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Wikipedia

Plant nursery

February 16, 2024

For other uses of "Nursery", see Nursery (disambiguation).

A nursery is a place where plants are propagated and grown to a desired size. Mostly the plants concerned are for gardening, forestry, or conservation biology, rather than agriculture. They include retail nurseries, which sell to the general public; wholesale nurseries, which sell only to businesses such as other nurseries and commercial gardeners; and private nurseries, which supply the needs of institutions or private estates. Some will also work in plant breeding.

Plants in a nursery

A "nurseryman" is a person who owns or works in a nursery.[1]

Some nurseries specialize in certain areas, which may include: propagation and the selling of small or bare root plants to other nurseries; growing out plant materials to a saleable size, or retail sales.[2] Nurseries may also specialize in one type of plant, e.g., groundcovers, shade plants, or rock garden plants. Some produce bulk stock, whether seedlings or grafted trees, of particular varieties for purposes such as fruit trees for orchards or timber trees for forestry. Some producers produce stock seasonally, ready in the spring for export to colder regions where propagation could not have been started so early or to regions where seasonal pests prevent profitable growing early in the season.

Nurseries edit

There are a number of different types of nurseries, broadly grouped as wholesale or retail nurseries, with some overlap depending on the specific operation. Wholesale nurseries produce plants in large quantities which are sold to retail nurseries[3]encyclopedia[4]

Wholesale nurseries may be small operations that produce a specific type of plant using a small area of land, or very larger operations covering many acres. They propagate plant material or buy plants from other nurseries which may include rooted or unrooted cuttings, or small rooted plants called plugs, or field grown bare root plants, which are planted and grown to a desired size. Some wholesale nurseries produce plants on contract for others which place an order for a specific number and size of plant, while others produce a wide range of plants that are offered for sale to other nurseries and landscapers and sold as first come first served. Retail nurseries sell plants ready to be placed in the landscape or used in homes and businesses

Methods edit

 
A small nursery filled with orchid plants in bloom.
 
A tree nursery using gutters to decrease growing costs

Propagation Nurseries produce new plants from seeds, cuttings, tissue culture, grafting, or division. The plants are then grown out to a salable size and either sold to other nurseries that may continue to grow the plants out in larger containers or field grow them to desired size. Propagation nurseries may also sell plant material large enough for retail sales and thus sale directly to retail nurseries or garden centers (which rarely propagated their own plants).[5]

Nurseries may produce plants for reforestation, zoos, parks, and cities. With Tree nurseries in the U.S. producing around 1.3 billion seedlings per year for reforestation.[6]

Nurseries grow plants in open fields, on container fields, in tunnels or greenhouses. In open fields, nurseries grow decorative trees, shrubs and herbaceous perennials. On a containerfield nurseries grow small trees, shrubs and herbaceous plants, usually destined for sales in garden centers. These have proper ventilation, sunlight etc. Plants may be grown by seeds, but the most common method is by planting cuttings, which can be taken from shoot tips or roots.

Conditioning edit

With the objective of fitting planting stock more able to withstand stresses after outplanting, various nursery treatments have been attempted or developed and applied to nursery stock. Buse and Day (1989),[7] for instance, studied the effect of conditioning of white spruce and black spruce transplants on their morphology, physiology, and subsequent performance after outplanting. Root pruning, wrenching, and fertilization with potassium at 375 kg/ha were the treatments applied. Root pruning and wrenching modified stock in the nursery by decreasing height, root collar diameter, shoot:root ratio, and bud size, but did not improve survival or growth after planting. Fertilization reduced root growth in black spruce but not of white spruce.

Hardening off, frost hardiness edit

Seedlings vary in their susceptibility to injury from frost. Damage can be catastrophic if "unhardened" seedlings are exposed to frost. Frost hardiness may be defined as the minimum temperature at which a certain percentage of a random seedling population will survive or will sustain a given level of damage (Siminovitch 1963, Timmis and Worrall 1975).[8][9] The term LT50 (lethal temperature for 50% of a population) is commonly used. Determination of frost hardiness in Ontario is based on electrolyte leakage from mainstem terminal tips 2 cm to 3 cm long in weekly samplings (Colombo and Hickie 1987).[10] The tips are frozen then thawed, immersed in distilled water, the electrical conductivity of which depends on the degree to which cell membranes have been ruptured by freezing releasing electrolyte. A −15 °C frost hardiness level has been used to determine the readiness of container stock to be moved outside from the greenhouse, and −40 °C has been the level determining readiness for frozen storage (Colombo 1997).[11]

In an earlier technique, potted seedlings were placed in a freezer chest and cooled to some level for some specific duration; a few days after removal, seedlings were assessed for damage using various criteria, including odour, general visual appearance, and examination of cambial tissue (Ritchie 1982).[12]

Stock for fall planting must be properly hardened-off. Conifer seedlings are considered to be hardened off when the terminal buds have formed and the stem and root tissues have ceased growth. Other characteristics that in some species indicate dormancy are color and stiffness of the needles, but these are not apparent in white spruce.

Forest tree nurseries edit

Whether in the forest or in the nursery, seedling growth is fundamentally influenced by soil fertility, but nursery soil fertility is readily amenable to amelioration, much more so than is forest soil.

Nitrogen, phosphorus, and potassium are regularly supplied as fertilizers, and calcium and magnesium are supplied occasionally. Applications of fertilizer nitrogen do not build up in the soil to develop any appreciable storehouse of available nitrogen for future crops.[13] Phosphorus and potassium, however, can be accumulated as a storehouse available for extended periods.

Fertilization permits seedling growth to continue longer through the growing season than unfertilized stock; fertilized white spruce attained twice the height of unfertilized.[14] High fertility in the rooting medium favours shoot growth over root growth, and can produce top-heavy seedlings ill-suited to the rigors of the outplant site. Nutrients in oversupply can reduce growth[15][16] or the uptake of other nutrients.[17] As well, an excess of nutrient ions can prolong or weaken growth to interfere with the necessary development of dormancy and hardening of tissues in time to withstand winter weather.[18]

Stock types, sizes and lots edit

Nursery stock size typically follows the normal curve when lifted for planting stock. The runts at the lower end of the scale are usually culled to an arbitrary limit, but, especially among bareroot stock, the range in size is commonly considerable. Dobbs (1976)[19] and McMinn (1985a)[20] examined how the performance of 2+0 bareroot white spruce related to differences in initial size of planting stock. The stock was regraded into large, medium, and small fractions according to fresh weight. The small fraction (20% of the original stock) had barely one-quarter of the dry matter mass of the large fraction at the time of outplanting. Ten years later, in the blade-scarified site, seedlings of the large fraction had almost 50% greater stem volume than had seedlings of the small fraction. Without site preparation, large stock were more than twice the size of small stock after 10 years.

 
Nursery of apricot seedlings

Similar results were obtained with regraded 2+1 transplants sampled to determine root growth capacity.[21][22] The large stock had higher RGC as well as greater mass than the small stock fraction.

The value of large size at the time of planting is especially apparent when outplants face strong competition from other vegetation, although high initial mass does not guarantee success. That the growth potential of planting stock depends on much more than size seems clear from the indifferent success of the transplanting of small 2+0 seedlings for use as 2+1 "reclaim" transplants.[20] The size of bareroot white spruce seedlings and transplants also had a major influence on field performance.

The field performance among various stock types in Ontario plantations was examined by Paterson and Hutchison (1989):[23] the white spruce stock types were 2+0, 1.5+0.5, 1.5+1.5, and 3+0. The nursery stock was grown at Midhurst Forest Tree Nursery, and carefully handled through lifting on 3 lift dates, packing, and hot-planting into cultivated weed-free loam. After 7 years, overall survival was 97%, with no significant differences in survival among stock types. The 1.5+1.5 stock with a mean height of 234 cm was significantly taller by 18% to 25% than the other stock types. The 1.5+1.5 stock also had significantly greater dbh than the other stock types by 30-43%. The best stock type was 57 cm taller and 1 cm greater in dbh than the poorest. Lifting date had no significant effect on growth or survival.

