CN114946512A - Cultivation method for improving growth performance of garlic plant - Google Patents
Cultivation method for improving growth performance of garlic plant Download PDFInfo
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
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- A—HUMAN NECESSITIES
- A01—AGRICULTURE; FORESTRY; ANIMAL HUSBANDRY; HUNTING; TRAPPING; FISHING
- A01G—HORTICULTURE; CULTIVATION OF VEGETABLES, FLOWERS, RICE, FRUIT, VINES, HOPS OR SEAWEED; FORESTRY; WATERING
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- A01G7/06—Treatment of growing trees or plants, e.g. for preventing decay of wood, for tingeing flowers or wood, for prolonging the life of plants
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- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A40/00—Adaptation technologies in agriculture, forestry, livestock or agroalimentary production
- Y02A40/10—Adaptation technologies in agriculture, forestry, livestock or agroalimentary production in agriculture
- Y02A40/22—Improving land use; Improving water use or availability; Controlling erosion
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
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- Y02P—CLIMATE CHANGE MITIGATION TECHNOLOGIES IN THE PRODUCTION OR PROCESSING OF GOODS
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- Y02P60/40—Afforestation or reforestation
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Abstract
The invention relates to a cultivation method for improving growth performance of garlic plant, relates to the technical field of garlic cultivation seedling and afforestation, and aims to solve the problems of low seedling rate and gradual decline of seedling growth in the garlic cultivation process. The invention changes the traditional garlic fruit cultivation mode, adopts a scientific planting method based on the specific root hemiparasitic characteristic of the garlic fruit, and continuously improves the growth performance of the garlic fruit plants by reasonably planting host plants in different development stages of the garlic fruit plants and assisting with scientific maintenance measures. The method fundamentally corrects the traditional maintenance and management measures which are mutually contradictory to the semi-parasitic characteristics of the roots of the garlic fruits, and solves the problems of low seedling rate of the garlic fruits and gradual decline of the growth vigor of seedlings.
Description
Technical Field
The invention belongs to the technical field of plant cultivation, and relates to a cultivation method capable of continuously improving growth performance of garlic fruit plants and keeping the garlic fruit plants in a good growth state.
Background
Garlic fruit (A)Malania oleifera Chun &S.K. Lee) is Allium (of the genus Allium of the family Cyperaceae (Oleaceae) ((R))Malania) Evergreen arbor is a unique single-species plant in China and is distributed only in karst mountainous areas in southeast Yunnan and western Guangxi. The nervonic acid content in the seed kernels of the garlic bulbs reaches up to 42 percent, and the seed kernels of the garlic bulbs are plants with the highest nervonic acid content at present and have great application potential in the development of brain health care products. In addition, the toxic protein in the seed kernels of the garlic bulbs can be used for researching and developing anticancer drugs, the garlic bulb wood is a passenger wood for buildings and furniture, plants of the garlic bulb wood are naturally distributed in limestone mountains and have strong adaptability, and the garlic bulb wood is an excellent tree seed for ecological restoration and stony desertification control in karst regions. Although the garlic cloves have great economic development value and ecological restoration function, the existing resources of the garlic cloves are very limited due to the ecological disturbance and early resource abuse. Although a great deal of research is carried out in the early stage to carry out the discussion of the planting and afforestation technology of the garlic, the problems of low seedling rate and annual decline of the growth vigor of seedlings in the artificial cultivation process of the garlic are not fundamentally solved, which limits the resource protection, development and utilization of the garlic to a great extent.
In the prior art of planting and afforesting the garlic, the conventional plant planting management and protection and afforesting technology is adopted, and the special biological characteristics of the garlic are not considered, so that the effect is not ideal. Recent studies have found that the garlic cloves have root hemiparasitic properties. Because the root hemiparasitic plant and the common plant nutrient absorption strategy have great difference, the cultivation and maintenance method suitable for the conventional green plant can not meet the growth requirement of the root hemiparasitic plant, the traditional management measures such as weeding, loosening and the like are not beneficial to establishing the parasitic relationship between the garlic fruits and the hosts, and are contrary to the requirement of the root hemiparasitic characteristic of the garlic fruits, so that fatal damage is caused to the garlic fruits, and the method is an important factor for causing the low afforestation seedling rate of the garlic fruits and the annual decline of the plants in the prior art.
