84 DIY Science: Illustrated Guide to Home Chemistry Experiments
the funnel. Make sure that all of the solid and liquid is
transferred into the funnel.
When all of the liquid has drained through the filter paper,
rinse the solid filtrand several times with a few mL of
water to make sure that all of the soluble material has
been rinsed into the receiving vessel.
If the filtrand is waste material, remove the funnel and
dispose of the filter paper and filtrand properly.
If the filtrand is your product, carefully remove the filter
paper and filtrand from the funnel and transfer them to
a Petri dish or similar container for drying. Once the filter
paper and filtrand are thoroughly dry, you can determine
their combined mass and subtract the mass of the filter
paper to determine the mass of the filtrand.
Wash and dry the funnel and any other vessels you used
and put them away.FIGURE 5-13:
Making a filter paper coneFIGURE 5-14:
Proper filtration procedureSATIEpAR oNS
In a laboratory sense, separation means physically dividing two or more immiscible liquid layers,
usually an aqueous layer and an organic layer. A separation most commonly follows an extraction,
in which a substance dissolved or suspended in one solvent is extracted from that solvent by
agitating the solution with a quantity of a second, immiscible solvent. If the solute is more soluble
in the second solvent than in the first, it is preferentially extracted into the second solvent.
Because the two liquids are immiscible, they separate upon standing into two physical layers,
which can subsequently be divided and isolated from each other.
For example, in one of the laboratory sessions later in this
book, we produce an aqueous solution that contains elemental
iodine. Iodine is relatively insoluble in water, but is very soluble
in many organic solvents. Adding a quantity of an organic
solvent to the reaction vessel and agitating the mixture allows
the iodine to migrate from the aqueous solution to the organic
solvent. Upon standing, the solvent layers separate, with the
less dense organic layer—which now contains nearly all of the
iodine—floating on top of the aqueous layer, which still contains
nearly all of the other reaction products. By drawing off and later
evaporating the organic layer, we can isolate nearly all of the
iodine in relatively pure form.
In formal laboratories, most separations are done with a
separatory flask, usually called a sep flask. If you don’t own a
sep flask, you can still do a good separation using inexpensive
standard glassware and a disposable plastic pipette. In the
following example, assume that you begin with two layers,
each of about 100 mL, in a 250 mL flask or beaker. If the
actual quantities differ significantly, you can modify this
procedure accordingly.
- First, make absolutely certain that you know which layer
contains your product and which layer is waste. Many
novice chemists have embarrassed themselves by
pouring the product layer down the drain and saving the
waste layer. In this example, we’ll assume that the top
layer is the product layer. - After allowing the two layers to separate completely,
carefully pour the top layer into your 100 mL graduated
cylinder. Make sure to get all of the top layer, and as little
as possible of the bottom layer—at most, a few mL. - Allow the layers to separate completely again, and then
pour as much as possible of the top layer into a receiving
beaker or flask, making sure that none of the bottom
layer is transferred. At this point, a few mL at most should
remain in the 100 mL graduated cylinder. - Pour the entire remaining contents of the 100 mL
graduated cylinder into your 10 mL graduated cylinder
and allow the layers to separate. - Use the disposable plastic pipette carefully to draw up as
much as possible of the top layer, as shown in Figure 5-15,
and transfer that liquid to the receiving beaker or flask.