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How To Improve Soil Fertility

1. Practice crop rotation: By planting different crops in a specific order, farmers can help prevent soil nutrient depletion and improve soil structure.

2. Use organic fertilizers: Natural fertilizers such as compost and manure can help to replenish soil nutrients and improve soil structure.

3. Reduce tillage: Excessive tillage can lead to soil erosion and degradation. By minimizing tillage, farmers can help preserve soil structure and fertility.

4. Irrigate wisely: Proper irrigation techniques can help to conserve water and prevent soil erosion.

5. Plant cover crops: Cover crops can help to reduce soil erosion, improve soil structure, and increase soil fertility.

No-dig gardening is a sustainable and low-effort gardening method that involves building up your garden beds without disturbing the soil. This technique promotes soil health, reduces w**d growth, and makes gardening easier by eliminating the need for tilling….

In the quest for sustainable and low-maintenance gardening methods, no-dig gardening has emerged as a revolutionary approach. This technique, also known as no-till or lasagna gardening, focuses on building up garden beds with layers of organic matter rather than disturbing the soil. By eliminating the need for tilling, no-dig gardening not only simplifies the gardening process but also enhances soil health, reduces w**d growth, and conserves moisture. Whether you’re a seasoned gardener or a novice looking for an easier way to cultivate your garden, this guide will walk you through the principles, benefits, and practical steps of no-dig gardening.

What is No-Dig Gardening?
No-dig gardening is a method that involves creating and maintaining garden beds without digging or tilling the soil. Instead of disrupting the soil structure, gardeners build up the bed with layers of organic materials. This approach mimics natural processes where organic matter accumulates on the forest floor, breaking down over time to nourish the soil. The key components of no-dig gardening are:

Layering Organic Matter: Adding layers of compost, straw, leaves, and other organic materials to create a nutrient-rich environment for plants.
Avoiding Soil Disturbance: Keeping the soil intact and undisturbed to preserve its structure and microbial life.
Building Soil Fertility: Relying on natural decomposition of organic matter to enrich the soil and support healthy plant growth.
Benefits of No-Dig Gardening

Improved Soil Health:
No-dig gardening promotes the natural development of soil structure and microbial life. By avoiding soil disturbance, you allow earthworms and beneficial organisms to thrive, which enhances soil fertility.

7 Secrets to Grow Avocados and Achieve Big Harvests Fast
Growing avocados can be a delightful experience, and here are seven essential secrets to ensure success in cultivating healthy avocado trees and enjoying bountiful harvests:,,. Sprouting the Seed in Moist Paper Towels:
Begin by selecting a healthy seed from a ripe avocado. Wrap it in moist paper towels, place it in a plastic ziplock bag in a warm, dark place, and ensure the towels stay damp for germination.
2. Growing Seeds in Water Using the Toothpick Method:
After sprouting, use the toothpick method. Insert toothpicks into the seed, suspend it in a glass of water, and place it in a sunny spot. Change the water regularly until roots and a sprout emerge.,,3. Grafting for Faster Fruit:
Speed up fruiting by grafting your young avocado plant with a branch (scion) from a mature tree. Join the scion to a similar cut on your young tree, secure it with grafting tape, and reduce the time to fruiting significantly.
4. Optimal Soil and Drainage:
Avocado trees thrive in well-draining, sandy loam soil with a pH between 6 and 6.5. If you have heavy soil, consider raised beds or containers for improved drainage to prevent root rot.,,5. Regular Pruning for Shape and Health:
Prune your avocado tree for size and shape management, allowing sunlight to reach all parts. Remove diseased or dead wood for better air circulation and overall health.
6. Consistent and Appropriate Watering:
Keep the soil consistently moist but not waterlogged. Adjust watering frequency in hot, dry climates, and use a moisture meter to gauge when to water.,,7. Fertilizing for Nutrient Boost:
Use a balanced, slow-release fertilizer high in nitrogen a few weeks after planting and follow a regular schedule as per the fertilizer’s instructions.
Climate Considerations:
Avocado trees prefer mild temperatures (60°F to 85°F or 15°C to 29°C) and moderate humidity. Protect them from extreme temperatures, both hot and cold, and shield them from frost.