Only a few related researches at the early stage only discover the root hemiparasitic characteristics and the host range of the garlic fruits, or select some plants which do not exist in the garlic fruit habitat and are inapplicable in cultivation and afforestation as hosts to confirm the influence on the growth of the garlic fruits, but do not discuss the reasonable selection of host species in combination with the garlic fruit cultivation and afforestation practice, do not consider the selection preference of the garlic fruits on the host plants at different development stages, and do not explore the key period of host plant matching and the management measures for realizing scientific nursery stock maintenance, so that specific guidance cannot be provided for garlic fruit cultivation and afforestation.
In order to solve the problems of low seedling rate and annual decline of seedling growth vigor in the artificial cultivation process of the garlic cloves, more intensive and systematic research needs to be carried out on the root hemiparasitic characteristics of the garlic cloves, and on the basis, a cultivation, maintenance and afforestation method suitable for the specific biological characteristics and physiological demand characteristics of the garlic cloves is provided, so that the aims of continuously improving the growth performance of garlic cloves plants and improving the growth state of the plants in cultivation and afforestation are fulfilled.
Disclosure of Invention
The invention aims to provide a cultivation method for continuously improving the growth performance of garlic fruit plants and keeping the garlic fruit plants in a good growth state.
The method obtains robust seedlings by optimizing seeds with good maturity, reasonably storing the seeds and promoting germination in due time, realizes continuous strong seedlings by matching and planting reasonable hosts as early as possible in the seedling stage, protects the parasitic relationship between the garlic fruits and the hosts after the seedlings are transplanted so as to improve the transplanting survival rate of the seedlings, scientifically matches and plants excellent hosts of the garlic fruits in the seedling stage and the adult stage so as to establish stable and sustainable parasitic relationship between each development stage of the garlic fruits and the hosts, balances the parasitic and competitive relationship between the garlic fruits and the host plants in each stage through multiple maintenance measures, realizes continuous and healthy growth of the garlic fruit plants and the host plants thereof, and solves the problems of low seedling rate and year-by-year decline of the plants in the existing garlic fruit cultivation and afforestation processes.
The invention is mainly realized by the following technical scheme:
aiming at the root hemiparasitic characteristic of the garlic fruits, the invention reasonably allocates host plants at different development stages according to the selection preference of the garlic fruits to different host plants at different development stages and assists with scientific maintenance management measures to promote the garlic fruits to continuously keep good growth state; the cultivation method mainly comprises the following steps:
(1) herbaceous host plants are planted at the same time or at the seedling stage when the garlic seeds are sowed, so that the garlic seeds and the hosts successfully establish a parasitic relationship, the growth state of seedlings is improved, and the stress resistance level and the survival rate of the seedlings are improved;
(2) transplanting the young garlic fruit seedlings together with the herbaceous host plants, and pruning the host plants when the herbaceous host plants are higher than the garlic fruits;
(3) and (3) planting shrub host plants and/or arbor host plants within one year after transplanting the garlic sprout.
The period for planting the host plant is selected according to the initial time of the production of the parasitic organ of the garlic fruit and the time sequence characteristics of the nutrient consumption of the seed storage after the seedling emerges. Parasitic organs are generated in the process that the garlic seedlings come out of the ground for about 6 weeks, and the host plants are planted in the process of the parasitic organs, so that the parasitic relationship can be formed earlier, and the development of the garlic seedlings is promoted; the root system absorption capacity of the garlic fruits is weak, the photosynthetic efficiency is low, the nutrient consumption stored in the seeds is exhausted after the garlic fruits grow out, the dependence degree on host plants is increased, at the moment, the nutrient supply of herbaceous hosts cannot meet the growth requirement of the garlic fruits, and therefore shrub hosts are needed to be planted before the garlic fruits grow to meet the growth requirement of the garlic fruits in the seedling stage and arbor hosts are needed to be planted to meet the growth requirement of the garlic fruits in the adult stage. Although allium sativum fruit parasitizes at the root of the host to take nutrients from the host, it still requires self-synthesis of photosynthetic products to maximize biomass accumulation. Because the aerial part of the host plant and the garlic fruit have competition of light resources and the garlic fruit grows slowly in the early stage, the problem of cultivation distance needs to be considered when the host is matched, so that the host plant and the garlic fruit do not excessively compete for the light resources. Shrub hosts can be cultivated at a short distance from garlic fruits, but the shrub hosts need to be cultivated at a relatively long distance from arbor hosts. The method can plant the hosts in the seedling stage and the adult stage within one year, and can reserve enough time for the root development of various plants, so that the garlic cloves can contact with the corresponding host root before being stressed by nutrients and establish a parasitic relationship, and the gradually increased nutrient requirements of various stages are met.