High elevation sites in British Columbia's southern mountains are characterized by a short growing season, low air and soil temperatures, severe winters, and deep snow. The survival and growth of Engelmann spruce and subalpine fir outplanted in 3 silvicultural trials on such sites in gaps of various sizes were compared by Lajzerowicz et al. (2006).[24] Survival after 5 or 6 years decreased with smaller gaps. Height and diameter also decreased with decreasing size of gap; mean heights were 50 cm to 78 cm after 6 years, in line with height expectations for Engelmann spruce in a high-elevation planting study in southeastern British Columbia.[25] In the larger gaps (≥1.0 ha), height increment by year 6 was ranging from 10 cm to 20 cm. Lajzerrowicz et al. Concluded that plantings of conifers in clearcuts at high elevations in the southern mountains of British Columbia are likely to be successful, even close to timberline; and group selection silvicultural systems based on gaps 0.1 ha or larger are also likely to succeed. Gaps smaller than 0.1 ha do not provide suitable conditions for obtaining adequate survival or for growth of outplanted conifers.

Planting stock edit

Planting stock, "seedlings, transplants, cuttings, and occasionally wildings, for use in planting out,"[26] is nursery stock that has been made ready for outplanting. The amount of seed used in white spruce seedling production and direct seeding varies with method.

A working definition of planting stock quality was accepted at the 1979 IUFRO Workshop on Techniques for Evaluating Planting Stock Quality in New Zealand: "The quality of planting stock is the degree to which that stock realizes the objectives of management (to the end of the rotation or achievement of specified sought benefits) at minimum cost. Quality is fitness for purpose."[27] Clear expression of objectives is therefore prerequisite to any determination of planting stock quality.[28] Not only does performance have to be determined, but performance has to be rated against the objectives of management.[29] Planting stock is produced in order to give effect to the forest policy of the organization.

A distinction needs to be made between "planting stock quality" and "planting stock performance potential" (PSPP). The actual performance of any given batch of outplanted planting stock is determined only in part by the kind and condition, i.e., the intrinsic PSPP, of the planting stock.

The PSPP is impossible to estimate reliably by eye because outward appearance, especially of stock withdrawn from refrigerated storage, can deceive even experienced foresters, who would be offended if their ability were questioned to recognize good planting stock when they saw it. Prior to Wakeley's (1954)[30] demonstration of the importance of the physiological state of planting stock in determining the ability of the stock to perform after outplanting, and to a considerable extent even afterwards, morphological appearance has generally served as the basis for estimating the quality of planting stock. Gradually, however, a realization developed that more was involved. Tucker et al. (1968),[31] for instance, after assessing 10-year survival data from several experimental white spruce plantations in Manitoba noted that "Perhaps the most important point revealed here is that certain lots of transplants performed better than others", even though all transplants were handled and planted with care. The intuitive "stock that looks good must be good" is a persuasive, but potentially dangerous maxim. That greatest of teachers, Bitter Experience, has often enough demonstrated the fallibility of such assessment, even though the corollary "stock that looks bad must be bad" is likely to be well founded. The physiological qualities of planting stock are hidden from the eye and must be revealed by testing. The potential for survival and growth of a batch of planting stock may be estimated from various features, morphological and physiological, of the stock or a sample thereof.

The size and shape and general appearance of a seedling can nevertheless give useful indications of PSPP. In low-stress outplanting situations, and with a minimized handling and lifting-planting cycle, a system based on specification for nursery stock and minimum morphological standards for acceptable seedlings works tolerably well.[32] In certain circumstances, benefits often accrue from the use of large planting stock of highly ranked morphological grades. Length of leading shoot, diameter of stem, volume of root system, shoot:root ratios, and height:diameter ratios have been correlated with performance under specific site and planting conditions.[33] However, the concept that larger is better negates the underlying complexities. Schmidt-Vogt (1980),[34] for instance, found that whereas mortality among large outplants is greater than among small in the year of planting, mortality in subsequent growing seasons is higher among small outplants than among large. Much of the literature on comparative seedling performance is clouded by uncertainty as to whether the stocks being compared share the same physiological condition; differences invalidate such comparisons.[35]

Height and root-collar diameter are generally accepted as the most useful morphological criteria[36] and are often the only ones used in specifying standards. Quantification of root system morphology is difficult but can be done, e.g. by using the photometric rhizometer to determine intercept area,[37] or volume by displacement or gravimetric methods.[38]

Planting stock is always subject to a variety of conditions that are never optimal in toto. The effect of sub-optimal conditions is to induce stress in the plants. The nursery manager aims, and is normally able to avoid stresses greater than moderate, i.e., restricting stresses to levels that can be tolerated by the plants without incurring serious damage. The adoption of nursery regimes to equip planting stock with characteristics conferring increased ability to withstand outplanting stresses, by managing stress levels in the nursery to "condition" planting stock to increase tolerance to various post-planting environmental stresses, has become widespread, particularly with containerized stock.

Outplanted stock that is unable to tolerate high temperatures occurring at soil surfaces will fail to establish on many forest sites, even in the far north.[39] Factors affecting heat tolerance were investigated by Colombo et al. (1995);[40] the production and roles of heat shock proteins (HSPs) are important in this regard. HSPs, present constitutively in black spruce and many other, perhaps most, higher plants[40][41][42][43] are important both for normal cell functioning and in a stress response mechanism following exposure to high, non-lethal temperature. In black spruce at least, there is an association between HSPs and increased levels of heat tolerance.[44][45] Investigation of the diurnal variability in heat tolerance of roots and shoots in black spruce seedlings 14 to 16 weeks old found in all 4 trials that shoot heat tolerance was significantly greater in the afternoon than in the morning.[40] The trend in root heat tolerance was similar to that found in the shoots; root systems exposed to 47 °C for 15 minutes in the afternoon averaged 75 new roots after a 2-week growth period, whereas only 28 new roots developed in root systems similarly exposed in the morning. HSP73 was detected in black spruce nuclear, mitochondrial, microsomal, and soluble protein fractions, while HSP72 was observed only in the soluble protein fraction. Seedlings exhibited constitutive synthesis of HSP73 at 26 °C in all except the nuclear membrane fraction in the morning; HSP levels at 26 °C in the afternoon were higher than in the morning in the mitochondrial and microsomal protein factions. Heat shock affected the abundance of HSPs depending on protein fraction and time of day. Without heat shock, nuclear membrane-bound HSP73 was absent from plants in the morning and only weakly present in the afternoon, and heat shock increased the abundance of nuclear membrane. Heat shock also affected the abundance of HSP73 in the afternoon, and caused HSP73 to appear in the morning. In the mitochondrial and microsomal protein fractions, an afternoon heat shock reduced HSP73, whereas a morning heat shock increased HSP73 in the mitochondrial but decreased it in the microsomal fraction. Heat shock increased soluble HSP72/73 levels in both the morning and afternoon. In all instances, shoot and root heat tolerances were significantly greater in the afternoon than in the morning.

Planting stock continues to respire during storage even if frozen.[46] Temperature is the major factor controlling the rate, and care must be taken to avoid overheating. Navratil (1982)[46] found that closed containers in cold storage averaged internal temperatures 1.5 °C to 2.0 °C above the nominal storage temperature. Depletion of reserves can be estimated from the decrease in dry weight. Cold-stored 3+0 white spruce nursery stock in northern Ontario had lost 9% to 16% of dry weight after 40 days of storage.[46] Carbohydrates can also be determined directly.

The propensity of a root system to develop new roots or extend existing roots cannot be determined by eye, yet it is the factor that makes or breaks the outcome of an outplanting operation. The post-planting development of roots or root systems of coniferous planting stock is determined by many factors, some physiological, some environmental.[47] Unsatisfactory rates of post-planting survival unrelated to the morphology of the stock, led to attempts to test the physiological condition of planting stock, particularly to quantify the propensity to produce new root growth. New root growth can be assumed to be necessary for successful establishment of stock after planting, but although the thesis that RGC is positively related to field performance would seem to be reasonable, supporting evidence has been meager.

The physiological condition of seedlings is reflected by changes in root activity. This is helpful in determining the readiness of stock for lifting and storing and also for outplanting after storage. Navratil (1982)[46] reported a virtually perfect (R² = 0.99) linear relationship in the frequency of 3+0 white spruce white root tips longer than 10 mm with time in the fall at Pine Ridge Forest Nursery, Alberta, decreasing during a 3-week period to zero on October 13 in 1982.Root regenerating research with white spruce in Canada (Hambly 1973, Day and MacGillivray 1975, Day and Breunig 1997)[48][49][50] followed similar lines to that of Stone's (1955)[51] pioneering work in California.

