o. Ignore your calculated molarity value (from Part II: Diluting the Kool-Aid) for a second. Estimate that concentration of the Part II solution solely based on its color, compared to the 0.11M and 0.20M Kool-Aid solutions. You may provide an approximate molarity or an estimated range of concentration values. Part II: Diluting the Kool-Aid Use the formula: M1V1= M2V2 To determine the concentration of the Kool-Aid solution prepared in Part II of the proceire. It is critical that the values used for M1 and Vi both pertain to the same solution. We might start the set-up by deciding to use 22.5 mL as the Vi value. Since 22.5 mL represents the volume of 0.20M Kool-Aid solution that was added, M, must be 0.20M. V, is the total volume of the diluted solution. Since V2 is associated with the diluted solution, solving for M2 will give us the concentration of the diluted solution. MV1= M2V2 0.20M · 22.5mL = M2· 100. mL %3D

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Chapter1: Chemical Foundations
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Problem 1RQ: Define and explain the differences between the following terms. a. law and theory b. theory and...
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o. Ignore your calculated molarity value (from Part II: Diluting the Kool-Aid) for a second.
Estimate that concentration of the Part II solution solely based on its color, compared to
the 0.11M and 0.20M Kool-Aid solutions. You may provide an approximate molarity or
an estimated range of concentration values.
Part II: Diluting the Kool-Aid
Use the formula:
M1V1 = M2V2
To determine the concentration of the Kool-Aid solution prepared in Part II of the proceire. It
is critical that the values used for M, and V, both pertain to the same solution. We might start
the set-up by deciding to use 22.5 mL as the Vi value. Since 22.5 mL represents the volume of
0.20M Kool-Aid solution that was added, M, must be 0.20M. V, is the total volume of the
diluted solution. Since V2 is associated with the diluted solution, solving for M2 will give us the
concentration of the diluted solution.
M,V1= M2V2
0.20M · 22.5mL = M2· 100. mL
d. Calculate the molarity of the diluted Kool-Aid solution. Show your set-up and work.
Transcribed Image Text:o. Ignore your calculated molarity value (from Part II: Diluting the Kool-Aid) for a second. Estimate that concentration of the Part II solution solely based on its color, compared to the 0.11M and 0.20M Kool-Aid solutions. You may provide an approximate molarity or an estimated range of concentration values. Part II: Diluting the Kool-Aid Use the formula: M1V1 = M2V2 To determine the concentration of the Kool-Aid solution prepared in Part II of the proceire. It is critical that the values used for M, and V, both pertain to the same solution. We might start the set-up by deciding to use 22.5 mL as the Vi value. Since 22.5 mL represents the volume of 0.20M Kool-Aid solution that was added, M, must be 0.20M. V, is the total volume of the diluted solution. Since V2 is associated with the diluted solution, solving for M2 will give us the concentration of the diluted solution. M,V1= M2V2 0.20M · 22.5mL = M2· 100. mL d. Calculate the molarity of the diluted Kool-Aid solution. Show your set-up and work.
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