Further, in the step (1), selecting seeds with good maturity, storing, promoting germination and then sowing to obtain robust garlic fruit seedlings; the seeds with good maturity refer to the seeds with full kernels collected after the middle and late ten days of 9 months. Before the seeds are stored, the seeds need to be washed by clear water after peel is removed, the seeds are soaked for 25-30 min by using 50wt% carbendazim wettable powder diluted by 500 times, and the seeds are naturally dried and stored in river sand or perlite with the water content of 10-15 wt% at normal temperature. Gradually increasing the humidity of perlite or river sand in the next early spring to promote seed germination, and after the seeds germinate, sowing the seeds in a wet river sand seedbed, a perlite seedbed or a non-woven bag filled with a matrix; sowing in wet river sand or a perlite seedbed at an interval of 25 cm to obtain bare-rooted seedlings; sowing 1 seed in each bag of non-woven fabric bags filled with the matrix to obtain bagged seedlings.
Further, in the step (1), the young seedling stage of the garlic fruits means within 6 weeks after the young seedlings come out of the soil. According to the previous experimental results, the parasitic organs of the garlic fruits grow out about 6 weeks after the seedlings come out of the soil, which is a key period for establishing the parasitic relationship with the hosts, and the garlic fruits and the hosts can be established with the parasitic organs earlier by planting host plants before the parasitic organs. Compared with the plant with the later matched host, the photosynthetic rate and the plant growth performance of the plant with the matched host are better in the same sowing period or within 6 weeks after the emergence of the seedling. The herbaceous host plant is preferably a herbaceous host plant with developed root system, rapid growth and pruning resistance. Further preferably, the herbaceous host plant comprises one or more of Artemisia pseudo-sagebrush, Artemisia argyi and Canada. The distance between the plant of the herbaceous host and the seed or seedling of the garlic bulb is 5-10 cm. The root system of the herbaceous host grows fast, the lignification degree is low, the herbaceous host is easy to be parasitized by parasitic organs of young garlic cloves, and the growth of the garlic cloves can be promoted under the condition of close planting. In the production, both bagged seedlings and bare-rooted seedlings belong to a space intensive cultivation mode, so that the herbaceous plants are better planted in the same sowing period or seedling period by matching with hosts. The selection of the host species at the seedling stage takes three factors into consideration: the host has the growth promoting effect on the garlic, the pruning resistance of the host, the availability of host materials and the simplicity of seedling transplanting operation. The growth promoting effect of the artemisia pseudo-wormwood or the canadian bur on the garlic fruit seedlings is superior to that of other plants, the pruning resistance and the cutting propagation are easy, and the materials are easy to obtain.
Further, in the step (2), transplanting is completed within half a year to two years after the garlic seedlings come out of the soil. Bare-rooted seedlings are required to reduce damage to root systems during seedling lifting, and moss and other water-retention materials are used for keeping moisture in the transportation process so as to prevent the root systems from losing water to cause dead seedlings; the non-woven fabric bags are cut off when the bagged seedlings are transplanted, and the root systems of the bagged seedlings with the packing phenomenon are required to be cut before earthing to enable the root systems to be in a relatively unfolded state. Either bare-rooted seedlings or bagged seedlings are transplanted together with the herbaceous host plants, and unnecessary root system disturbance is avoided as much as possible. The transplanting area is preferably a section with good drainage. Loosening soil in the planting area before transplanting, and mixing 1 kg of farmyard manure with good maturity in each planting hole. The young garlic fruit seedlings and the host are placed in the center of the planting hole, the seedlings are straightened, and soil is backfilled to make the depth of the soil cover equal to the junction of the roots and the stems of the young garlic fruit seedlings. Watering the seedlings once a week within one month after transplanting; in the maintenance process, if the herbaceous host plant is found to be higher than the garlic, the host should be pruned in time so as not to influence the photosynthesis of the garlic; during the management and protection period, the disturbance of the soil around the root system in a large range or high strength is reduced as much as possible, so that the connection of the root system between the garlic fruit and the host is prevented from being damaged, but the hardened part of the soil can be loosened properly, and the development of the root system is facilitated.
Further, in the step (3), the shrub host plant is preferably a shrub plant which grows rapidly, is pruning-resistant and adapts to the karst environment. More preferably, the shrub host plant comprises one or more of Ledum Palustre L.of Myrsinaceae, Caragana sinica of Leguminosae, bauhinia variegata of Leguminosae, Satureja japonica of Anacardiaceae, and Phyllanthus emblica of Euphorbiaceae. The planting distance between the shrub host plant and the garlic plant is 30-50 cm, so as to achieve ideal parasitic effect.