Simpson and Ritchie (1997)[52] debated the proposition that root growth potential of planting stock predicts field performance; their conclusion was that root growth potential, as a surrogate for seedling vigor, can predict field performance, but only under such situations as site conditions permit. Survival after planting is only partly a function of an outplant's ability to initiate roots in test conditions; root growth capacity is not the sole predictor of plantation performance.[53]

Some major problems militate against greater use of RGC in forestry, including: unstandardized techniques; unstandardized quantification; uncertain correlation between quantified RGC and field performance; variability within given, nominally identical, kinds of planting stock; and the irrelevance of RGC test values determined on a sub-sample of a parent population that subsequently, before it is planted, undergoes any substantive physiological or physical change. In its present form, RGC testing is silviculturally useful chiefly as a means of detecting planting stock that, while visually unimpaired, is moribund.[54]

Seedling moisture content can be increased or decreased in storage, depending on various factors including especially the type of container and the kind and amount of moisture-retaining material present. When seedlings exceed 20 bars PMS in storage, survival after outplanting becomes problematical. The Relative Moisture Content of stock lifted during dry conditions can be increased gradually when stored in appropriate conditions. White spruce (3+0) packed in Kraft bags in northern Ontario increased RMC by 20% to 36% within 40 days.[46]

Bareroot 1.5+1.5 white spruce were taken from cold storage and planted early in May on a clear-felled boreal forest site in northeastern Ontario.[55] Similar plants were potted and kept in a greenhouse. In outplanted trees, maximum stomatal conductances (g) were initially low (<0.01 cm/s), and initial base xylem pressure potentials (PSIb) were -2.0 MPa. During the growing season, g increased to about 0.20 cm/s and PSIb to -1.0 MPa. Minimum xylem pressure potential (PSIm) was initially -2.5 MPa, increasing to -2.0 MPa on day 40, and about -1.6 MPa by day 110. During the first half of the growing season, PSIm was below turgor loss point. The osmotic potential at turgor loss point decreased after planting to -2.3 MPa 28 days later. In the greenhouse, minimum values of PSIT were -2.5 MPa (in the first day after planting. the maximum bulk modulus of elasticity was greater in white spruce than in similarly treated jack pine and showed greater seasonal changes. Relative water content (RWC) at turgor loss was 80-87%. Available turgor (TA), defined as the integral of turgor over the range of RWC between PSIb and xylem pressure potential at the turgor loss point) was 4.0% for white spruce at the beginning of the season compared with 7.9% for jack pine, but for the rest of the season TA for jack pine was only 2%, to 3% that of white spruce. Diurnal turgor (Td), the integral of turgor over the range of RWC between PSIb and PSIm, as a percentage of TA was higher in field-planted white spruce than jack pine until the end of the season.

The stomata of both white and black spruce were more sensitive to atmospheric evaporative demands and plant moisture stress during the first growing season after outplanting on 2 boreal sites in northern Ontario than were jack pine stomata,[56] physiological differences that favoured growth and establishment being more in jack pine than in the spruces.

With black spruce and jack pine, but not with white spruce, Grossnickle and Blake's (1987)[57] findings warrant mention in relation to the bareroot-containerized debate. During the first growing season after outplanting, containerized seedlings of both species had greater needle conductance than bareroot seedlings over a range of absolute humidity deficits. Needle conductance of containerized seedlings of both species remained high during periods of high absolute humidity deficits and increasing plant moisture stress. Bareroot outplants of both species had a greater early season resistance to water-flow through the soil–plant–atmosphere continuum (SPAC) than had containerized outplants. Resistance to water flow through the SPAC decreased in bareroot stock of both species as the season progressed, and was comparable to containerized seedlings 9 to 14 weeks after planting. Bareroot black spruce had greater new-root development than containerized stock throughout the growing season.

The greater efficiency of water use in newly transplanted 3-year-old white spruce seedlings under low levels of absolute humidity difference in water-stressed plants immediately after planting[58] helps explain the commonly observed favourable response of young outplants to the nursing effect of a partial canopy. Silvicultural treatments promoting higher humidity levels at the planting microsite should improve white spruce seedling photosynthesis immediately after planting.[58]

Stock types (Seedling nomenclature) edit

Planting stock is grown under many diverse nursery culture regimes, in facilities ranging from sophisticated computerized greenhouses to open compounds. Types of stock include bareroot seedlings and transplants, and various kinds of containerized stock. For simplicity, both container-grown and bareroot stock are generally referred to as seedlings, and transplants are nursery stock that have been lifted and transplanted into another nursery bed, usually at wider spacing. The size and physiological character of stock vary with the length of growing period and with growing conditions. Until the technology of raising containerized nursery stock bourgeoned in the second half of the twentieth- century, bareroot planting stock classified by its age in years was the norm.

Classification by age edit

The number of years spent in the nursery seedbed by any particular lot of planting stock is indicated by the 1st of a series of numbers. The 2nd number indicates the years subsequently spent in the transplant line, and a zero is shown if indeed there has been no transplanting. A 3rd number, if any, would indicate the years subsequently spent after a second lifting and transplanting. The numbers are sometimes separated by dashes, but separation by plus sign is more logical inasmuch as the sum of the individual numbers gives the age of the planting stock. Thus 2+0 is 2-year-old seedling planting stock that has not been transplanted, and Candy's (1929)[59] white spruce 2+2+3 stock had spent 2 years in the seedbed, 2 years in transplant lines, and another 3 years in transplant lines after a second transplanting. Variations have included such self-explanatory combinations, such as 1½+1½, etc.

The class of planting stock to use on a particular site is generally selected on the basis of historical record of survival, growth, and total cost of surviving trees.[60] In the Lake States, Kittredge[61] concluded that good stock of 2+1 white spruce was the smallest size likely to succeed and was better than larger and more expensive stock when judged by final cost of surviving trees.

Classification by seedling description code edit

Because age alone is an inadequate descriptor of planting stock, various codes have been developed to describe such components of stock characteristics as height, stem diameter, and shoot:root ratio.[62] A description code may include an indication of the intended planting season.

Physiological characteristics edit

Neither age classification nor seedling description code indicate the physiological condition of planting stock, though rigid adherence to a given cultural regime together with observation of performance over a number of years of planting can produce stock suitable for performing on a "same again" basis.

Classification by Production System edit

Nursery plant material is sold using a variety of systems. The most common systems for woody plants are bare root, containers, [63] and ball & burlap. [64] There are manuals specifically for the production of bare root[65] and containerized crops[66] In North America, the American Standard for Nursery Stock (ANSI Z.60.1) [67] and the Canadian nursery stock standard set specifications that determine what category of size a nursery plant material belongs.[68] The categories relate to size of the plant, plant calliper and` height ratio, and the size of the root ball. [69]

If plant stock is grown in a pot of any size or material, it is considered container grown plant stock. [70] the benefits of using the system of container grown plant stock include the convenience of being able to maintain and transport the plant stock (find citation). However, container grown plant stock will develop poor root structure when the roots hit the side of the container and begin to circle. When the roots circle the pot, the plant is considered root bound. [71] Container grown plant stock may be grown to size in the field and transplanted into a container, or grown in a container until marketable size [72] if grown in container rather than a field, continual upsizing of pots will be important for preventing the plant becoming root bound.[73] Some ways to prevent a crop from becoming root bound is by using air-pruning containers, which have spaces around the pot that expose growing media and roots to air. [74] The air will stop the root tip from growing and circling the pot. [75] Nurseries will also mechanically prune roots with "U" shaped or linear blades that are connected to tractors.[76] Container production can be used for any plant species.[77]

If a nursery plant is sold as "bare root", it means that soil has been removed from the roots, the product being sold is just the plant.[78] Plants sold as bare root are marketed in the winter,[79] to sell to customers in spring. Plants sold as bare root include herbaceous and woody perennial plants. [80] Bare root plants are grown in the field during the growing season until they become a harvestable bare root crop. [81] During dormancy, bare root plants are dug up, bundled, stored in a cool warehouse with roots in a moist media, they will be sold, [82] transplanted back into the field in spring, or disposed of if there is not enough space in the field. The issue of being root bound is non existent for bare root plants because there is no container for the roots to circle around, bare root nursery stock has the standard of being free of root deformities, and being free of pests. [83]

If a plant is ball and burlapped, it means the nursery dug around the plant with its soil while it's in the field and wrapped it in burlap which they tie down with rope. Nurseries may also use wire baskets to support the ball and burlap trees if needed.[84] Ball and burlap trees loose close to 90% of their root systems when dug[85] The size of the root ball of a ball and burlap tree depends on the calliper of the tree, and the species of the tree. [86] Root balls must have the depth to keep most of the plant root system and also be deep enough to keep plant root ball intact while the plant is being moved or planted.

