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3 years ago

During the liquid-liquid extraction of your panacetin sample, the dissolve acetylsalicylic acid (aspirin) will be in which layer

Chemistry

2 answers:

DiKsa [7]3 years ago

6 0

Answer:

Then, as mentioned, aspirin is placed in the second layer.

Explanation:

Liquid-liquid extraction is a very useful method to separate components from a mixture. It consists of separating one or several substances dissolved in a solvent by transferring them to another insoluble, or partially insoluble, solvent in the former. The transfer of matter is achieved by direct contact between the two liquid phases.

Panacetin is a mixture of sucrose, aspirin and tylenol, whose densities are respectively are 1.59 g / mL, 1.4 g / mL and 1.26 g / mL.

For the extraction process, the solution is arranged in a separating or separating funnel, an organic solvent immiscible with water is added (ethyl ether is the most used), the solution with the compound to be separated, the funnel is covered and the funnel is covered. shake According to the solubilities and density different layers are observed. The denser the compound, the more it will sink. Therefore, the upper layer is tylenol, followed by aspirin, and the lower layer is sucrose. Subsequently, by separating the separating funnel, the phases are separated.

Then, as mentioned, aspirin is placed in the second layer.

Mila [183]3 years ago

4 0

Panacetin is a mixture of three components: sucrose, aspirin and tylenol. To determine the arrangement of layers, you must research on the densities of the components. The densities of sucrose, aspirin, and tylenol are 1.59 g/mL, 1.4 g/mL and 1.26 g/mL. The more dense the component, the farther it sinks to the bottom. Thus, the topmost layer is tylenol, followed by aspirin, and the bottom layer is sucrose. <em>Therefore, aspirin is placed in the second layer.</em>

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What is the theoretical yield of aluminum that can be produced by the reaction of 60.0 g of aluminum oxide with 30.0 g of carbon

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Answer: 31.8 g

Explanation:

To calculate the moles :

$\text{Moles of solute}=\frac{\text{given mass}}{\text{Molar Mass}}$

$\text{Moles of} Al_2O_3=\frac{60.0g}{102g/mol}=0.59moles$

$\text{Moles of} C=\frac{30.0g}{12g/mol}=2.5moles$

$Al_2O_3+3C\rightarrow 2Al+3CO$

According to stoichiometry :

1 mole of $Al_2O_3$ require 3 moles of $C$

Thus 0.59 moles of $Al_2O_3$ will require= $\frac{3}{1}\times 0.59=1.77moles$ of $C$

Thus $Al_2O_3$ is the limiting reagent as it limits the formation of product and $C$ is the excess reagent as it is present in more amount than required.

As 1 mole of $Al_2O_3$ give = 2 moles of $Al$

Thus 0.59 moles of $Al_2O_3$ give = $\frac{2}{1}\times 0.59=1.18moles$ of $Al$

Mass of $Al=moles\times {\text {Molar mass}}=1.18moles\times 27g/mol=31.8g$

Thus 31.8 g of $Al$ will be produced from the given masses of both reactants.

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