one answer: cell growth, which is caused by photosynthesis.
No, woody plants do not lack secondary growth. Secondary growth is the process by which plants increase their girth through the production of secondary tissues such as wood and bark, which woody plants exhibit. This growth allows woody plants to increase in size and longevity.
Tomato plants primarily exhibit primary growth, which involves the elongation of stems and roots. However, they can also show limited secondary growth, primarily in the form of thickening of stems due to the activity of the vascular cambium, though this is not as pronounced as in woody plants. This secondary growth allows for increased support and nutrient transport as the plant matures. Overall, while secondary growth occurs, it is not a significant feature of tomato plants compared to their primary growth.
During active growth in plants the new tissues are formed for photosynthesis as well as for storage of food material. Therefore sourse (site for photosynthesis) and sink (site for storage) remain changing.
Primary growth in plants adds length to the stems and roots through cell division in the apical meristems. Secondary growth, on the other hand, adds girth to the stems and roots through cell division in the lateral meristems, such as vascular and cork cambium.
The difference between apical meristems and lateral meristems are the location that they sprout buds on plants. Apical buds are present at the top of plants, while lateral buds are present at the base of plants.
No, woody plants do not lack secondary growth. Secondary growth is the process by which plants increase their girth through the production of secondary tissues such as wood and bark, which woody plants exhibit. This growth allows woody plants to increase in size and longevity.
Plants can utilize nitrate (NO3-) as the primary form of nitrogen for growth and development.
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Primary growth in plants occurs at the apical meristem.
Plants that lack secondary growth increase girth through primary growth, which involves cell division and expansion in the primary tissues of the plant (such as the primary xylem and phloem). These plants rely on the activity of their apical meristems to produce new cells that allow for a limited increase in girth over time.
The primary growth in vascular plants takes place with the differentiation of vascular tissue from parenchymatous cells and the secondary growth takes place when the intra-vascular and inter vascular cambium adds to the secondary phloem and secondary xylem.
Tomato plants primarily exhibit primary growth, which involves the elongation of stems and roots. However, they can also show limited secondary growth, primarily in the form of thickening of stems due to the activity of the vascular cambium, though this is not as pronounced as in woody plants. This secondary growth allows for increased support and nutrient transport as the plant matures. Overall, while secondary growth occurs, it is not a significant feature of tomato plants compared to their primary growth.
The primary sources of potassium in plants are soil minerals, organic matter, and fertilizers. Potassium is essential for plant growth and is absorbed by plant roots from the soil.
During active growth in plants the new tissues are formed for photosynthesis as well as for storage of food material. Therefore sourse (site for photosynthesis) and sink (site for storage) remain changing.
Establishing a new site for plant growth involves selecting a suitable location with proper sunlight exposure, soil quality, and drainage. The site should be prepared by clearing any debris, tilling the soil, and adding organic matter or fertilizer as needed. Planting the desired plants or seeds at the right depth and spacing, as well as providing regular watering and maintenance, will help ensure successful plant growth at the new site.
Primary growth in plants adds length to the stems and roots through cell division in the apical meristems. Secondary growth, on the other hand, adds girth to the stems and roots through cell division in the lateral meristems, such as vascular and cork cambium.
Leaves are important to plants because they are the primary site for photosynthesis, the process by which plants convert sunlight into energy. This energy is essential for the plant's growth and overall health. Leaves also help regulate the plant's water balance, exchange gases with the environment, and store nutrients. Overall, leaves play a crucial role in the plant's ability to thrive and survive.