There are terms used to identify the stage that the nursery plants are at. Liners are young plants that are one or two years old. They may be sold as bare root or in containers. [87] A whip is a tree with just a trunk and little to no branches. Whips can be grown from hardwood cuttings, seedlings, or propagated by budding, which is a method of grafting propagation where a single bud of a desired cultivar is grafted onto a rootstock plant.[88] In the case of budding, the rootstock will be older than the crown.[89]

See also edit

References edit

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  2. ^ McDaniel, Gary L. (1982). Ornamental Horticulture. Reston Publishing Company. p. 346. ISBN 978-0-8359-5348-1.
  3. ^ Kumar, Rohit (31 January 2024). "Nursery". britannica. Retrieved 31 January 2024.
  4. ^ Maiti, Ratikanta; Rodríguez, Humberto González; Thakur, Ashok Kumar; Sarkar, Narayan Chandra (14 August 2017). APPLIED BOTANY. American Academic Press. ISBN 978-1-63181-866-0.
  5. ^ Reid, Robert L. (22 October 2013). The Manual of Australian Agriculture. Elsevier. ISBN 978-1-4831-0034-0.
  6. ^ "The Reforestation Pipeline". American Forests. Retrieved 16 March 2022.
  7. ^ Buse, L.J.; Day, R.J. 1989. Conditioning three boreal conifers by root pruning and wrenching. USDA, For. Serv., Tree Plant. Notes 40(2):33–39.
  8. ^ Siminovitch, D. 1963. Evidence from increase in ribonucleic acid and protein synthesis in autumn for increase in proto plasm during frost hardening of black locust bark cells. Can. J. Bot. 41:1301–1308.
  9. ^ Timmis, R.; Worrall, J. 1975. Environmental control of cold acclimation in douglas-fir during germination, active growth, and rest. Can. J. For. Res. 5:464–477.
  10. ^ Colombo, S.J.; Hickie, D.F. 1987. A one-day test for determining frost hardiness using the electrical conductivity technique. Ont. Min. Nat. Resour., For. Res. Note 45. 4 p.
  11. ^ Colombo, S.J. 1997. The role of operational frost hardiness testing in the development of container stock hardening regimes in Ontario. New. For. 13:449–467.
  12. ^ Ritchie, G.A. 1982. Carbohydrate reserves and root growth potential in Douglas-fir seedlings before and after cold storage. Can. J. For. Res. 12:905–912.
  13. ^ Armson, K.A.; Carman, R.D. 1961. Forest tree nursery soil management. Ont. Dep. Lands & Forests, Timber Branch, Ottawa ON. 74 p.
  14. ^ Armson, K.A. 1966. The growth and absorption of nutrients by fertilized and unfertilized white spruce seedlings. For. Chron. 42(2):127–136.
  15. ^ Stiell, W.M. 1976. White spruce: artificial regeneration in Canada. Dep. Environ., Can. For. Serv., Ottawa ON, Inf. Rep. FMR-X-85. 275 p.
  16. ^ Duryea, M.L.; McClain, K.M. 1984. Altering seedling physiology to improve reforestation success. pp. 77–114 in M.L. Dryea and G.N. Brown (eds.). Seedling physiology and reforestation success. Martinus Nijhoff/Dr. W. Junk, The Hague.
  17. ^ Armson, K.A.; Sadreika, V. 1979. Forest tree nursery soil management and related practices – metric edition. Ont. Min. Nat. Resour., Div. For. For. Manage. Branch, Toronto ON. 179 p.
  18. ^ van den Driessche, R. 1980. (E.P. 640.66), Growth of Douglas-fir and white spruce seedlings treated with slow release fertilizers in the nursery. B.C. Min. For., Victoria BC, Res. Memo 39. 2 p.
  19. ^ Dobbs, R.C. 1976. Effect of initial mass of white spruce and lodgepole pine planting stock on field performance in the British Columbia Interior. Can. Dep. Environ., Can. For. Serv., Victoria BC, Inf. Rep. BC-X-149. 14 p.
  20. ^ a b McMinn, R.G. 1985a. Effect of initial mass on the field performance of white spruce planting stock. Can. For. Serv., Victoria BC, File Rep. PC 48-357, Exp. 72-F2. 5 p.
  21. ^ McMinn, R.G. 1980. Root growth capacity and field performance of various types and sizes of white spruce stock following outplanting in the central interior of British Columbia. p. 37–41 in Schmidt-Vogt, H. (Ed.). Characterization of Plant Material. Proc. IUFRO Working Group S1.05-04 Meet., Waldbau-Institut, Univ. Freiburg, Germany.
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February 16, 2024
plant, nursery, other, uses, nursery, nursery, disambiguation, this, article, needs, additional, citations, verification, please, help, improve, this, article, adding, citations, reliable, sources, unsourced, material, challenged, removed, find, sources, news,. For other uses of Nursery see Nursery disambiguation This article needs additional citations for verification Please help improve this article by adding citations to reliable sources Unsourced material may be challenged and removed Find sources Plant nursery news newspapers books scholar JSTOR December 2014 Learn how and when to remove this template message A nursery is a place where plants are propagated and grown to a desired size Mostly the plants concerned are for gardening forestry or conservation biology rather than agriculture They include retail nurseries which sell to the general public wholesale nurseries which sell only to businesses such as other nurseries and commercial gardeners and private nurseries which supply the needs of institutions or private estates Some will also work in plant breeding Plants in a nurseryA nurseryman is a person who owns or works in a nursery 1 Some nurseries specialize in certain areas which may include propagation and the selling of small or bare root plants to other nurseries growing out plant materials to a saleable size or retail sales 2 Nurseries may also specialize in one type of plant e g groundcovers shade plants or rock garden plants Some produce bulk stock whether seedlings or grafted trees of particular varieties for purposes such as fruit trees for orchards or timber trees for forestry Some producers produce stock seasonally ready in the spring for export to colder regions where propagation could not have been started so early or to regions where seasonal pests prevent profitable growing early in the season Contents 1 Nurseries 2 Methods 3 Conditioning 3 1 Hardening off frost hardiness 4 Forest tree nurseries 4 1 Stock types sizes and lots 4 2 Planting stock 4 3 Stock types Seedling nomenclature 4 4 Classification by age 4 5 Classification by seedling description code 4 6 Physiological characteristics 4 7 Classification by Production System 5 See also 6 References 7 External linksNurseries editThere are a number of different types of nurseries broadly grouped as wholesale or retail nurseries with some overlap depending on the specific operation Wholesale nurseries produce plants in large quantities which are sold to retail nurseries 3 encyclopedia 4 Wholesale nurseries may be small operations that produce a specific type of plant using a small area of land or very larger operations covering many acres They propagate plant material or buy plants from other nurseries which may include rooted or unrooted cuttings or small rooted plants called plugs or field grown bare root plants which are planted and grown to a desired size Some wholesale nurseries produce plants on contract for others which place an order for a specific number and size of plant while others produce a wide range of plants that are offered for sale to other nurseries and landscapers and sold as first come first served Retail nurseries sell plants ready to be placed in the landscape or used in homes and businessesMethods edit nbsp A small nursery filled with orchid plants in bloom nbsp A tree nursery using gutters to decrease growing costsPropagation Nurseries produce new plants from seeds cuttings tissue culture grafting or division The plants are then grown out to a salable size and either sold to other nurseries that may continue to grow the plants out in larger containers or field grow them to desired size Propagation nurseries may also sell plant material large enough for retail sales and thus sale directly to retail nurseries or garden centers which rarely propagated their own plants 5 Nurseries may produce plants for reforestation zoos parks and cities With Tree nurseries in the U S producing around 1 3 billion seedlings per year for reforestation 6 Nurseries grow plants in open fields on container fields in tunnels or greenhouses In open fields nurseries grow decorative trees shrubs and herbaceous perennials On a containerfield nurseries grow small trees shrubs and herbaceous plants usually destined for sales in garden centers These have proper ventilation sunlight etc Plants may be grown by seeds but the most common method is by planting cuttings which can be taken from shoot tips or roots Conditioning editWith the objective of fitting planting stock more able to withstand stresses after outplanting various nursery treatments have been attempted or developed and applied to nursery stock Buse and Day 1989 7 for instance studied the effect of conditioning of white spruce and black spruce transplants on their morphology physiology and subsequent performance after outplanting Root pruning wrenching and fertilization with potassium at 375 kg ha were the treatments applied Root pruning and wrenching modified stock in the nursery by decreasing height root collar diameter shoot root ratio and bud size but did not improve survival or growth after planting Fertilization reduced root growth in black spruce but not of white spruce Hardening off frost hardiness edit Seedlings vary in their susceptibility to injury from frost Damage can be catastrophic if unhardened seedlings are exposed to frost Frost hardiness may be defined as the minimum temperature at which a certain percentage of a random seedling population will survive or will sustain a given level of damage Siminovitch 1963 Timmis and Worrall 1975 8 9 The term LT50 lethal