cell is the fundamental unit of organization of the organism, and contains all the requisite genetic information to make the entire organism (totipotent). It is possible, and routinely done, to raise a whole plant from a single cell! This is critical to genetic engineering, for the transgene is inserted into a single cell that is nurtured and regenerated into a full blown plant in vitro (in the test tube). Micropropagation is useful for multiplying a limited amount of plant material very rapidly. Pieces of the plant part (leaf, stem, roots, flower, etc.) can be obtained and nurtured into full plants. Plants so produced are clones (genetically identical). The plant part used to start tissue culture is called the explant. By manipulating the cultural environment using growth regulators, the researcher can induce a variety of morphological structures, including roots and shoots. The induction of organs from explants is called organogenesis. In genetic engineering applications, often the explant used is the callus, an amorphous mass of meristematic cells that are equivalent to human stem cells in that they can be manipulated to produce various organs. Pieces of DNA or genes can be inserted into single cells in the callus by direct bombardment in a special device called a gene gun (Figure 6–5). Another common approach is to use specially modified bacteria (Agrobacterium) to transfer the gene of interest into the cell. Another application of tissue culture in breeding is embryo rescue. When plants that are genetically distant are crossed, there is often a number of problems, including lethality, failure of fertilization, or failure of the embryo to develop. Just like premature birth in humans, plant breeders may extract the immature embryo from the flower and culture on appropriate media to produce a full plant. 6.23 Tissue Culture in Plant Breeding 207
FIGURE 6–5 A gene gun. This tabletop model uses compressed helium gas to propel the DNA. (Source: George Acquaah) SUMMARY 208 Chapter 6 Breeding Horticultural Plants Plant improvement involves the manipulation of the genome of the plant with a specific goal in mind. A good understanding of genetics helps breeders to be effective and efficient in their endeavors. DNA, hereditary material, is located mostly in the nuclei of plants in linear structures called chromosomes. Genes, the factors that condition traits, are pieces of DNA arranged in a linear order in chromosomes. Gene—not traits—are inherited by the offspring from their parents. The transmission of genes in this fashion is governed by certain laws that were discovered by Mendel: gene pairs segregate during cell division so that only one from each pair ends up in each gamete, and genes assort independently during meiosis. Some genes (dominant) mask the expression of others (recessive) when they occur at the same locus. Meiosis is the major source of biological variation. However, the ultimate source of variation is mutation. The expression of genes is subject to the environment in which they occur. Certain traits are governed by one or a few genes (simply inherited), whereas others are governed by many genes with small effects (quantitative traits). The underlying principle in plant breeding is that the phenotype (what is observed) is a product of the interaction between the genotype (genetic makeup) of the individual and its environment. Phenotype can therefore be changed by manipulating either the genotype (plant breeding) or its environment (agronomy). Before starting a breeding program, breeders should first ascertain whether adequate heritable variation is available. Then they should have clear goals or objectives. The specific methods used depend on the mating system of the plant. Genetic changes may be made in flowering plants through crossing (hybridization). Molecular biotechnological procedures are being utilized by plant breeders to accelerate their breeding programs through the use of molecular markers for effective selection. Further, breeders are able to import genes from outside of the genus with which they are working and thereby develop transgenic plants. Problems that once were impossible to solve with conventional breeding are being tackled with amazing success using molecular biotechnological tools. It should be emphasized that conventional and molecular biotechnological methods of breeding are complementary tools. Geneticists and breeders work together to improve horticultural plants.
