QUESTION IMAGE
Question
- in the diagram below, identify the type of passive transport- osmosis that is occurring.
type of osmosis
what happens to the cell?
To solve this, we analyze osmosis types (hypotonic, isotonic, hypertonic) by cell-water movement:
First Column (Left)
Step 1: Identify Osmosis Type
If the small cell (e.g., a red blood cell) swells (water enters), the solution outside is hypotonic (lower solute, higher water potential than the cell).
Step 2: What Happens to the Cell?
Water moves into the cell (osmosis, passive transport). The cell swells (may lyse if animal cell, becomes turgid if plant cell).
Second Column (Middle)
Step 1: Identify Osmosis Type
If the cell’s size stays the same, the solution is isotonic (equal solute/water potential to the cell).
Step 2: What Happens to the Cell?
Water moves in and out at equal rates. No net change in cell size/shape.
Third Column (Right)
Step 1: Identify Osmosis Type
If the small cell shrinks (water exits), the solution outside is hypertonic (higher solute, lower water potential than the cell).
Step 2: What Happens to the Cell?
Water moves out of the cell. The cell shrinks (crenates in animal cells, plasmolyzes in plant cells).
Filling the Table (Assuming Common Cell Examples: Red Blood Cells)
| Type of Osmosis | What happens to the cell? |
|---|---|
| Isotonic | No net change (water moves in/out equally). |
| Hypertonic | Cell shrinks (crenates) as water exits. |
(Note: The diagram’s visual cues (e.g., arrow direction, cell size change) confirm these:
- Hypotonic: Arrows into the small cell (swelling).
- Isotonic: Arrows balanced (no size change).
- Hypertonic: Arrows out of the small cell (shrinking).)
Final table entries depend on the diagram’s specific cell/solution interactions, but the above logic applies.
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To solve this, we analyze osmosis types (hypotonic, isotonic, hypertonic) by cell-water movement:
First Column (Left)
Step 1: Identify Osmosis Type
If the small cell (e.g., a red blood cell) swells (water enters), the solution outside is hypotonic (lower solute, higher water potential than the cell).
Step 2: What Happens to the Cell?
Water moves into the cell (osmosis, passive transport). The cell swells (may lyse if animal cell, becomes turgid if plant cell).
Second Column (Middle)
Step 1: Identify Osmosis Type
If the cell’s size stays the same, the solution is isotonic (equal solute/water potential to the cell).
Step 2: What Happens to the Cell?
Water moves in and out at equal rates. No net change in cell size/shape.
Third Column (Right)
Step 1: Identify Osmosis Type
If the small cell shrinks (water exits), the solution outside is hypertonic (higher solute, lower water potential than the cell).
Step 2: What Happens to the Cell?
Water moves out of the cell. The cell shrinks (crenates in animal cells, plasmolyzes in plant cells).
Filling the Table (Assuming Common Cell Examples: Red Blood Cells)
| Type of Osmosis | What happens to the cell? |
|---|---|
| Isotonic | No net change (water moves in/out equally). |
| Hypertonic | Cell shrinks (crenates) as water exits. |
(Note: The diagram’s visual cues (e.g., arrow direction, cell size change) confirm these:
- Hypotonic: Arrows into the small cell (swelling).
- Isotonic: Arrows balanced (no size change).
- Hypertonic: Arrows out of the small cell (shrinking).)
Final table entries depend on the diagram’s specific cell/solution interactions, but the above logic applies.