temperature for 50 of a population is commonly used Determination of frost hardiness in Ontario is based on electrolyte leakage from mainstem terminal tips 2 cm to 3 cm long in weekly samplings Colombo and Hickie 1987 10 The tips are frozen then thawed immersed in distilled water the electrical conductivity of which depends on the degree to which cell membranes have been ruptured by freezing releasing electrolyte A 15 C frost hardiness level has been used to determine the readiness of container stock to be moved outside from the greenhouse and 40 C has been the level determining readiness for frozen storage Colombo 1997 11 In an earlier technique potted seedlings were placed in a freezer chest and cooled to some level for some specific duration a few days after removal seedlings were assessed for damage using various criteria including odour general visual appearance and examination of cambial tissue Ritchie 1982 12 Stock for fall planting must be properly hardened off Conifer seedlings are considered to be hardened off when the terminal buds have formed and the stem and root tissues have ceased growth Other characteristics that in some species indicate dormancy are color and stiffness of the needles but these are not apparent in white spruce Forest tree nurseries editWhether in the forest or in the nursery seedling growth is fundamentally influenced by soil fertility but nursery soil fertility is readily amenable to amelioration much more so than is forest soil Nitrogen phosphorus and potassium are regularly supplied as fertilizers and calcium and magnesium are supplied occasionally Applications of fertilizer nitrogen do not build up in the soil to develop any appreciable storehouse of available nitrogen for future crops 13 Phosphorus and potassium however can be accumulated as a storehouse available for extended periods Fertilization permits seedling growth to continue longer through the growing season than unfertilized stock fertilized white spruce attained twice the height of unfertilized 14 High fertility in the rooting medium favours shoot growth over root growth and can produce top heavy seedlings ill suited to the rigors of the outplant site Nutrients in oversupply can reduce growth 15 16 or the uptake of other nutrients 17 As well an excess of nutrient ions can prolong or weaken growth to interfere with the necessary development of dormancy and hardening of tissues in time to withstand winter weather 18 Stock types sizes and lots edit Nursery stock size typically follows the normal curve when lifted for planting stock The runts at the lower end of the scale are usually culled to an arbitrary limit but especially among bareroot stock the range in size is commonly considerable Dobbs 1976 19 and McMinn 1985a 20 examined how the performance of 2 0 bareroot white spruce related to differences in initial size of planting stock The stock was regraded into large medium and small fractions according to fresh weight The small fraction 20 of the original stock had barely one quarter of the dry matter mass of the large fraction at the time of outplanting Ten years later in the blade scarified site seedlings of the large fraction had almost 50 greater stem volume than had seedlings of the small fraction Without site preparation large stock were more than twice the size of small stock after 10 years nbsp Nursery of apricot seedlingsSimilar results were obtained with regraded 2 1 transplants sampled to determine root growth capacity 21 22 The large stock had higher RGC as well as greater mass than the small stock fraction The value of large size at the time of planting is especially apparent when outplants face strong competition from other vegetation although high initial mass does not guarantee success That the growth potential of planting stock depends on much more than size seems clear from the indifferent success of the transplanting of small 2 0 seedlings for use as 2 1 reclaim transplants 20 The size of bareroot white spruce seedlings and transplants also had a major influence on field performance The field performance among various stock types in Ontario plantations was examined by Paterson and Hutchison 1989 23 the white spruce stock types were 2 0 1 5 0 5 1 5 1 5 and 3 0 The nursery stock was grown at Midhurst Forest Tree Nursery and carefully handled through lifting on 3 lift dates packing and hot planting into cultivated weed free loam After 7 years overall survival was 97 with no significant differences in survival among stock types The 1 5 1 5 stock with a mean height of 234 cm was significantly taller by 18 to 25 than the other stock types The 1 5 1 5 stock also had significantly greater dbh than the other stock types by 30 43 The best stock type was 57 cm taller and 1 cm greater in dbh than the poorest Lifting date had no significant effect on growth or survival High elevation sites in British Columbia s southern mountains are characterized by a short growing season low air and soil temperatures severe winters and deep snow The survival and growth of Engelmann spruce and subalpine fir outplanted in 3 silvicultural trials on such sites in gaps of various sizes were compared by Lajzerowicz et al 2006 24 Survival after 5 or 6 years decreased with smaller gaps Height and diameter also decreased with decreasing size of gap mean heights were 50 cm to 78 cm after 6 years in line with height expectations for Engelmann spruce in a high elevation planting study in southeastern British Columbia 25 In the larger gaps 1 0 ha height increment by year 6 was ranging from 10 cm to 20 cm Lajzerrowicz et al Concluded that plantings of conifers in clearcuts at high elevations in the southern mountains of British Columbia are likely to be successful even close to timberline and group selection silvicultural systems based on gaps 0 1 ha or larger are also likely to succeed Gaps smaller than 0 1 ha do not provide suitable conditions for obtaining adequate survival or for growth of outplanted conifers Planting stock edit Planting stock seedlings transplants cuttings and occasionally wildings for use in planting out 26 is nursery stock that has been made ready for outplanting The amount of seed used in white spruce seedling production and direct seeding varies with method A working definition of planting stock quality was accepted at the 1979 IUFRO Workshop on Techniques for Evaluating Planting Stock Quality in New Zealand The quality of planting stock is the degree to which that stock realizes the objectives of management to the end of the rotation or achievement of specified sought benefits at minimum cost Quality is fitness for purpose 27 Clear expression of objectives is therefore prerequisite to any determination of planting stock quality 28 Not only does performance have to be determined but performance has to be rated against the objectives of management 29 Planting stock is produced in order to give effect to the forest policy of the organization A distinction needs to be made between planting stock quality and planting stock performance potential PSPP The actual performance of any given batch of outplanted planting stock is determined only in part by the kind and condition i e the intrinsic PSPP of the planting stock The PSPP is impossible to estimate reliably by eye because outward appearance especially of stock withdrawn from refrigerated storage can deceive even experienced foresters who would be offended if their ability were questioned to recognize good planting stock when they saw it Prior to Wakeley s 1954 30 demonstration of the importance of the physiological state of planting stock in determining the ability of the stock to perform after outplanting and to a considerable extent even afterwards morphological appearance has generally served as the basis for estimating the quality of planting stock Gradually however a realization developed that more was involved Tucker et al 1968 31 for instance after assessing 10 year survival data from several experimental white spruce plantations in Manitoba noted that Perhaps the most important point revealed here is that certain lots of transplants performed better than others even though all transplants were handled and planted with care The intuitive stock that looks good must be good is a persuasive but potentially dangerous maxim That greatest of teachers Bitter Experience has often enough demonstrated the fallibility of such assessment even though the corollary stock that looks bad must be bad is likely to be well founded The physiological qualities of planting stock are hidden from the eye and must be revealed by testing The potential for survival and growth of a batch of planting stock may be estimated from various features morphological and physiological of the stock or a sample thereof The size and shape and general appearance of a seedling can nevertheless give useful indications of PSPP In low stress outplanting situations and with a minimized handling and lifting planting cycle a system based on specification for nursery stock and minimum morphological standards for acceptable seedlings works tolerably well 32 In certain circumstances benefits often accrue from the use of large planting stock of highly ranked morphological grades Length of leading shoot diameter of stem volume of root system shoot root ratios and height diameter ratios have been correlated with performance under specific site and planting conditions 33 However the concept that larger is better negates the underlying complexities Schmidt Vogt 1980 34 for instance found that whereas mortality among large outplants is greater than among small in the year of planting mortality in subsequent growing seasons is higher among