Please answer this question:


-My graph shows:
Higher temperature=higher absorption rate for each temperature (best fit line)

Fluid mosaic model theory:
-Membrane composed of phospholipid bilayer
-Protein molecule float around in it
In the liquid bilayer
-Membrane particles move around
-Protein patchwork found in phospholipid Bilayer

Question:(in a paragraph)
Explain your results and the shape of your graph using theory about the fluid mosiac model

Basically, what i said about my graph above is the results and i explained the trend too

Based on the fluid mosaic model theory, the structure of the membrane is composed of a phospholipid bilayer with protein molecules floating around in it. The movement of membrane particles and the presence of protein patches contribute to the overall permeability of the membrane.

In the experiment investigating the effect of temperature on membrane permeability using beetroot, the graph shows that as the temperature increases, the absorption rate also increases. This observation can be explained using the fluid mosaic model theory.

At higher temperatures, the fluidity of the phospholipid bilayer increases, allowing the molecules to move more freely and increase the permeability of the membrane. Additionally, the increase in temperature may cause the proteins to undergo conformational changes, leading to larger gaps or openings in the protein patchwork, which further enhances the permeability.

Therefore, the higher absorption rate observed at higher temperatures in the graph aligns with the predictions of the fluid mosaic model theory, which suggests that increased temperature results in increased membrane permeability.

Based on the theory of the fluid mosaic model, the membrane is composed of a phospholipid bilayer with protein molecules floating around in it. This means that the membrane is not static but rather dynamic, with particles constantly moving and interacting with each other.

In the context of the effects of temperature on membrane permeability, the higher the temperature, the higher the absorption rate observed in the beetroot experiment. This is reflected in the shape of the graph, where the absorption rate increases as the temperature increases. This can be explained by the fluid nature of the membrane.

At higher temperatures, the particles in the membrane have greater kinetic energy, leading to increased movement and fluidity. This increased fluidity allows for greater movement of the phospholipids and protein molecules within the membrane. As a result, the phospholipids become more spaced out, creating gaps or openings in the membrane structure.

These gaps or openings in the membrane allow molecules, such as the pigment in beetroot cells, to pass through more easily. Therefore, at higher temperatures, there is an increased permeability of the membrane, resulting in a higher absorption rate of the pigment.

In summary, the fluid mosaic model explains the observed results, where an increase in temperature leads to a higher absorption rate, by considering the dynamic nature of the membrane and how it affects the movement and arrangement of its constituents.