The nutrient consumption of the garlic fruits is further increased in the seedling stage, and the herbaceous host plants cannot meet the demand. However, if the arbor host plants are directly planted, if the cultivation distance is long, the root systems can be contacted for a long time, the arbor host plants are thick and strong in root systems and high in lignification degree, the parasitic relationship needs to be established for a long time, and the garlic fruits are stressed by nutrients during the period; if the cultivation distance is short, because the crown of the arbor host is large, the arbor host and the garlic fruit are cultivated in a short distance, light resources are easy to compete, and the growth vigor of the garlic fruit is weakened. Shrubs are selected as hosts of garlic bulbs in seedling stages, and can be cultivated at a short distance from the garlic bulbs, so that the problem of excessive competition of optical resources is avoided while the nutrient supply efficiency of the garlic bulbs is effectively improved, and a good transition effect is achieved. Preferred are plants of the shrubs including Duchesnea rotundifolia of the family Myrsinaceae, Caragana sinica of the family Leguminosae, bauhinia galpinii of the family Leguminosae, pistacia veronica of the family Anacardiaceae, and Emblica officinalis of the family Euphorbiaceae, because the plants of the shrubs grow fast, have weak defense response against parasitism of garlic bulbs, are resistant to pruning, and have good adaptability.
Further, in the step (3), the arbor host plant is preferably an arbor plant which has a good economic value and is suitable for afforestation. Further preferably, the arbor host plant comprises one or more of Yunnan fir of Pinaceae, Pinus massoniana of Pinaceae, Dalbergia odorifera of Leguminosae, and Camellia oleifera of Theaceae. The distance between the arbor host plant and the plant of the garlic bulb is 2-3 m, and the arbor host plant and the plant of the garlic bulb can be used as hosts on which the garlic bulb depends for a long time and coexist with the garlic bulb, namely permanent hosts. The grown garlic fruit can reach several meters or even higher, the nutrient demand is huge, and arbor hosts can continuously supply a large amount of nutrients for the garlic fruit, so the garlic fruit can be used as permanent hosts. The garlic fruits can be fruited within about 8 years, the output empty window period is long, and in order to improve the forest land benefit, the economic value of host plants is considered in addition to the growth promoting effect on the garlic fruits in the aspect of selecting arbor hosts. These arbor host plants are selected to be the dominant afforestation species or economic species in the garlic spread area.
Further, parasitic relationship maintenance and long-term nursery stock maintenance: in the whole cultivation stage of the garlic cloves, maintenance measures for damaging the connection between the garlic cloves root systems and the host root systems are avoided so as to ensure the stability and the continuity of parasitic relations. The biomass accumulation of allium sativum fruits depends to a large extent on their own photosynthesis, so that in order to avoid the host plant from growing too much and thus to shield the allium sativum fruits, the host plant needs to be trimmed periodically when the plant of the host plant is higher than the plant of the allium sativum fruits. It is important to note that the host plant is not removed during the seedling stage, adult stage or fruiting stage of the garlic plant, so as not to cause irreversible damage to the garlic. In order to avoid that the growth vigor of host plants is weakened due to parasitism of the garlic bulbs so as to influence the growth of the garlic bulbs, the garlic bulbs can be fertilized once every 3 months and 7 months; for the garlic plant in the flowering and fruiting period, the compound fertilizer can be applied to the garlic and the host plant once in 5 months. Particularly, the balanced application of nitrogen, phosphorus and potassium fertilizers is emphasized, and the ternary compound fertilizer with the proportion of nitrogen, phosphorus and potassium being 20:10:10 is preferred. The preparation and selection of the compound fertilizer are based on the analysis of the experimental result of the nutrient demand of the garlic and the host plants in earlier period. The compound fertilizer is closer to the optimal nutrient element proportion in the experimental result. Our results show that the nutrient supply level has a significant effect on the relationship between root hemiparasitic plants and host plants. The fertilizer can promote the growth of the garlic fruits, balance the parasitic relationship between the garlic fruits and host plants, avoid the garlic fruits from excessively depriving the hosts of nutrients, further realize the sustainability of the parasitic relationship between the garlic fruits and the hosts and achieve the effect of continuously and well growing the garlic fruits.