small outplants than among large Much of the literature on comparative seedling performance is clouded by uncertainty as to whether the stocks being compared share the same physiological condition differences invalidate such comparisons 35 Height and root collar diameter are generally accepted as the most useful morphological criteria 36 and are often the only ones used in specifying standards Quantification of root system morphology is difficult but can be done e g by using the photometric rhizometer to determine intercept area 37 or volume by displacement or gravimetric methods 38 Planting stock is always subject to a variety of conditions that are never optimal in toto The effect of sub optimal conditions is to induce stress in the plants The nursery manager aims and is normally able to avoid stresses greater than moderate i e restricting stresses to levels that can be tolerated by the plants without incurring serious damage The adoption of nursery regimes to equip planting stock with characteristics conferring increased ability to withstand outplanting stresses by managing stress levels in the nursery to condition planting stock to increase tolerance to various post planting environmental stresses has become widespread particularly with containerized stock Outplanted stock that is unable to tolerate high temperatures occurring at soil surfaces will fail to establish on many forest sites even in the far north 39 Factors affecting heat tolerance were investigated by Colombo et al 1995 40 the production and roles of heat shock proteins HSPs are important in this regard HSPs present constitutively in black spruce and many other perhaps most higher plants 40 41 42 43 are important both for normal cell functioning and in a stress response mechanism following exposure to high non lethal temperature In black spruce at least there is an association between HSPs and increased levels of heat tolerance 44 45 Investigation of the diurnal variability in heat tolerance of roots and shoots in black spruce seedlings 14 to 16 weeks old found in all 4 trials that shoot heat tolerance was significantly greater in the afternoon than in the morning 40 The trend in root heat tolerance was similar to that found in the shoots root systems exposed to 47 C for 15 minutes in the afternoon averaged 75 new roots after a 2 week growth period whereas only 28 new roots developed in root systems similarly exposed in the morning HSP73 was detected in black spruce nuclear mitochondrial microsomal and soluble protein fractions while HSP72 was observed only in the soluble protein fraction Seedlings exhibited constitutive synthesis of HSP73 at 26 C in all except the nuclear membrane fraction in the morning HSP levels at 26 C in the afternoon were higher than in the morning in the mitochondrial and microsomal protein factions Heat shock affected the abundance of HSPs depending on protein fraction and time of day Without heat shock nuclear membrane bound HSP73 was absent from plants in the morning and only weakly present in the afternoon and heat shock increased the abundance of nuclear membrane Heat shock also affected the abundance of HSP73 in the afternoon and caused HSP73 to appear in the morning In the mitochondrial and microsomal protein fractions an afternoon heat shock reduced HSP73 whereas a morning heat shock increased HSP73 in the mitochondrial but decreased it in the microsomal fraction Heat shock increased soluble HSP72 73 levels in both the morning and afternoon In all instances shoot and root heat tolerances were significantly greater in the afternoon than in the morning Planting stock continues to respire during storage even if frozen 46 Temperature is the major factor controlling the rate and care must be taken to avoid overheating Navratil 1982 46 found that closed containers in cold storage averaged internal temperatures 1 5 C to 2 0 C above the nominal storage temperature Depletion of reserves can be estimated from the decrease in dry weight Cold stored 3 0 white spruce nursery stock in northern Ontario had lost 9 to 16 of dry weight after 40 days of storage 46 Carbohydrates can also be determined directly The propensity of a root system to develop new roots or extend existing roots cannot be determined by eye yet it is the factor that makes or breaks the outcome of an outplanting operation The post planting development of roots or root systems of coniferous planting stock is determined by many factors some physiological some environmental 47 Unsatisfactory rates of post planting survival unrelated to the morphology of the stock led to attempts to test the physiological condition of planting stock particularly to quantify the propensity to produce new root growth New root growth can be assumed to be necessary for successful establishment of stock after planting but although the thesis that RGC is positively related to field performance would seem to be reasonable supporting evidence has been meager The physiological condition of seedlings is reflected by changes in root activity This is helpful in determining the readiness of stock for lifting and storing and also for outplanting after storage Navratil 1982 46 reported a virtually perfect R 0 99 linear relationship in the frequency of 3 0 white spruce white root tips longer than 10 mm with time in the fall at Pine Ridge Forest Nursery Alberta decreasing during a 3 week period to zero on October 13 in 1982 Root regenerating research with white spruce in Canada Hambly 1973 Day and MacGillivray 1975 Day and Breunig 1997 48 49 50 followed similar lines to that of Stone s 1955 51 pioneering work in California Simpson and Ritchie 1997 52 debated the proposition that root growth potential of planting stock predicts field performance their conclusion was that root growth potential as a surrogate for seedling vigor can predict field performance but only under such situations as site conditions permit Survival after planting is only partly a function of an outplant s ability to initiate roots in test conditions root growth capacity is not the sole predictor of plantation performance 53 Some major problems militate against greater use of RGC in forestry including unstandardized techniques unstandardized quantification uncertain correlation between quantified RGC and field performance variability within given nominally identical kinds of planting stock and the irrelevance of RGC test values determined on a sub sample of a parent population that subsequently before it is planted undergoes any substantive physiological or physical change In its present form RGC testing is silviculturally useful chiefly as a means of detecting planting stock that while visually unimpaired is moribund 54 Seedling moisture content can be increased or decreased in storage depending on various factors including especially the type of container and the kind and amount of moisture retaining material present When seedlings exceed 20 bars PMS in storage survival after outplanting becomes problematical The Relative Moisture Content of stock lifted during dry conditions can be increased gradually when stored in appropriate conditions White spruce 3 0 packed in Kraft bags in northern Ontario increased RMC by 20 to 36 within 40 days 46 Bareroot 1 5 1 5 white spruce were taken from cold storage and planted early in May on a clear felled boreal forest site in northeastern Ontario 55 Similar plants were potted and kept in a greenhouse In outplanted trees maximum stomatal conductances g were initially low lt 0 01 cm s and initial base xylem pressure potentials PSIb were 2 0 MPa During the growing season g increased to about 0 20 cm s and PSIb to 1 0 MPa Minimum xylem pressure potential PSIm was initially 2 5 MPa increasing to 2 0 MPa on day 40 and about 1 6 MPa by day 110 During the first half of the growing season PSIm was below turgor loss point The osmotic potential at turgor loss point decreased after planting to 2 3 MPa 28 days later In the greenhouse minimum values of PSIT were 2 5 MPa in the first day after planting the maximum bulk modulus of elasticity was greater in white spruce than in similarly treated jack pine and showed greater seasonal changes Relative water content RWC at turgor loss was 80 87 Available turgor TA defined as the integral of turgor over the range of RWC between PSIb and xylem pressure potential at the turgor loss point was 4 0 for white spruce at the beginning of the season compared with 7 9 for jack pine but for the rest of the season TA for jack pine was only 2 to 3 that of white spruce Diurnal turgor Td the integral of turgor over the range of RWC between PSIb and PSIm as a percentage of TA was higher in field planted white spruce than jack pine until the end of the season The stomata of both white and black spruce were more sensitive to atmospheric evaporative demands and plant moisture stress during the first growing season after outplanting on 2 boreal sites in northern Ontario than were jack pine stomata 56 physiological differences that favoured growth and establishment being more in jack pine than in the spruces With black spruce and jack pine but not with white spruce Grossnickle and Blake s 1987 57 findings warrant mention in relation to the bareroot containerized debate During the first growing season after outplanting containerized seedlings of both species had greater needle conductance than bareroot seedlings over a range of absolute humidity deficits Needle conductance of containerized seedlings of both species remained high during periods of high absolute humidity deficits and increasing plant moisture stress Bareroot outplants of both species had a greater early season resistance to water flow