Elodea have a more rigid shape. Elodea cells have a cell wall, chloroplasts, and are square shaped. Animal Cells are round, don't have cell walls just a membrane, and because they are heterotrophic they don't have chloroplasts.
Yes, the elodea leaf will likely swell up in 5% saline water due to osmosis. The higher concentration of salt outside the leaf will cause water to move into the leaf cells, leading to an increase in turgor pressure and swelling.
The hypothesis of an osmosis lab with an Elodea leaf could be that the Elodea leaf will lose water and shrink when placed in a hypertonic solution due to water moving out of the leaf cells by osmosis, causing the cells to become flaccid. Conversely, if the Elodea leaf is placed in a hypotonic solution, it may gain water, swell, and become turgid as water moves into the leaf cells via osmosis.
The human epithelial cells are thick and boxlike whereas elodea cells are thin and platelike. The cells of elodea are rigid and rectangular in shape.
Elodea is an aquatic plant commonly known as waterweed. It belongs to the genus Elodea within the family Hydrocharitaceae. Elodea is often used in biology classrooms for studying plant cells and photosynthesis.
Elodea leaf cells have chloroplasts, which are responsible for photosynthesis, a process that converts light energy into chemical energy. This is a unique organelle not found in animal cells. The central vacuole in Elodea leaf cells helps maintain turgor pressure, providing rigidity to the cell and aiding in photosynthesis, another feature not typically found in animal cells.
The lower epidermis of the elodea leaf has the largest cell.
Yes, the elodea leaf will likely swell up in 5% saline water due to osmosis. The higher concentration of salt outside the leaf will cause water to move into the leaf cells, leading to an increase in turgor pressure and swelling.
The hypothesis of an osmosis lab with an Elodea leaf could be that the Elodea leaf will lose water and shrink when placed in a hypertonic solution due to water moving out of the leaf cells by osmosis, causing the cells to become flaccid. Conversely, if the Elodea leaf is placed in a hypotonic solution, it may gain water, swell, and become turgid as water moves into the leaf cells via osmosis.
An Elodea leaf belongs in the domain Eukarya, as it is a complex, multicellular organism with cells that contain a true nucleus.
The human epithelial cells are thick and boxlike whereas elodea cells are thin and platelike. The cells of elodea are rigid and rectangular in shape.
Due to plasmolysis
hi man fhbehfsdv fjs retert
When an elodea leaf is mounted on a 10 percent salt solution, the cells of the leaf will lose water through osmosis. This will cause the cells to shrink and the leaf to become flaccid. The high salt concentration outside the cells will create a hypertonic environment, leading to water moving out of the cells to try to balance the concentration of solutes.
Elodea is an aquatic plant commonly known as waterweed. It belongs to the genus Elodea within the family Hydrocharitaceae. Elodea is often used in biology classrooms for studying plant cells and photosynthesis.
Elodea leaf cells have chloroplasts, which are responsible for photosynthesis, a process that converts light energy into chemical energy. This is a unique organelle not found in animal cells. The central vacuole in Elodea leaf cells helps maintain turgor pressure, providing rigidity to the cell and aiding in photosynthesis, another feature not typically found in animal cells.
When you deal with problems like this, you need to consider diffusion and osmosis. In this case, you would refer to diffusion, which is the movement of water across a membrane from high concentrations to low concentrations (to try to balance the concentrations). First consider what happens to the cells when you place the elodea leaf in the salt solution; the water in the cells tries to balance the high concentration of salt (sodium chloride) in the surrounding solution, so the water leaves the leaf, thus the cells shrink. Now when you put the elodea leaf into regular water again, there is a higher concentration of water in the surrounding environment compared to inside the leaf's cells, so in attempt to balance concentrations, water goes INTO the cells, thus the cells in the elodea leaf swell (expand).
If the vacuoles in Elodea leaf cells are placed in distilled water, they become hypotonic. Distilled water has a lower solute concentration compared to the vacuoles of the cells, causing water to move into the cells through osmosis, leading to swelling and eventual bursting of the cells.