a root hair cell increase the surface area of the root which helps it colect more water and stuff
A root hair is haploid. Root hairs are specialized structures that arise from the single-celled epidermal layer of a plant root. Each root hair cell contains a single set of chromosomes, making it haploid.
A root hair cell adapts by having a large surface area due to its long projections, enabling efficient absorption of water and nutrients from the soil. It also forms a symbiotic relationship with mycorrhizal fungi to enhance nutrient uptake. Additionally, it has a high concentration of transport proteins in its cell membrane to facilitate the movement of molecules.
The root hair cell has elongated projections that increase the surface area for absorbing water and minerals. It contains a large central vacuole to store nutrients and ions, along with a high concentration of mitochondria to generate energy for active transport. The cell wall is thin to allow for efficient exchange of substances with the surrounding soil.
the main similarity is : They both don't have chloroplast
The shape of the root hair cell increases its surface area, allowing for more efficient absorption of water and minerals from the soil. The elongated shape also helps the cell to penetrate between soil particles, enhancing nutrient uptake.
Root hair cell are dermal cells found on the roots of many vascular plants.Their job is to provide a greater surface area for water absorption.As transpiration pulls water up to the leaves, root hair cells have to absorb large amounts of water. The process by which root dermal cells take in water is osmosis. In order to diffuse large amounts of water, a cell obviously needs a large surface area. The root hair cells provide this needed extra surface area to absorb large amounts of water.
It has a large surface area for maximum absorption.
a root hair cell increase the surface area of the root which helps it colect more water and stuff
It has an extension to increase its surface area.
it has a nucleus and a cell wall it helps it carry out its job by telling it what to do
A root hair is haploid. Root hairs are specialized structures that arise from the single-celled epidermal layer of a plant root. Each root hair cell contains a single set of chromosomes, making it haploid.
Root hair cells have long, thin projections that increase surface area for absorption of water and nutrients. They have thin cell walls to facilitate osmosis and have many mitochondria to provide energy for active transport. Additionally, they are located near the root tip where soil nutrients are most abundant.
A root hair cell has a large surface area due to its long, thin shape and microscopic hair-like extensions. This structure allows for efficient absorption of water and minerals from the soil, essential for plant growth and survival. Additionally, root hair cells are packed with mitochondria to provide the energy needed for active transport of nutrients into the plant.
A palisade cell has chloroplasts in its cytoplasm to carry out photosynthesis, which root hair cells lack. Chloroplasts contain chlorophyll that captures light energy to convert it into sugars. Root hair cells, on the other hand, are specialized for absorption of water and minerals from the soil.
Root hair cell are dermal cells found on the roots of many vascular plants.Their job is to provide a greater surface area for water absorption.As transpiration pulls water up to the leaves, root hair cells have to absorb large amounts of water. The process by which root dermal cells take in water is osmosis. In order to diffuse large amounts of water, a cell obviously needs a large surface area. The root hair cells provide this needed extra surface area to absorb large amounts of water.
A root hair cell adapts by having a large surface area due to its long projections, enabling efficient absorption of water and nutrients from the soil. It also forms a symbiotic relationship with mycorrhizal fungi to enhance nutrient uptake. Additionally, it has a high concentration of transport proteins in its cell membrane to facilitate the movement of molecules.