through the soil plant atmosphere continuum SPAC than had containerized outplants Resistance to water flow through the SPAC decreased in bareroot stock of both species as the season progressed and was comparable to containerized seedlings 9 to 14 weeks after planting Bareroot black spruce had greater new root development than containerized stock throughout the growing season The greater efficiency of water use in newly transplanted 3 year old white spruce seedlings under low levels of absolute humidity difference in water stressed plants immediately after planting 58 helps explain the commonly observed favourable response of young outplants to the nursing effect of a partial canopy Silvicultural treatments promoting higher humidity levels at the planting microsite should improve white spruce seedling photosynthesis immediately after planting 58 Stock types Seedling nomenclature edit Planting stock is grown under many diverse nursery culture regimes in facilities ranging from sophisticated computerized greenhouses to open compounds Types of stock include bareroot seedlings and transplants and various kinds of containerized stock For simplicity both container grown and bareroot stock are generally referred to as seedlings and transplants are nursery stock that have been lifted and transplanted into another nursery bed usually at wider spacing The size and physiological character of stock vary with the length of growing period and with growing conditions Until the technology of raising containerized nursery stock bourgeoned in the second half of the twentieth century bareroot planting stock classified by its age in years was the norm Classification by age edit The number of years spent in the nursery seedbed by any particular lot of planting stock is indicated by the 1st of a series of numbers The 2nd number indicates the years subsequently spent in the transplant line and a zero is shown if indeed there has been no transplanting A 3rd number if any would indicate the years subsequently spent after a second lifting and transplanting The numbers are sometimes separated by dashes but separation by plus sign is more logical inasmuch as the sum of the individual numbers gives the age of the planting stock Thus 2 0 is 2 year old seedling planting stock that has not been transplanted and Candy s 1929 59 white spruce 2 2 3 stock had spent 2 years in the seedbed 2 years in transplant lines and another 3 years in transplant lines after a second transplanting Variations have included such self explanatory combinations such as 1 1 etc The class of planting stock to use on a particular site is generally selected on the basis of historical record of survival growth and total cost of surviving trees 60 In the Lake States Kittredge 61 concluded that good stock of 2 1 white spruce was the smallest size likely to succeed and was better than larger and more expensive stock when judged by final cost of surviving trees Classification by seedling description code edit Because age alone is an inadequate descriptor of planting stock various codes have been developed to describe such components of stock characteristics as height stem diameter and shoot root ratio 62 A description code may include an indication of the intended planting season Physiological characteristics edit Neither age classification nor seedling description code indicate the physiological condition of planting stock though rigid adherence to a given cultural regime together with observation of performance over a number of years of planting can produce stock suitable for performing on a same again basis Classification by Production System edit Nursery plant material is sold using a variety of systems The most common systems for woody plants are bare root containers 63 and ball amp burlap 64 There are manuals specifically for the production of bare root 65 and containerized crops 66 In North America the American Standard for Nursery Stock ANSI Z 60 1 67 and the Canadian nursery stock standard set specifications that determine what category of size a nursery plant material belongs 68 The categories relate to size of the plant plant calliper and height ratio and the size of the root ball 69 If plant stock is grown in a pot of any size or material it is considered container grown plant stock 70 the benefits of using the system of container grown plant stock include the convenience of being able to maintain and transport the plant stock find citation However container grown plant stock will develop poor root structure when the roots hit the side of the container and begin to circle When the roots circle the pot the plant is considered root bound 71 Container grown plant stock may be grown to size in the field and transplanted into a container or grown in a container until marketable size 72 if grown in container rather than a field continual upsizing of pots will be important for preventing the plant becoming root bound 73 Some ways to prevent a crop from becoming root bound is by using air pruning containers which have spaces around the pot that expose growing media and roots to air 74 The air will stop the root tip from growing and circling the pot 75 Nurseries will also mechanically prune roots with U shaped or linear blades that are connected to tractors 76 Container production can be used for any plant species 77 If a nursery plant is sold as bare root it means that soil has been removed from the roots the product being sold is just the plant 78 Plants sold as bare root are marketed in the winter 79 to sell to customers in spring Plants sold as bare root include herbaceous and woody perennial plants 80 Bare root plants are grown in the field during the growing season until they become a harvestable bare root crop 81 During dormancy bare root plants are dug up bundled stored in a cool warehouse with roots in a moist media they will be sold 82 transplanted back into the field in spring or disposed of if there is not enough space in the field The issue of being root bound is non existent for bare root plants because there is no container for the roots to circle around bare root nursery stock has the standard of being free of root deformities and being free of pests 83 If a plant is ball and burlapped it means the nursery dug around the plant with its soil while it s in the field and wrapped it in burlap which they tie down with rope Nurseries may also use wire baskets to support the ball and burlap trees if needed 84 Ball and burlap trees loose close to 90 of their root systems when dug 85 The size of the root ball of a ball and burlap tree depends on the calliper of the tree and the species of the tree 86 Root balls must have the depth to keep most of the plant root system and also be deep enough to keep plant root ball intact while the plant is being moved or planted There are terms used to identify the stage that the nursery plants are at Liners are young plants that are one or two years old They may be sold as bare root or in containers 87 A whip is a tree with just a trunk and little to no branches Whips can be grown from hardwood cuttings seedlings or propagated by budding which is a method of grafting propagation where a single bud of a desired cultivar is grafted onto a rootstock plant 88 In the case of budding the rootstock will be older than the crown 89 See also editSeed orchardReferences edit Dictionaries Oxford 10 May 2012 Paperback Oxford English Dictionary OUP Oxford ISBN 978 0 19 964094 2 McDaniel Gary L 1982 Ornamental Horticulture Reston Publishing Company p 346 ISBN 978 0 8359 5348 1 Kumar Rohit 31 January 2024 Nursery britannica Retrieved 31 January 2024 Maiti Ratikanta Rodriguez Humberto Gonzalez Thakur Ashok Kumar Sarkar Narayan Chandra 14 August 2017 APPLIED BOTANY American Academic Press ISBN 978 1 63181 866 0 Reid Robert L 22 October 2013 The Manual of Australian Agriculture Elsevier ISBN 978 1 4831 0034 0 The Reforestation Pipeline American Forests Retrieved 16 March 2022 Buse L J Day R J 1989 Conditioning three boreal conifers by root pruning and wrenching USDA For Serv Tree Plant Notes 40 2 33 39 Siminovitch D 1963 Evidence from increase in ribonucleic acid and protein synthesis in autumn for increase in proto plasm during frost hardening of black locust bark cells Can J Bot 41 1301 1308 Timmis R Worrall J 1975 Environmental control of cold acclimation in douglas fir during germination active growth and rest Can J For Res 5 464 477 Colombo S J Hickie D F 1987 A one day test for determining frost hardiness using the electrical conductivity technique Ont Min Nat Resour For Res Note 45 4 p Colombo S J 1997 The role of operational frost hardiness testing in the development of container stock hardening regimes in Ontario New For 13 449 467 Ritchie G A 1982 Carbohydrate reserves and root growth potential in Douglas fir seedlings before and after cold storage Can J For Res 12 905 912 Armson K A Carman R D 1961 Forest tree nursery soil management Ont Dep Lands amp Forests Timber Branch Ottawa ON 74 p Armson K A 1966 The growth and absorption of nutrients by fertilized and unfertilized white spruce seedlings For Chron 42 2 127 136 Stiell W M 1976 White spruce artificial regeneration in Canada Dep Environ Can For Serv Ottawa ON Inf Rep FMR X 85 275 p Duryea M L McClain K M 1984 Altering seedling physiology to improve reforestation success pp 77 114 in M L Dryea and G N Brown eds Seedling physiology and reforestation success Martinus Nijhoff Dr W Junk The Hague Armson K A Sadreika V 1979 Forest tree nursery soil management and related practices metric edition Ont Min Nat Resour Div For For Manage Branch Toronto ON 179 p van den Driessche R 1980 E P 640 66 Growth of Douglas fir