The red blood cells would increase in size because water is moving from the area of higher water potential the distilled water to the area of lower water potential the red blood cells until dynamic equilibrium is reached. Lab 1E Questions 1 After preparing a wet mount slide, I have observed the onion cells under magnification and they appear to be small, empty boxes pushed closely together.
Osmosis and tonicity Video transcript - Let's say that I have this green container and inside this green container I have some air molecules.
Now the air molecules, we assume that there's some temperature, there's some average kinetic energy to them but they're all going to have different velocities, they're all going to be bumping around in different ways.
Now the way that I've drawn it you might notice something. On the left hand side, and I'll just draw an imaginary line here, this line has no, no real, I guess you could say structural significance, it's not like it's actually dividing it, I'm just using it to visualize the left and right hand sides.
You see on the left hand side I have a higher concentration of my molecules, higher concentration, and how do you measure concentration? Well the number of molecules per, well the real way that you should do it is unit volume but we're looking at a cross section here.
If I were to take a section that large, look, I got four molecules here, looks like I have about four, three to five molecules per section around that size, well if I took a that size section on this side I'm getting one or maybe two molecules.
And I'm not going to get too precise but it's clear that I have a higher concentration here, I have more molecules that we have drawn at per unit area but if we're thinking in three dimensions, per unit volume, than we have on the right hand side.
So we have a higher concentration on the left, we have a lower concentration on the right, lower concentration on the right. And when you have this situation where you have a higher concentration and then a lower concentration, we call this a concentration gradient. The concentration is changing from high to low and so we call this a concentration, concentration Now what do we think is going to happen?
Let's say this is, this is what our situation is right when we look at it, what do we think is going to happen?
Well these, all of these particles are all going to be bouncing around, things get moved from the left to the right, things get moved from the right to the left, but we have more particles on the left that are likely to move to the right than we have particles on the right that are likely to move to the left.
Remember, they're all moving in different directions with these random velocities but I have more on this side and they're all bouncing around so in any given moment when we have this higher concentration on the left I have a higher chance that I'm going to have stuff go from the left to the right, go from the left to the right, than I do from the right to the left, and so as time goes on, as time goes on it's going to look something like this.
If we let this system stabilize, if we let this system stabilize for awhile it should look like this. Now let me see if I can do a good job, a good job drawing it, and I'll just draw the molecules, I won't draw their actual, their actual velocity vectors.
So if we wait awhile, how many molecules did I have, one, two, three, four, five, six, seven, eight, nine, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, 20, so now I have one, two, three, four five, six, seven, eight, nine, 10, 11, 12, 13, 14, 15, 16, 17, 18, 19, So if we let enough time go by we see that we don't, we should no longer have a concentration gradient, that the concentration should be fairly uniform over time.
So even if I were to draw that imaginary dashed line, if I were to draw that imaginary dashed line, I should have the same concentration on both sides so I no longer have a gradient, I have no gradient, and once again there's nothing magical here, it's not like the molecule said, "Oh, we are less "concentrated over there, I somehow have to know "to move there," you just have to think that these are all just randomly bouncing around and if you have a higher concentration on the left there's a higher chance that you have bounces or you have things moving from the left to the right as you do from the right to left.
Even in this situation things are still going to be moving from left to right and right to left, but now that you have the same number on either side at any given moment, in any given period of time, you have an equal probability of things moving from the left to the right as you do from the right to the left, so you're getting to kind of this equilibrium situation.
Sure, in a given, you know, if you take a certain unit of time, maybe that one moves from the left to the right, that one moves from the left to the right, that one moves from the left to the right, but since you have equal concentrations on both sides you're just as likely to have the same number move from right to left.
And I only did this with 20, I only did this with 20 particles, which is a little bit of an artificially low number. If we're actually talking about concentrations of air molecules or as we'll see when we think about cellular membranes, if we think about different types of molecules that might be in an aqueous solution, we're talking about way more than 20 molecules and so you really do think in terms of probabilistic large numbers, well hey, the probability of something moving from the left to the right is the same as the right to left, and so you're going to have this stability.
Right here there's a much higher probability in any given moment of something moving from left to right than right to left and that's why you see things moving from high concentration to low concentration.
Or another way to think about it, what we just observed here is we saw things diffusing down their conf-- down their concentration gradient. So this process that we just described, this is diffusion, this is diffusion, and as we study different types of systems we'll see that this is actually very important to biological systems and even chemical systems because this doesn't require any extra energy to move the molecules from here to there, it's going to happen probabilistically, it's going to happen naturally and once again, no magic, just more stuff here, higher chance moving from left to right than moving from right to left.
And I really want to make that point clear. You can still move from right to left, for example you might have this character, maybe his, maybe instead of moving in that direction completely possible, completely possible that he goes from right to left.
It's not like everything is moving from left to right but you have a higher chance, you're going to have more things moving from left to right, so that guy could move in that direction because there's just more stuff here.
They're all bouncing around in all, in all different, in all different random directions.rutadeltambor.com is a leading medical & health education platform with an audience of over , current & future clinicians & caregivers.
Lab Report On Egg Osmosis Words | 5 Pages. Egg Osmosis Lab Report Yen Do Period 2 Introduction: Cells in all living things have an outer layer known as the cell membrane. The structure of the cell membrane consists of the phospholipid bilayer organized by the arrangement of hydrophilic heads and hydrophobic tails. The processes of diffusion and osmosis account for much of the passive movement of molecules at the cellular level. In this laboratory, you will study some of the basic principles of molecular movement in solution and perform a series of activities to investigate these processes. View Lab Report - Osmosis Lab Report from BIO at University of Wisconsin, La Crosse. Osmosis Lab Report Introduction Osmosis is the diffusion of water across the semi-permeable membrane in a%(6).
Our vision: Everyone. Science Coursework Osmosis Plan An introduction to osmosis. The movement of water molecules from a high concentration of water molecules to a lower concentration of water molecules through a partially permeable membrane is called Osmosis.
Under normal conditions, the concentration of water molecules and salts is the same in both cells and. This activity provides a sequence of learning activities designed to optimize student learning and understanding of osmosis by beginning with a student investigation of osmosis at the macroscopic level and then moving to analyzing osmosis at the molecular and cellular levels.
Intro and Biological Molecules. Is Yeast Alive? (hands-on. Sample potato osmosis lab report. To receive the best grade in potato cells lab report,we recommend the below format which we have clearly explained it for you in a simple manner. Kindly consult our experts for more detailed report per your instructions and academic level.
The processes of diffusion and osmosis account for much of the passive movement of molecules at the cellular level. In this laboratory, you will study some of the basic principles of molecular movement in solution and perform a series of activities to investigate these processes.
Osmosis Lab Introduction: Cells have kinetic energy.
This causes the molecules of the cell to move around and bump into each other. Diffusion is one result of this molecular movement. Diffusion is the random movement of molecules from an area of higher concentration to areas of lower concentration.