Chapter 6 Laboratory: Separating Mixtures 99oALIpToN ACTIvITIES
If you have enough time and the required materials,
consider performing these optional activities:- Repeat the distillation, transferring the original
distillate to the distillation vessel for redistillation. The
volume of the second distillate will be smaller than
the volume produced during the first distillation, so
you’ll either need to distill considerably more than
100 mL originally or else use a smaller volumetric
flask to determine the density of the second distillate.
Alternatively, you can use a graduated cylinder to
determine the density of the second distillate, with
some loss of accuracy. - Run the distillation a third time, and determine the
density (and ethanol concentration) of the third
distillate.
Item DataA. Volumetric flask _________.___ gB. Volumetric flask with 100 mL 70% ethanol _________.___ gC. Mass of 100 mL 70% ethanol (B – A) _________.___ gD. Density of 70% ethanol (C/100) _________.___ g/mLE. Volumetric flask with 100 mL distilled ethanol _________.___ gF. Mass of 100 mL distilled ethanol (E – A) _________.___ gG. Density of distilled ethanol (F/100) _________.___ g/mLTABLE 6-2: Distillation of ethanol—observed and calculated data
LINGHBoGHI I poINT AzEoTRopES
Hydrochloric acid is one familiar example of a negative
(high-boiling) azeotrope. Pure hydrogen chloride has
a boiling point of -84°C and pure water a boiling point
of 100°C. A solution of 20.2% hydrogen chloride (by
weight) in water has a boiling point of 110°C, higher than
the boiling point of either component. This means that
boiling a solution of hydrochloric acid of any concentration
eventually produces a solution of exactly 20.2%
hydrogen chloride by weight. If the starting solution is
more dilute, water is driven off until the solution reaches
20.2% concentration. If the starting solution is more
concentrated, hydrogen chloride gas is driven off until the
solution reaches 20.2% concentration.