The invention has the following effects:
according to the cultivation method, the survival rate of the three-year-old garlic seedlings can reach more than 90%, and the growth vigor of the garlic plants is far beyond that of the traditional cultivation method: the net photosynthetic rate of the seedlings can be improved by more than 2.5 times, the plant height can reach more than 2 times in a half year by using a traditional cultivation method, and the biomass accumulation of the seedlings after 3 years is more than 5 times of that of the seedlings by using a traditional seedling method; the growth performance of the garlic plant at each seedling age stage which maintains stable parasitic relation with the superior host plant is continuously improved.
Drawings
FIG. 1 is a diagram of the growth of a plant of allium sativum; the garlic plant parasitizing the superior host, namely the Du-stem mountain with deep green leaves and luxuriant plant height is arranged in the back row; the front row is the same batch of garlic plant without host, the leaf is yellow, and the plant is short.
Detailed Description
Based on the root hemiparasitic characteristic of the garlic fruits and the selection preference of the garlic fruits to different host plants in different development stages, the growth performance of the garlic fruits is continuously improved by reasonably matching and planting the host plants in the key development stage of the garlic fruit plants and assisting scientific maintenance measures. The seedling stage is matched with the hosts to be beneficial to improving the survival rate of the seedlings, and the garlic fruits can continuously and well grow from the seedling stage to the adult stage by matching and planting good hosts suitable for different growth stages of the garlic fruits and maintaining the stable parasitic relationship between the garlic fruits and the hosts by the aid of scientific maintenance measures.
The technical scheme of the embodiment of the invention is described in detail below by taking artemisia pseudo-rupestris, ledum rotundifolia and dalbergia odorifera as hosts of young seedling stage, seedling stage and adult stage of garlic fruit respectively. It is noted that the details described herein are only some of the embodiments of the invention. All other embodiments obtained by anyone without creative work based on the embodiments of the present invention belong to the protection scope of the present invention.
Example 1 Effect of host mating on the growth Performance of Garlic plants
Example 1: the method for cultivating the garlic plant comprises the following steps:
(1) preparing and sowing seeds: garlic seeds collected from eosin county of Guannan province of Yunnan province in 2017, 10 months and 8 days are washed with clear water after peeling, soaked in 50wt% carbendazim wettable powder diluted by 500 times for 25-30 min for surface disinfection, naturally dried and stored in wet river sand with the water content of about 10wt% at normal temperature. In 2018, the humidity of river sand is gradually increased to about 15% at the beginning of 2 months, a large amount of seeds germinate in 3 months, and hypocotyls break through seed coats. And transplanting the germinated seeds into seedling pots filled with leaf mold and red soil in a volume ratio of 3:1 at the bottom of 3 months, wherein 1 seed is planted in each pot.
(2) In the seedling stage, artemisia pseudo-rupestris is used as a host: when the seeds of the garlic bulbs are sowed, cutting seedlings of the artemisia pseudo-sieversiana are transplanted to serve as hosts of the garlic bulbs at the same time, the distance between the artemisia pseudo-sieversiana and the garlic bulbs is 8 cm, and 2 artemisia pseudo-sieversiana plants are planted in each pot. Watering once a week after transplanting, and watering nutrient solution once a week by 10% of the volume of the matrix; when the plant of the pseudo-wormwood is higher than the young garlic fruit, the pseudo-wormwood is trimmed so as not to shield the garlic fruit plant.
(3) Transplanting and maintaining seedlings: transplanting is completed after the garlic fruit seedlings come out of the soil for one year. When transplanting, the seedling raising pot is cut open, the root system is properly trimmed firstly when the root system has the packing phenomenon, so that the root system is in a relatively unfolded state, and the seedling raising pot and the false artemisia are transplanted together. The transplanting area is preferably selected to have a good drainage area. Loosening soil in the planting area before transplanting, and mixing 1 kg of farmyard manure with good maturity in each planting hole. Placing young garlic bulbs and pseudo-wormwood in the center of a planting hole, strengthening the young garlic bulbs, and backfilling soil to make the depth of the soil cover equal to the junction of the roots and stems of the young garlic bulbs. And irrigating water once per week within one month after transplanting the seedlings. For peripheral weeds, only the overground part is trimmed, and the root system is not disturbed.
(4) And (3) respectively planting excellent hosts in the seedling stage and the adult stage: transplanting the Duhushan leaves about 3 months after transplanting the young garlic sprouts and about 50 cm away from the garlic plants; transplanting Dalbergia odorifera seedlings about 3 m away from the allium sativum L.var.sativum L.var.oleifera plant.