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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
Page 182 and 183: 5.1.2 THE ROLE OF SIGNALS IN GROWTH
Page 184 and 185: waxes are embedded. Waxes consist o
Page 186 and 187: 5.3.1 PHOTOSYNTHESIS Photosynthesis
Page 188 and 189: CO 2 FIGURE 5-6 The C 4 pathway of
Page 190 and 191: Growth and Development The general
Page 192 and 193: TABLE 5-2 Energy Produced from Aero
Page 194 and 195: Certain plants are adapted to dry e
Page 196 and 197: conditions exist to sustain growth
Page 198 and 199: Shoot Elongation In certain plants,
Page 200 and 201: for success, since high temperature
Page 202 and 203: FIGURE 5-13 Ripening of plantain sh
Page 204 and 205: Terminal bud removed Unbranched pla
Page 206 and 207: conditions—pertaining to light, m
Page 208 and 209: them to maturity. The major process
Page 210 and 211: 6 Breeding Horticultural Plants PUR
Page 212 and 213: Similarly, there can be no plant br
Page 214 and 215: APPLICATION, CHALLENGES, AND PROSPE
Page 216 and 217: hit with target DNA. Therefore, it
Page 218 and 219: Generally, within ten days of exper
Page 220 and 221: Aziz A.N., Sauve R.J., Zhou S., 200
Page 222 and 223: (b) F 1 Rr Rr round round F 2 RR R
Page 224 and 225: e.g., Aa × Aa), the lethal allele
Page 226 and 227: eeder’s equation. Simply stated,
Page 228 and 229: Before the seed or product becomes
Page 230 and 231: 6.18.2 THE GENERAL STEPS OF RDNA TE
Page 234 and 235: REFERENCES AND SUGGESTED READING Ac
Page 236 and 237: PART 2 PROTECTING HORTICULTURAL PLA
Page 238 and 239: 7 Biological Enemies of Horticultur
Page 240 and 241: 8. Weeds may clog drains, waterways
Page 242 and 243: is also a root parasite that obtain
Page 244 and 245: LEGISLATIVE Both state and federal
Page 246 and 247: Example Integrated cultural, physic
Page 248 and 249: 7.4.2 IMPORTANT INSECT ORDERS Insec
Page 250 and 251: Egg FIGURE 7-3 Life cycle of an ins
Page 252 and 253: sucking insects (also found with so
Page 254 and 255: FIGURE 7-12 Corn earworm damage. (S
Page 256 and 257: TABLE 7-1 Selected Fungal Diseases
Page 258 and 259: 7.6.1 SMALL ANIMALS Rabbits, mice,
Page 260 and 261: FIGURE 7-16 The disease triangle. P
Page 262 and 263: fungitoxic exudates in its leaves,
Page 264 and 265: SUMMARY Insects are a major class o
Page 266 and 267: For the home growers or those who c
Page 268 and 269: for consumers and the environment).
Page 270 and 271: TABLE 8-1 Strategy 4: Strategies an
Page 272 and 273: gibberellic acid spray overcomes st
Page 274 and 275: In a competitive industry, a variet
Page 276 and 277: Chemicals gain access to humans thr
Page 278 and 279: 2. Pesticide management. Controllin
Page 280 and 281: 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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The photoperiod affects when the ho
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patted firm to keep the plant erect
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Other Materials Apart from clay and
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(a) ( FIGURE 11-25 Support for plan
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TABLE 11-7 Common Problems of House
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• Keep soil moist all the time
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• Prefers high temperatures • P
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amount and quality of light. If sup
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12 Controlled-Environment Horticult
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6. Curvilinear 7. Curved eave 8. Do
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Detached greenhouses have several a
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12.2.3 FRAME DESIGN There are two b
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horticultural business a less-expen
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Texas, Hawaii, and California. The
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source of heat for times when the t
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FIGURE 12-17 Greenhouse production
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FIGURE 12-21 Moving tables allowing
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Research program on greenhouse engi
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greenhouses equipped with a variety
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FIGURE 1 Annual energy required per
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This system was demonstrated in a 5
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FIGURE 6 Amounts of waste energy ut
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Ekholt, B.A., D.R. Mears, M.S. Gini
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or object to be warmed. Failure to
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objects in its path (e.g., the floo
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FIGURE 12-27 Motorized ventilation
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FIGURE 12-30 Movable internal shade
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FIGURE 12-33 A high pressure sodium
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Source of Water The quality of loca
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FIGURE 12-37 Overhead sprinkler irr
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Intermittent Feed Greenhouse plants
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However, in winter, greenhouse vent
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OUTCOMES ASSESSMENT 1. Explain the
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. Foliage or green plants. Foliage
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2. Labor. The size of the labor for
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FIGURE 13-1 Greenhouse production o
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FIGURE 13-2 Lettuce plug is inserte
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13.8.4 AGGREGATE HYDROPONIC SYSTEMS
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(a) (b) (c) FIGURE 13-6 Plug produc
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14 Growing Succulents PURPOSE AND E
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FIGURE 14-3 Leaf succulent represen
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frost-hardy. Their rosettes are usu
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TABLE 14-1 Plant Selected Popular S
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(a) (b) FIGURE 14-12 Typical bromel
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14.7.1 WHAT ARE CACTI? 14.7 CACTI C
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FIGURE 14-16 Opuntia. (Source: Crai
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FIGURE 14-23 Mammillaria. (Source:
Page 492 and 493:
FIGURE 14-28 Both desert and jungle
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Growing mix Gravel Cacti (a) (b) FI
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PART5 GROWING PLANTS OUTDOORS: ORNA
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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
Page 716 and 717:
pH value-a measure of the acidity o
Page 718 and 719:
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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