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Here are 200 soil science terminologies, numbered for easy reference:

👍👉 Professional Farmers PH

1. Absorption: The process by which soil particles attract and hold water, nutrients, and other substances.
2. Acidification: The process of increasing the acidity of soil.
3. Aerobic: A condition where oxygen is present.
4. Aggregate: A cluster of soil particles held together by organic matter, clay, and other binding agents.
5. A horizon: The topsoil layer, characterized by a high concentration of organic matter.
6. Alkalinity: The opposite of acidity, indicating a high pH.
7. Alluvial soil: Soil formed from sediment deposited by rivers.
8. Anaerobic: A condition where oxygen is absent.
9. Anion: A negatively charged ion.
10. Available nutrients: Nutrients that are readily available for plant uptake.
11. Base saturation: The percentage of soil cation exchange capacity occupied by basic cations.
12. Bedrock: The solid rock layer beneath the soil.
13. Bioavailability: The degree to which a nutrient is available for plant uptake.
14. Bioturbation: The mixing of soil by living organisms.
15. Bulk density: The mass of dry soil per unit volume.
16. C horizon: The parent material layer, often consisting of weathered bedrock.
17. Cation: A positively charged ion.
18. Cation exchange capacity (CEC): The ability of soil to hold and exchange cations.
19. Clay: Soil particles smaller than 0.002 mm in diameter.
20. Colloid: A particle that is so small that it can remain suspended in a liquid.
21. Degradation: The process of soil deterioration, leading to reduced fertility and productivity.
22. Denitrification: The conversion of nitrate to nitrogen gas.
23. Drainage: The removal of excess water from soil.
24. Dryland farming: Farming practices used in arid and semi-arid regions.
25. Dust bowl: A severe drought and dust storm event.
26. E horizon: A layer of soil that has been leached of nutrients.
27. Erosion: The process of soil removal by wind, water, or other agents.
28. Evapotranspiration: The combined loss of water from soil by evaporation and plant transpiration.
29. Fertility: The ability of soil to support plant growth.
30. Field capacity: The amount of water held in soil after excess water has drained away.
31. Fissure: A crack or opening in soil.
32. Flocculation: The clumping together of soil particles.
33. Friable: A soil texture that is easily crumbled.
34. Gley: A soil color that indicates poor drainage.
35. Grain size: The diameter of soil particles.
36. Gravel: Soil particles larger than 2 mm in diameter.
37. Humus: Decomposed organic matter in soil.
38. Hydration: The process of water molecules attaching to soil particles.
39. Hydrology: The study of water in the soil.
40. Infiltration: The movement of water into soil.
41. Inorganic matter: Soil components that are not derived from living organisms.
42. Irrigation: The artificial application of water to soil.
43. Leaching: The removal of nutrients from the soil by water.
44. Loam: A soil texture that contains a mixture of sand, silt, and clay.
45. Macronutrients: Nutrients that plants need in large amounts.
46. Micronutrients: Nutrients that plants need in small amounts.
47. Mineralogy: The study of minerals in soil.
48. Moisture content: The amount of water in soil.
49. Mulch: A layer of organic material applied to the soil surface.
50. Nitrogen fixation: The conversion of atmospheric nitrogen gas into a form that can be used by plants.
51. Nutrient cycling: The movement of nutrients through the soil and ecosystem.
52. Organic matter: Soil components derived from living organisms.
53. O horizon: The uppermost layer of soil, consisting of fresh or partially decomposed organic matter.
54. pH: A measure of soil acidity or alkalinity.
55. Permeability: The ability of soil to allow water to pass through it.
56. Phosphorus fixation: The process by which phosphorus becomes unavailable to plants.
57. Plant available water: The amount of water that plants can extract from soil.
58. Podzolization: A soil-forming process that results in the accumulation of organic matter and iron in the upper layers of soil.
59. Redox potential: A measure of the availability of oxygen in soil.
60. Rhizosphere: The zone of soil immediately surrounding plant roots.
61. Root zone: The area of soil where plant roots grow.
62. Salinity: The concentration of salts in soil.
63. Sand: Soil particles between 0.05 and 2 mm in diameter.
64. Silt: Soil particles between 0.002 and 0.05 mm in diameter.
65. Soil aeration: The presence of air in soil pores.
66. Soil compaction: The process of reducing the volume of soil by pressure.
67. Soil fertility: The ability of soil to support plant growth.
68. Soil horizon: A distinct layer of soil that differs in physical, chemical, or biological properties.
69. Soil profile: A vertical cross-section of soil that reveals its different horizons.
70. Soil structure: The arrangement of soil particles into aggregates.
71. Soil texture: The relative proportions of sand, silt, and clay in soil.
72. Texture: The relative proportions of sand, silt, and clay in soil.
73. Topsoil: The uppermost layer of soil, rich in organic matter.
74. Translocation: The movement of nutrients within the soil profile.
75. Unconsolidated soil: Soil that is not cemented together.
76. Vertisol: A type of soil that is high in clay and shrinks and swells with changes in moisture content.
77. Water holding capacity: The amount of water that a soil can hold.
78. Weathering: The physical and chemical breakdown of rocks and minerals.
79. Biochar: A charcoal-like material produced from the pyrolysis of biomass.
80. Bulk density: The mass of dry soil per unit volume.
81. Calcareous soil: Soil containing a significant amount of calcium carbonate.
82. Capillary action: The movement of water upwards through soil pores.
83. Carbon sequestration: The process of removing carbon dioxide from the atmosphere and storing it in soil.
84. Clay minerals: Crystalline structures in soil that have a high capacity to hold water and nutrients.
85. Clay loam: A soil texture with a high percentage of clay.
86. Climatic factors: Weather conditions that influence soil formation.
87. Colluvium: Soil material transported and deposited by gravity.
88. Compaction: The process of reducing the volume of soil by pressure.
89. Conservation tillage: Farming practices that minimize soil disturbance.
90. Crusting: The formation of a hard, impermeable layer on the soil surface.
91. Decomposers: Organisms that break down organic matter in soil.
92. Deposition: The process of adding soil material to a location.
93. Eluviation: The process of removing soil material from one layer and transporting it to another.
94. Erosion control: Practices designed to prevent soil erosion.
95. Exchangeable cations: Cations that are held loosely on soil particles and can be exchanged with other cations.
96. Field capacity: The amount of water held in soil after excess water has drained away.
97. Fertilizer: A substance that provides nutrients to plants.
98. Fine-textured soil: Soil with a high percentage of clay and silt.
99. Flooding: The submergence of soil by water.
100. Footprint: The area of land used for a particular activity.
101. Forest soil: Soil found under forest vegetation.
