so it cant get to wet and get to much water
The process that causes leaves to become larger is called cell division and elongation, which is driven by the plant hormone gibberellin. This hormone promotes cell growth and expansion in the leaves, leading to an increase in their size.
The bipinnate compound leaves of this plant are adapted to optimize photosynthesis in varying light conditions by increasing the surface area for light absorption. The multiple leaflets allow for more efficient light capture, while the ability to adjust the angle of the leaves helps to maximize sunlight exposure for photosynthesis.
The flat green organ adapted to collect as much light as possible to make food for the plant is called a leaf. Leaves contain chlorophyll, a pigment that absorbs sunlight for photosynthesis, allowing the plant to convert the light energy into chemical energy in the form of sugars.
The leaves of a flowering plant capture the most sunlight for photosynthesis. They contain chlorophyll, the pigment that absorbs sunlight and converts it into energy through photosynthesis. Leaves are specifically adapted to maximize their surface area for efficient light capture.
Leaves can become larger due to factors such as genetics, nutrient availability, water supply, and sunlight exposure. Genetic factors determine the potential size of the leaves, while adequate nutrients, water, and sunlight can support optimal growth leading to larger leaves. Stressors like limited resources or environmental conditions can inhibit leaf size.
A shade plant is adapted to thrive in low light conditions and typically has larger leaves with a higher chlorophyll content to maximize light absorption. A sun plant, on the other hand, is adapted to thrive in bright, direct sunlight and often has smaller, thicker leaves to prevent water loss.
because no other plant can kill them or touch them
they nake starch and produce energy for the plant.
The process that causes leaves to become larger is called cell division and elongation, which is driven by the plant hormone gibberellin. This hormone promotes cell growth and expansion in the leaves, leading to an increase in their size.
A xeromorph is any plant with the ability to store water in its leaves, which has intentionally adapted to survive in a dry climate.
The roots and leaves are adapted to fit the tree's/plant's needs.
Succulent plants have adapted to dry, arid conditions, by storing water in its fleshy leaves and swollen stems.
The bipinnate compound leaves of this plant are adapted to optimize photosynthesis in varying light conditions by increasing the surface area for light absorption. The multiple leaflets allow for more efficient light capture, while the ability to adjust the angle of the leaves helps to maximize sunlight exposure for photosynthesis.
the drip tips its the pointy end of the plant so when it rains the water that is caught on the leaves drips down to the point into the soil so it can use it. if it didn't have the drip tips the giant leaves would act like giant umbrellas and it wouldn't get any water to the roots.
Large leaves typically produce more food for a plant compared to small leaves. This is because a larger surface area allows for more photosynthesis to occur, resulting in increased production of sugars and energy for the plant.
The giant panda has a wide, powerful jaw specifically adapted for chewing tough bamboo leaves. Its strong molars and robust jaw muscles allow it to effectively grind and break down the fibrous plant material. This dietary specialization is essential for the panda, as bamboo constitutes the majority of its diet.
The aloe plant is best adapted for arid and semi-arid climates, typically found in desert biomes. Its ability to store water in its fleshy leaves allows it to survive in dry conditions with little water available.