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In an isotonic solution the cell would be unchanged. In a hypertonic solution water would flow out of the cell and it would shrink. In a hypotonic solution water would flow into the cell and it would expand like a balloon and possibly rupture.
A cell is hypertonic when it has a greater concentration than its environment, but, when a solution is hypertonic, it has a greater concentration than the cell it is being compared to. For example, a 5% salt solution is hypertonic to an onion cell while the onion cell is hypotonic to the solution.The salt concentration of an onion cell must be less than 5% - actually its somewhere between 1.6 and 1.3 percent.This question should not be in genetics, but I don't feel like switching it.
The words isotonic, hypertonic, and hypotonic refer to the relationship between two solutions. - When two solutions are isotonic to one another, the two solutions have the same amount of solute as each other. - When a solution is hypertonic in reference to another solution, that solution has more solute than the other. - When a solution is hypotonic in reference to another solution, that solution has less solute than the other. - Thus, on a scale of INCREASING solutes, you could align three solutions like this: hypotonic --> isotonic --> hypertonic. Secondly, since substances move from a region of high concentration (more solute) to low concentration (less solute), remember that solutes will always move from a hypertonic solution to a hypotonic solution OR solvents will always move from a hypotonic solution to a hypertonic solution. A good way to remember this is to know that "hyper" means above (more than) and hypo means "below" (less than), e.g. in HYPERactive = being really energetic or more energetic than normal vs. HYPOthermia = being very cold or below the normal temperature. A way to figure out whether a solution is isotonic, hypertonic, or hypotonic in respect to another solution is to figure out the solutions tonacities. Tonacity is the measure of solute in a solution. Therefore, something hypertonic has more tonacity or more solute than another solution. Some people learn the term "solute potential," which has a similar concept to tonacity. Examples: A 0.4 mol glucose solution is isotonic to a 0.4 mol glucose solution. A 0.4 mol glucose solution is hypertonic to a 0.2 mol glucose solution. A 0.2 mol glucose solution is hypotonic to a 0.4 mol glucose solution.
The best environment for cosmos is, inside The tropical rain forests provide best environment for plants to grow very fast.
vinegar is a hypotonic solution if you would like an example take an egg and put it in to a glass of vinegar and the egg will swell.
In an isotonic solution the cell would be unchanged. In a hypertonic solution water would flow out of the cell and it would shrink. In a hypotonic solution water would flow into the cell and it would expand like a balloon and possibly rupture.
A cell is hypertonic when it has a greater concentration than its environment, but, when a solution is hypertonic, it has a greater concentration than the cell it is being compared to. For example, a 5% salt solution is hypertonic to an onion cell while the onion cell is hypotonic to the solution.The salt concentration of an onion cell must be less than 5% - actually its somewhere between 1.6 and 1.3 percent.This question should not be in genetics, but I don't feel like switching it.
Hypertonic solutions contain higher concentrations of various dilutes than blood, Isotonic solutions contain the same concentrations, and Hypotonic solutions contain less of its dilute components than blood. As such, you might deliver hypertonic saline to a patient who is electrolytically depleted, an isotonic to a patient whose blood chemistry is good but is hypovolemic, and a hypotonic like D5W to a dehydrated patient whose electrolytes are very high in spite of the dehydration. It's a way of adding fluids and trying to balance the blood chemistry at the same time.
The words isotonic, hypertonic, and hypotonic refer to the relationship between two solutions. - When two solutions are isotonic to one another, the two solutions have the same amount of solute as each other. - When a solution is hypertonic in reference to another solution, that solution has more solute than the other. - When a solution is hypotonic in reference to another solution, that solution has less solute than the other. - Thus, on a scale of INCREASING solutes, you could align three solutions like this: hypotonic --> isotonic --> hypertonic. Secondly, since substances move from a region of high concentration (more solute) to low concentration (less solute), remember that solutes will always move from a hypertonic solution to a hypotonic solution OR solvents will always move from a hypotonic solution to a hypertonic solution. A good way to remember this is to know that "hyper" means above (more than) and hypo means "below" (less than), e.g. in HYPERactive = being really energetic or more energetic than normal vs. HYPOthermia = being very cold or below the normal temperature. A way to figure out whether a solution is isotonic, hypertonic, or hypotonic in respect to another solution is to figure out the solutions tonacities. Tonacity is the measure of solute in a solution. Therefore, something hypertonic has more tonacity or more solute than another solution. Some people learn the term "solute potential," which has a similar concept to tonacity. Examples: A 0.4 mol glucose solution is isotonic to a 0.4 mol glucose solution. A 0.4 mol glucose solution is hypertonic to a 0.2 mol glucose solution. A 0.2 mol glucose solution is hypotonic to a 0.4 mol glucose solution.
Tonicity is the osmotic pressure gradient between two solutions separated by a semipermeable membrane.Assuming a balloon-like structure filled with vegetable oil is submerged in water, as vegetable oil is less dense than water, water would attempt to enter the balloon-like structure. Therefore, it would be hypotonic.
Animal cells do not have rigid cell walls. When they are exposed to hypertonic solutions, water rushes out of the cell causing it to shrink.
Salt water. Salt water is very hypotonic and will force the egg to float. Regular water is hypertonic and force water in. Causing the egg to sink like the Titanic.
A hypotonic solution has less than normal tension: hypo = less, and tonic = tonicity, the concentration of solute. Examples of hypotonic solutions: (1) Sports drinks that contain salts / electrolytes (2) physiologically: a. 0.45% NaCl (half-normal saline solution); since normal saline is 0.9% NaCl, any solution less than 9% is hypotonic b. dextrose 2.5% in water c. dextrose 2% in water
within the seedless plants category
The physical environment refers to things like mountains and rivers where living things live. The biological environment refers to the parts of the living plants and and animals where living things live.
A non-example of a habitat would be somthing like river, ocean,and lake.
so they can fertalize