Stomata are small openings on the surface of leaves that facilitate gas exchange, allowing carbon dioxide to enter and oxygen to exit. The intercellular spaces in mesophyll tissue are air-filled cavities that connect with the stomata, enabling the diffusion of gases between the internal leaf environment and the atmosphere. Together, stomata and intercellular spaces play a crucial role in photosynthesis and respiration by ensuring a continuous supply of gases to the mesophyll cells.
Stomata are small openings on the surface of leaves that facilitate gas exchange between the atmosphere and the internal tissues of the plant. They connect to intercellular spaces within the mesophyll tissue, allowing carbon dioxide to enter for photosynthesis and oxygen to exit as a byproduct. The intercellular spaces increase the surface area available for gas diffusion, enhancing the efficiency of this exchange process. Overall, the stomata and intercellular spaces work together to optimize the plant's respiratory and photosynthetic functions.
in the stomata
through the stomata. then it enters the spongy mesophyll.
The air spaces in the spongy mesophyll connect with the exterior of the leaf through small pores called stomata. Stomata are located on the underside of the leaf and allow for gas exchange between the interior of the leaf and the surrounding environment.
In the middle of the leaf, in line with the xylem cells (under the palisade cells but above the stomata)
Leaves contain stomata for gas exchange, palisade mesophyll for photosynthesis, and vascular tissue in the midribs and veins for nutrient transport. These structures help the leaf to carry out its essential functions efficiently.
in the stomata
Oxygen enters the mesophyll cells of a green plant through small pores on the leaves called stomata. During photosynthesis, carbon dioxide is taken in through the stomata, and oxygen is released as a byproduct, diffusing from the leaves into the surrounding air.
Upper and lower epidermis, stomata and mesophyll consisting of palisade, spongy paenchyma and vascular bundles.
gas ion transfer or diffusion through cells.
Through the stomata, and dissolved at the moist cell membrane of the spongy mesophyll cell.
Leaves contain stomata for gas exchange, mesophyll tissue for photosynthesis, and vascular tissue (xylem and phloem) in the midribs and veins for transporting water and nutrients throughout the plant. These structures work together to maintain the leaf's function in the process of photosynthesis and transpiration.