102. Friability: The ease with which soil can be crumbled.
103. Genesis: The process of soil formation.
104. Geomorphic factors: Landforms and geological processes that influence soil formation.
105. Gill: A small, vertical crack in soil.
106. Gleyed soil: Soil that has a grayish color due to poor drainage.
107. Gravel: Soil particles larger than 2 mm in diameter.
108. Groundwater: Water that is stored beneath the Earth's surface.
109. Hardpan: A hard, compacted layer in soil that restricts root growth.
110. Horizon: A distinct layer of soil that differs in physical, chemical, or biological properties.
111. Humification: The process of decomposing organic matter into humus.
112. Hydric soil: Soil that is saturated with water for long periods.
113. Infiltration rate: The speed at which water enters the soil.
114. Intercropping: Growing two or more crops together in the same field.
115. Land degradation: The deterioration of soil quality and productivity.
116. Land use: The way that land is used by humans.
117. Laterite: A type of soil rich in iron and aluminum oxides.
118. Leaching: The removal of nutrients from the soil by water.
119. Loamy soil: Soil with a balanced mixture of sand, silt, and clay.
120. Macropores: Large pores in soil that allow for rapid water movement.
121. Mantle: The layer of soil that covers bedrock.
122. Microbial activity: The processes carried out by microorganisms in soil.
123. Micropores: Small pores in soil that hold water and nutrients.
124. Mineralization: The conversion of organic matter into inorganic nutrients.
125. Mollisol: A type of soil with a thick, dark topsoil rich in organic matter.
126. Monoculture: The practice of growing a single crop in a field.
127. Nutrient availability: The amount of nutrients that are readily available for plant uptake.
128. Nutrient deficiency: A condition where plants lack essential nutrients.
129. Nutrient leaching: The loss of nutrients from the soil by water.
130. Nutrient management: Practices designed to maintain soil fertility and prevent nutrient loss.
131. Oxisol: A type of soil that is highly weathered and rich in iron and aluminum oxides.
132. Parent material: The underlying rock or sediment from which soil is formed.
133. Ped: A single soil aggregate.
134. Pedogenesis: The process of soil formation.
135. Percolation: The downward movement of water through soil.
136. pH: A measure of soil acidity or alkalinity.
137. Phosphate: A form of phosphorus that is available to plants.
138. Phytoremediation: The use of plants to remove pollutants from soil.
139. Plant available water: The amount of water that plants can extract from soil.
140. Pore space: The volume of air and water in soil.
141. Profile: A vertical cross-section of soil that reveals its different horizons.
142. R horizon: The bedrock layer.
143. Regolith: The layer of unconsolidated material that covers bedrock.
144. Residual soil: Soil that has formed in place from the underlying bedrock.
145. Rhizosphere: The zone of soil immediately surrounding plant roots.
146. Saline soil: Soil with a high concentration of salts.
147. Salinization: The process of increasing the salt content of soil.
148. Sandy soil: Soil with a high percentage of sand.
149. Saturated soil: Soil that is completely filled with water.
150. Sodic soil: Soil with a high concentration of sodium.
151. Soil amendment: A substance added to soil to improve its physical, chemical, or biological properties.
152. Soil conservation: Practices designed to protect and improve soil quality.
153. Soil fertility: The ability of soil to support plant growth.
154. Soil health: The overall condition of soil, including its physical, chemical, and biological properties.
155. Soil horizon: A distinct layer of soil that differs in physical, chemical, or biological properties.
156. Soil management: Practices designed to maintain and improve soil quality.
157. Soil map: A map that shows the distribution of different soil types.
158. Soil moisture: The amount of water in soil.
159. Soil organic matter: Decomposed plant and animal material in soil.
160. Soil structure: The arrangement of soil particles into aggregates.
161. Soil survey: A systematic investigation of soil characteristics.
162. Soil texture: The relative proportions of sand, silt, and clay in soil.
163. Soil water: Water that is held in soil pores.
164. Solum: The upper part of the soil profile that includes the A, B, and E horizons.
165. Spodosol: A type of soil that is highly weathered and acidic.
166. Subsoil: The layer of soil beneath the topsoil.
167. Subsurface drainage: The removal of excess water from soil by underground pipes.
168. Sustainability: The ability to meet the needs of the present without compromising the ability of future generations to meet their own needs.
169. Surface drainage: The removal of excess water from soil by surface channels.
170. Texture: The relative proportions of sand, silt, and clay in soil.
171. Tillage: The mechanical disturbance of soil.
172. Topsoil: The uppermost layer of soil, rich in organic matter.
173. Transpiration: The loss of water from plants through their leaves.
174. Ultisol: A type of soil that is highly weathered and acidic.
175. Vermicomposting: The use of earthworms to decompose organic matter.
176. Water balance: The relationship between the amount of water entering and leaving a soil system.
177. Water infiltration: The movement of water into soil.
178. Waterlogging: The saturation of soil with water to the point where it becomes anaerobic.
179. Water table: The level below which soil is saturated with water.
180. Weathering: The physical and chemical breakdown of rocks and minerals.
181. Wetland soil: Soil that is saturated with water for long periods.
182. Wind erosion: The removal of soil by wind.
183. Zonal soil: A soil that has developed under a particular climate and vegetation.
184. Bioremediation: The use of living organisms to clean up contaminated soil.
185. Carbon footprint: The amount of carbon dioxide emissions associated with a particular activity.
186. Climate change: The long-term shift in global weather patterns.
187. Compost: Decomposed organic matter that can be used as a soil amendment.
188. Conservation agriculture: Farming practices that minimize soil disturbance and maintain soil health.
189. Crop rotation: The practice of growing different crops in the same field in a sequence.
190. Desertification: The process of land degradation leading to the formation of desert-like conditions.
191. Ecosystem services: The benefits that humans derive from natural ecosystems.
192. Food security: The availability of safe, nutritious food for all people at all times.
193. Green manure: A crop grown specifically to be plowed under to improve soil fertility.
194. Land use change: The conversion of land from one use to another.
195. No-till farming: A farming practice that avoids tillage.
196. Organic farming: A farming practice that avoids the use of synthetic fertilizers and pesticides.
197. Precision agriculture: The use of technology to manage crops and soil more precisely.
198. Soil biodiversity: The variety of living organisms in soil.
199. Soil carbon: The amount of carbon stored in soil.
200. Sustainable agriculture: Farming practices that are environmentally