(5) Maintaining parasitic relationship and maintaining nursery stock for a long time: in the whole cultivation stage of the garlic cloves, the disturbance of the shallow root system is avoided as much as possible, the fertilization is carried out on the side far away from the host, and the weeding is mainly carried out in a mode of cutting the overground part so as to ensure the stability and the continuity of the parasitic relationship. When the host plant grows too vigorously to shield the garlic, the host tree crown is regularly trimmed. After transplanting seedlings, applying ternary compound fertilizer with the nitrogen-phosphorus-potassium ratio of 20:10:10 once in 3 and 7 months each year.
Comparative example 1
Comparative example 1 was carried out exactly according to the conditions of example 1, except that in comparative example 1, the host plant was not allocated to the garlic cloves. The comparative results show that the garlic cloves of example 1 show a significant improvement in survival rate, plant height, biomass and net photosynthetic rate at each seedling stage compared to the plants of comparative example 1.
The correlation results are given in the following table:
example 2 Effect of sowing of Co-planted hosts on the occurrence of the sucking device of garlic bulbs
Time profile of occurrence of allium sativum fruit suckers and responses thereof to host plants
(1) Preparing and sowing seeds: the method comprises the steps of collecting seeds of garlic bulbs in 2019, 10 months, from 23-degree 44 '52' N, 105-degree 09 '42' E, and an altitude of 1469 m of village, south, Guannan county, Yunnan province, removing peels, washing with clear water, soaking for 25-30 min by using 50wt% carbendazim wettable powder diluted by 500 times, disinfecting the surfaces, naturally drying, and storing in perlite with the water content of about 10wt% at normal temperature. The moisture of the perlite is gradually increased to about 15% from 1 month to 18 months in 2020, a large amount of seeds germinate in 6 months, and the hypocotyl breaks through the seed coat. Sowing the germinated seeds into a container filled with perlite: vermiculite =2:1 (volume ratio) root box, 1 seed per pot.
(2) Planting the false artemisia or not at the same sowing period: when sowing seeds of the garlic bulbs, transplanting cutting seedlings of the artemisia pseudo-sieversiana as hosts of the garlic bulbs at the same time, wherein the distance between the artemisia pseudo-sieversiana and the garlic bulbs is 8 cm, and planting 1 artemisia pseudo-sieversiana in each box; in the treatment without matching with the host, the planting position of the garlic fruit is the same as that of the matching with the artemisia pseudo-sieversiana. Watering the transplanted plants once a week, and watering Long Ashton standard nutrient solution once a week by 10% of the volume of the matrix; when the plant of the pseudo-wormwood is higher than the young garlic plant, the pseudo-wormwood is trimmed, and the plant of the garlic plant is not shielded.
(3) Observation and inhaler number statistics: the number of haustorium occurrences in the root box was observed weekly and recorded.
The results showed that young garlic shoots continued to produce parasitic organs (i.e., haustoria) after 6 weeks of emergence. The allocation of host plants to them before was effective in increasing the number of aspirators that occurred (Table 2).
TABLE 2 Effect of host plant Allocation on the number and dynamic variation of young garlic sprout suckers
EXAMPLE 3 Effect of different NPK supply levels on the growth of Allium sativum plants
The cultivation method is completed according to the conditions of the embodiment 1, and the difference lies in the different fertilization of the nitrogen-phosphorus-potassium compound fertilizer. To examine the nutrient demand preference of the allium sativum plants, annual plantlets were selected for testing, since the plants at this time are depleted of the nutrients stored in the seeds and are more responsive to nutrient supply. Taking out annual garlic fruit seedlings from a culture medium in 2019, 11 and 28 days, washing roots, measuring the base data such as plant height, stem base diameter, leaf number and the like, transplanting the seedlings to a root control pot (diameter: depth =19 cm: 20 cm), treating 15 pots of each garlic fruit, wherein the culture medium is perlite: vermiculite =2:1 (volume ratio), nutrient solutions with different proportions are applied according to the experimental design after two weeks of seedling revival, and the nutrient solutions are applied according to 10% of the volume of the culture medium every week. Nutrient treatment was designed as a three-factor, three-level orthogonal test of N, P, K three levels of each of the three elements. On the basis of the LongAshton standard nutrient solution, the following steps are set: three nitrogen levels: nitrogen deficiency (-N), normal nitrogen (N), double nitrogen (2N); three phosphorus levels: phosphorus deficiency (-P), normal phosphorus (P), double phosphorus (2P) and three potassium levels: potassium deficiency (-K), normal potassium (K), double potassium (2K), for a total of 9 treatments.