and white spruce seedlings treated with slow release fertilizers in the nursery B C Min For Victoria BC Res Memo 39 2 p Dobbs R C 1976 Effect of initial mass of white spruce and lodgepole pine planting stock on field performance in the British Columbia Interior Can Dep Environ Can For Serv Victoria BC Inf Rep BC X 149 14 p a b McMinn R G 1985a Effect of initial mass on the field performance of white spruce planting stock Can For Serv Victoria BC File Rep PC 48 357 Exp 72 F2 5 p McMinn R G 1980 Root growth capacity and field performance of various types and sizes of white spruce stock following outplanting in the central interior of British Columbia p 37 41 in Schmidt Vogt H Ed Characterization of Plant Material Proc IUFRO Working Group S1 05 04 Meet Waldbau Institut Univ Freiburg Germany McMinn R G 1984 Field performance of various sizes of white spruce stock in recently cut and backlog sites Can For Serv Victoria BC File Rep PC 48 357 Exp 78 F1 4 p Paterson J M Hutchison R E 1989 Red pine white pine white spruce stock type comparisons Ont Min Nat Resour For Res Note 47 4 p Lajzerowicz C C Vyse A Jull M and Newsome T 2006 Performance of planted Engelmann spruce and subalpine fir seedlings in British Columbia s southern mountains For Chron 82 1 84 94 Thompson C 1995 Preliminary height expectations of Engelmann spruce plantations for three elevations in the Nelson Forest Region B C Min For Nelson For Region Res Sum RS 020 Cited by Lajzerowicz et al 2006 orig not seen Ford Robertson F C Ed 1971 Terminology of Forest Science Technology Practice and Products English language version Soc Amer For Washington DC 349 p Willen P Sutton R F 1980 Evaluation of planting stock quality Evaluation of stock after planting New Zealand J For Sci 10 297 299 Sutton R F 1982 Plantation establishment in the boreal forest planting season extension Can Dep Environ Can For Serv Sault Ste Marie ON Inf Rep O X 344 129 p Sutton R F 1987 Plantation establishment in boreal Ontario a study of spring planting and mechanization Gov t Can Can For Serv Sault Ste Marie ON Inf Rep O X 383 26 p Wakely P C 1954 Planting the southern pines USDA For Serv Monograph 18 233 p Tucker R E Jarvis J M Waldron R M 1968 Early survival and growth of white spruce plantations Riding Mountain National Park Manitoba Can Dep For Rural Devel For Branch Ottawa ON Publ 1239 26 p Sutton R F 1979 Plantation establishment in the boreal forest nutrient redistribution during mechanized planting Can Dep Environ Can For Serv Sault Ste Marie ON Inf Rep O X 303 16 p Cited in Coates et al 1994 Mullin R E Christl C 1981 Morphological grading of white spruce nursery stock For Chron 57 3 126 130 Cited in Coates et al 1994 Schmidt Vogt H Ed 1980 Characterization of plant material Proc IUFRO Meet Div 1 Freiburg Germany van den Driessche R 1976 How far do seedling standards reflect seedling quality p 50 52 in Proc XVI IUFRO World Congr Div II For Plants For Prot Oslo Norway Navratil S Brace L G Edwards I K 1986 Planting stock quality monitoring Canadian Forestry Service Northern Forestry Centre Edmonton Alberta NOR X 279 Morrison I K Armson K A 1968 The rhizometer a new device for measuring roots of tree seedlings For Chron 44 21 23 Burdett A N 1979 New methods for measuring root growth capacity their value in assessing lodgepole pine stock quality Can J For Res 9 63 67 Helgerson O T 1990 Heat damage in tree seedlings and its prevention New For 3 333 358 a b c Colombo S J Timmer V R Colclough M L Blumwald E 1995 Diurnal variation in heat tolerance and heat shock protein expression in black spruce Picea mariana Can J For Res 25 3 369 375 Key J L Lin C Y Chen Y M 1981 Heat shock proteins of higher plants Proc U S Acad Sci 78 3526 3530 Kimpel J A Key J L 1985a Heat chock in plants Trends Biochem Sci 10 353 357 Kimpel J A Key J L 1985b Presence of heat shock mRNAs in field grown soybeans Plant Physiol 79 672 678 Coclough M L 1991 The induction of thermotolerance and heat shock protein synthesis in Picea mariana seedlings by heat conditioning M Sc Thesis University of Toronto Toronto Ontario Colombo S J Colclough M L Timmer V R Blumwald E 1992 Clonal variation in heat tolerance and heat shock protein expression in black spruce Silvae Gent 41 234 239 a b c d e Navratil S 1982 Storaging of bare root planting stock Proc Fed Prov Nurserymen s Meet Smoky Lake AB Nov 1982 Alberta Energy amp Nat Resour 13 p Sutton R F 1990 Root growth capacity in coniferous forest trees HortSci 25 259 266 Hambly E S L 1973 The periodicity of root regeneration potential of black and white spruce and jack pine nursery seedlings M Sc thesis Univ Toronto Fac For Toronto ON 66 p Day R J MacGillivray G R 1975 Root regeneration of fall lifted white spruce nursery stock in relation to soil moisture content For Chron 51 196 199 Day R J Breunig E 1997 Root generation of 3 0 white spruce varies with root system size post planting moisture and climate B Sc F Thesis Lakehead University Thunder Bay Ontario 38 p Stone E C 1955 Poor survival and the physiological condition of planting stock For Sci 1 90 94 Simpson D G Ritchie G A 1997 Does RGP predict field performance A debate New For 13 253 277 Scagel C F Linderman R G 2001 Modification of root IAA concentrations tree growth and survival by application of plant growth regulating substances to container grown conifers New For 21 159 186 Sutton R F 1984 Plantation establishment in the boreal forest glyphosate hexazinone and manual weed control For Chron 60 282 287 Grossnickle S C 1988 Planting stress in newly planted jack pine and white spruce I Factors influencing water uptake Tree Physiol 4 1 71 84 Search 8 abstr 38 of 99 Grossnickle S C Blake T J 1986 Environmental and physiological control of needle conductance for bare root black spruce white spruce and jack pine seedlings on boreal cutover sites Can J Bot 64 5 943 949 Grossnickle S C Blake T J 1987 Water relation patterns of bare root and container jack pine and black spruce seedlings planted on boreal cut over sites New For 1 101 116 a b Marsden B J Lieffers V J and Zwiazek J J 1996 The effect of humidity on photosynthesis and water relations of white spruce seedlings during the early establishment phase Can J For Res 26 6 1015 1021 Candy R H 1929 Seedlings versus transplants at Petawawa Forest Experiment Station For Chron 5 4 17 20 Korstian C F Baker F S 1925 Forest planting in the Intermountain region USDA For Serv Washington DC Agric Bull 1264 56 p Kittredge J 1929 Forest planting in the Lake States U S D A for Serv Washington DC Agric Bull 1497 87 p Cleary B D Greaves R D Hermann R K Compilers and Eds 1978 Regenerating Oregon s Forests Oregon State Univ Exten Serv Corvallis OR 287 p Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis G 1990 Wire Baskets A Further Look American Nurseryman 128 131 Duryea M L Landis T D Eds 1984 Forest Nursery Manual Production of Bareroot Seedlings Nijhoff Junk Boston MA 386 p Tinus R W McDonald S E 1979 How to grow tree seedlings in containers in greenhouses USDA For Serv Rocky Mountain For Range Exp Sta Fort Collins CO Gen Tech Rep RM 60 256 p Cited in Nienstaedt and Zasada 1990 Quinn W A 2014 American Standard for Nursery Stock Columbus AmericanHort Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Ministry of Agriculture Food and Rural Affairs 2022 July 18 Starting a commercial nursery in Ontario Retrieved from Ontario https www ontario ca page starting commercial nursery ontario text your 20market s 20needs Production 20Systems deciduous 20shrubs 20and 20herbaceous 20perennials Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Shaw C 2019 A common sense approach to root pruning Nursery Management Magazine 1 Shaw C 2019 A common sense approach to root pruning Nursery Management Magazine 1 Tripepi B 2009 Pruning Roots during Plant Production Idaho Horticulture Expo 2009 pp 1 7 Idaho Horticultural Sciences Division University of Idaho Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Ministry of Agriculture Food and Rural Affairs 2022 July 18 Starting a commercial nursery in Ontario Retrieved from Ontario https www ontario ca page starting commercial nursery ontario text your 20market s 20needs Production 20Systems deciduous 20shrubs 20and 20herbaceous 20perennials Ministry of Agriculture Food and Rural Affairs 2022 July 18 Starting a commercial nursery in Ontario Retrieved from Ontario https www ontario ca page starting commercial nursery ontario text your 20market s 20needs Production 20Systems deciduous 20shrubs 20and 20herbaceous 20perennials Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Ministry of Agriculture Food and Rural Affairs 2022 July 18 Starting a commercial nursery in Ontario Retrieved from Ontario https www ontario ca page starting commercial nursery ontario text your 20market s 20needs Production 20Systems deciduous 20shrubs 20and 20herbaceous 20perennials Damman A 2021 February 1 Swansons Nursery Retrieved from Swansons Nursery https www swansonsnursery com blog bare root plants Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Bassuk 2 Trowbridge Nina 2 Peter 2004 Trees In The Urban Landscape John Wiley amp Sons Inc p 140 ISBN 0471392464 a href Template Cite book html title Template Cite book cite book a CS1 maint numeric names authors list link Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association Lumis A H 2017 Canadian Nursery Stock Standard Ninth Edition Milton Canadian Nursery Landscape Association External links edit nbsp Media related to Plant nurseries at Wikimedia Commons Retrieved from https en wikipedia org w index php title Plant nursery amp oldid 1207405658, wikipedia, wiki, book, books, library,

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