What Active Transport ((free)) -

| Feature | Active Transport | Passive Transport (Diffusion/Osmosis) | | :--- | :--- | :--- | | Direction | Low → High (against gradient) | High → Low (down gradient) | | Energy Required | Yes (ATP) | No | | Protein Carriers | Yes (pumps) | Maybe (channels or carriers for facilitated diffusion) | | Equilibrium | Creates or maintains disequilibrium | Reaches equilibrium |

Antiport (move opposite directions) – Sodium-calcium exchanger. | what active transport

is the movement of molecules or ions across a cell membrane against their concentration gradient (from an area of low concentration to an area of high concentration). Because this movement opposes the natural tendency of diffusion, it requires an input of chemical energy . | Feature | Active Transport | Passive Transport

Active transport is a vital, energy-driven process that allows cells to control their internal environment with precision. While passive transport handles equilibrium-based needs, active transport creates the disequilibrium —the differences in concentration and charge—that makes life processes like thinking, moving, and growing possible. Without it, cells would be at the mercy of their surroundings and could not maintain the order necessary for life. Active transport is a vital, energy-driven process that

| Type | Energy Source | Mechanism | Example | | :--- | :--- | :--- | :--- | | | Direct (ATP) | Uses a pump that directly hydrolyzes ATP to move solutes. | Sodium-Potassium pump, Calcium pump (moves Ca2+ out of cytoplasm). | | Secondary | Indirect (Ion gradient) | Uses the energy stored in an ion gradient (created by primary transport) to drag another molecule along. | Symport (both move same direction) – Sodium-glucose symporter (Na+ flows down its gradient, pulling glucose against its gradient into the cell).