The cultivation test was carried out on a moving bed in a glass greenhouse (25 ℃ 08 '22 "N, 102 ℃ 44' 23" E, altitude: 1990 m) of the Kunming plant. The growth time of pouring different nutrient solutions to the plants is 12 days in 2019 and 12 days to 5 days in 2021 and 2 months, the total time is 421 days (13 months and 24 days), after nutrient treatment is carried out for 10 months, net photosynthetic rate measurement is carried out on the leaves of the garlic cloves, the plant height and the number of the leaves are measured after the test is finished, the growth increment of each plant relative to the plants before nutrient treatment is calculated, and the influence of different nutrient elements on the growth and physiological indexes of the garlic cloves and the interaction effect among the elements are revealed by utilizing the analysis of the variance of the three factors.
The research result shows that the nitrogen supply has very obvious promotion effect on the increase of the plant height and the leaf number of the garlic cloves and the photosynthetic capacity, and the supply levels of the nitrogen fertilizer and the phosphate fertilizer have obvious interaction effect (Table 3). In all treatments, 2 times of nitrogen effect is generally better, the nitrogen-phosphorus ratio is 2:1 with best effect (table 4), potassium element has little influence on the garlic cloves, so the potassium ratio is preferably kept moderate in production, and the compound fertilizer with N: P: K =20:10:10 is adopted in combination with the common proportion of commercial compound fertilizers.
TABLE 3 results of analysis of the three-factor variance of the effect of different NPK supply levels on the growth and physiological indicators of the Allium sativum plants
Note: the plant height increment represents incremental data obtained by subtracting the plant height at the beginning of the test from the plant height at the time of harvesting the plants, and the increment of the leaf number is the same. The black and bold font in the table indicates that the test factor has a significant effect on the index (P< 0.05) or very significant influenceP<0.01)。
TABLE 4 influence of different NPK supply levels on the growth and physiological indices of Allium sativum plants
Finally, it is noted that the above-mentioned preferred embodiments illustrate rather than limit the invention, and that, although the invention has been described in detail with reference to the above-mentioned preferred embodiments, it will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the invention as defined by the appended claims.
Claims (9)
1. A cultivation method for improving growth performance of a garlic clove plant is characterized by comprising the following steps:
(1) planting herbaceous host plants at the same time or at a seedling stage when sowing the garlic seeds;
(2) transplanting the young garlic fruit seedlings together with the herbaceous host plants, and pruning the host plants when the herbaceous host plants are higher than the garlic fruits;
(3) and (3) planting shrub host plants and/or arbor host plants within one year after transplanting the garlic sprout.
2. The cultivation method for improving the growth performance of a garlic fruit plant according to claim 1, wherein the cultivation method comprises the following steps: in the step (1), the young seedling stage of the garlic fruits refers to 6 weeks after the young seedlings come out of the soil; the distance between the plant of the herbaceous host and the seed or seedling of the garlic bulb is 5-10 cm.
3. The cultivation method for improving the growth performance of the garlic clove plant according to claim 1 or 2, wherein the cultivation method comprises the following steps: in the step (1), the herbaceous host plant comprises one or more of folium Artemisiae Argyi, folium Artemisiae Argyi or Canadian Pepper.
4. The cultivation method for improving the growth performance of a garlic fruit plant according to claim 1, wherein the cultivation method comprises the following steps: in the step (2), transplanting is completed within half a year to two years after the garlic fruit seedlings come out of soil.
5. The cultivation method for improving the growth performance of a garlic fruit plant according to claim 1, wherein the cultivation method comprises the following steps: in the step (3), the distance between the shrub host plant and the garlic plant is 30-50 cm; the distance between the arbor host plant and the garlic plant is 2-3 m.
6. The cultivation method for improving the growth performance of the garlic clove plant according to claim 1 or 5, wherein the cultivation method comprises the following steps: in the step (3), the shrub host plant comprises one or more of Ledum Palustre L.of Myrsinaceae, Caragana sinica of Leguminosae, bauhinia variegata of Leguminosae, Satureja japonica of Anacardiaceae, and Phyllanthus emblica of Euphorbiaceae; the arbor host plant comprises one or more of Yunnan oil fir of Pinaceae, Pinus massoniana of Pinaceae, Dalbergia odorifera of Leguminosae, and Camellia oleifera of Theaceae.
7. The cultivation method for improving the growth performance of a garlic fruit plant according to claim 1, wherein the cultivation method comprises the following steps: the herbaceous host plant is not removed in the seedling stage, adult stage or fructification stage of the garlic plant, and the host is pruned when the herbaceous host plant is higher than the garlic plant.