Good morning everyone, currently all our plants are being sold out,

We still have range of nurseries coming up, book yours early as we have lots of customers asking for the plants.

Thanks all.

Thanks brother Damien for buying most of our plants..
We greatly appreciate your support 🙏

Poro Plants Nursery Your soil has the ability to produce more, all you need is a poro plant and you won't regret having one or more plants growing in your backyard. A poro that serves!..

Papaya!

Thanks to our new follower ♥️🙏

Worth trying

6 Tips for Growing Avocado in a Pot and for it to bear fruit 🥑

1. Master Germination
Clean the seed, prick with toothpicks, place in water, and wait for germination.

2. Potting Matters
Use a manageable pot indoors if temperatures drop below 10ºC (50ºF).

3. Optimal Growing Environment
Use an acidic substrate mix (peat, coconut fiber, earthworm humus) with perlite for aeration.

4. Essential Care Guidelines
Protect from cold, manage heat, ensure proper watering and drainage.

5. Fertilization
Fertilize in spring and summer with earthworm humus.

6. Pruning for Success
Prune at one year old to encourage branching and healthy growth.

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Fully grown and well established roots system..
Oranges and lemons seedlings available.
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Your soil has the ability to produce more, all you need is a poro plant and you won't regret having one or more plants growing in your backyard. A poro that serves!.

Hello everyone,
We have range of lemon varieties available now in our little shed..if you or someone you know who in need of this please do inbox us..

Art and the artist 💚🫡

The art & artist.❤️