8. The cultivation method for improving the growth performance of a garlic fruit plant according to claim 1, wherein the cultivation method comprises the following steps: fertilizing once in each of march and July; and for the garlic plant in the flowering and fruiting period, applying the fertilizer for the garlic and the host plant once in May.
9. The cultivation method for improving growth performance of a plant of allium sativum according to claim 8, wherein: the fertilizer for fertilizing the garlic and the host plant is a ternary compound fertilizer with the proportion of nitrogen, phosphorus and potassium of 20:10: 10.
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Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116008196A (en) * | 2023-03-20 | 2023-04-25 | 中国科学院昆明植物研究所 | Method for rapidly and minimally invasively detecting activity of young garlic fruits |
CN116584302A (en) * | 2023-07-13 | 2023-08-15 | 西南林业大学 | Cultivation method for improving preservation rate of artificial forestation and promoting rapid growth of garlic fruits |
Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN107466782A (en) * | 2017-09-13 | 2017-12-15 | 云南省林业科学院 | A kind of breeding cultivation method of malania oleifera seed |
CN109337939A (en) * | 2018-09-30 | 2019-02-15 | 河北康睿达脂质有限公司 | A kind of preparation method of polyunsaturated fatty acid structured lipid |
CN109417981A (en) * | 2017-08-24 | 2019-03-05 | 云南吉成园林科技股份有限公司 | The artificial direct seeding forestation method of malania oleifera |
CN110419376A (en) * | 2019-08-28 | 2019-11-08 | 毛平 | Malania oleifera nutrient bag seeding cultivating method |
CN110810242A (en) * | 2019-11-25 | 2020-02-21 | 文山学院 | Rapid propagation method of garlic fruits |
CN110999647A (en) * | 2019-12-18 | 2020-04-14 | 云南省林业科学院 | Cutting propagation method of garlic cloves |
CN112352621A (en) * | 2020-11-12 | 2021-02-12 | 云南林业职业技术学院 | Wild-simulated cultivation method capable of remarkably improving survival rate of garlic fruits |
-
2022
- 2022-08-02 CN CN202210920735.0A patent/CN114946512B/en active Active
Patent Citations (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN109417981A (en) * | 2017-08-24 | 2019-03-05 | 云南吉成园林科技股份有限公司 | The artificial direct seeding forestation method of malania oleifera |
CN107466782A (en) * | 2017-09-13 | 2017-12-15 | 云南省林业科学院 | A kind of breeding cultivation method of malania oleifera seed |
CN109337939A (en) * | 2018-09-30 | 2019-02-15 | 河北康睿达脂质有限公司 | A kind of preparation method of polyunsaturated fatty acid structured lipid |
CN110419376A (en) * | 2019-08-28 | 2019-11-08 | 毛平 | Malania oleifera nutrient bag seeding cultivating method |
CN110810242A (en) * | 2019-11-25 | 2020-02-21 | 文山学院 | Rapid propagation method of garlic fruits |
CN110999647A (en) * | 2019-12-18 | 2020-04-14 | 云南省林业科学院 | Cutting propagation method of garlic cloves |
CN112352621A (en) * | 2020-11-12 | 2021-02-12 | 云南林业职业技术学院 | Wild-simulated cultivation method capable of remarkably improving survival rate of garlic fruits |
Non-Patent Citations (3)
Title |
---|
AI-RONG LI等: "Root hemiparasitism in Malania oleifera (Olacaceae), a neglected", 《PLANT DIVERSITY》 * |
李勇鹏等: "蒜头果半寄生特性研究", 《西部林业科学》 * |
王毅等: "蒜头果的内生真菌多样性分析", 《基因组学和应用生物学》 * |
Cited By (4)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN116008196A (en) * | 2023-03-20 | 2023-04-25 | 中国科学院昆明植物研究所 | Method for rapidly and minimally invasively detecting activity of young garlic fruits |
CN116008196B (en) * | 2023-03-20 | 2023-06-02 | 中国科学院昆明植物研究所 | Method for rapidly and minimally invasively detecting activity of young garlic fruits |
CN116584302A (en) * | 2023-07-13 | 2023-08-15 | 西南林业大学 | Cultivation method for improving preservation rate of artificial forestation and promoting rapid growth of garlic fruits |
CN116584302B (en) * | 2023-07-13 | 2023-09-22 | 西南林业大学 | Cultivation method for improving preservation rate of artificial forestation and promoting rapid growth of garlic fruits |
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