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Experiment Three – The Use of Volumetric Glassware
Objective
Familiarity with the various instruments used for making physical measurements in the
laboratory is essential to the study of experimental chemistry. In this experiment, you will
investigate the uses and limits of the various types of volumetric glassware.
Introduction Most of the glassware in your laboratory has been marked by the manufacturer to indicate the
volume contained by the glassware when filled to a certain level. The graduations etched or painted
onto the glassware by the manufacturer differ greatly in the precision they indicate, depending on
the type of glassware and its intended use. For example, beakers and Erlenmeyer flasks are marked
with very approximate volumes, which serve merely as a rough guide to the volume of liquid in
the container. Other pieces of glassware, notably burets, pipets, and graduated cylinders, are
marked much more precisely by the manufacturer to indicate volumes. It is important to distinguish
when a precise volume determination is necessary and appropriate for an experiment and when
only a rough determination of volume is needed. This manual attempts to be nonspecific when
describing situations when the volume is important (for example, “add a few milliliters of water”),
and explicit when the volume is important (for example, “pipet exactly 1.0 milliliters of the
mixture).
A. Graduated Cylinders
The most common apparatus for routine determination of liquid volumes is the graduated cylinder.
Although a graduated cylinder does not permit as precise a determination of volume as do other
volumetric devices, for many applications the precision of the graduated cylinder is sufficient.
Figures 2-1 and 2-2 show typical graduated cylinders. In Figure 2-1, notice the plastic safety ring,
which helps to keep the graduated cylinder from breaking if it is tipped over. In Figure 2-2,
compare the difference in graduations shown for the 10-mL and 100-mL cylinders. Examine the
graduated cylinders in your lab locker, and determine the smallest graduation of volume that can
be determined with each cylinder.
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When water (or an aqueous solution) is contained in a narrow glass container such as a graduated
cylinder, the liquid surface is not flat as might be expected. Rather, the liquid surface is curved
downward (see Figure 2-3). This curved surface is called a meniscus and is caused by an
interaction between the water molecules and the molecules of the glass container wall. When
reading the volume of a liquid that makes a meniscus, hold the gradated cylinder so that the
meniscus is at eye level, and read the liquid level at the bottom of the curved surface (that is,
tangent to the curved surface).
B. Pipets When a more precise determination of liquid volume is needed than can be provided by a graduated
cylinder, a transfer pipet may be used. Pipets are especially useful if several measurements of the
same volume are needed (such as in preparing similar-sized samples of a liquid substance). Two
types of pipet are commonly available, as indicated in Figure 2-4. The Mohr pipet is calibrated at
least at each milliliter and can be used to deliver any size sample (up to the capacity of the pipet).
The volumetric transfer pipet can deliver only one size sample (as stamped on the barrel of the
pipet), but generally it is easier to use and the results more reproducible.
Pipets are filled using a rubber safety bulb to supply the suction needed to draw liquid into the
pipet. It is absolutely forbidden to pipet by mouth in the chemistry laboratory. Two common types
of rubber safety bulbs are shown in Figure 2-5.
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The simple bulb should not actually be placed onto the barrel of the pipet. This would be likely to
cause the liquid being measured to be sucked into the bulb itself. Rather, squeeze the bulb, and
just gently press the opening of the bulb against the opening in the barrel of the pipet to apply the
suction force, keeping the tip of the pipet under the surface of the liquid being sampled. Do not
force the pipet into the plastic tip of the safety bulb, or the pipet may break. Allow the suction to
draw liquid into the pipet until the liquid level is 1 or 2 inches above the calibration mark on the
barrel of the pipet. At this point, quickly place your index finger over the opening at the top of the
pipet to prevent the liquid level from falling. By gently releasing the pressure of your index finger,
you can allow the liquid level to fall until it reaches the calibration mark of the pipet. The tip of
the pipet may then be inserted into the container that is to receive the sample and the pressure of
the finger removed to allow the liquid to flow from the barrel of the pipet. (See Figure 2-6.)
Finally, glassware is intended to contain or to deliver specific volumes and is generally marked on
the glassware with the markings “TC” (to contain) and “TD” (to deliver). They may sound the
same, but please keep in mind there is a slight difference. A flask or beaker would be marked as
TC, implying that it contains a specific amount of liquid. A pipet on the other hand is designed to
deliver a very accurate and precise amount, so a pipette marked “TD 10mL” will deliver 10.00mL
of liquid. The remaining liquid in the tip is there by design; 10.00mL has been delivered to the
container and any remaining liquid in the tip is not needed. So when using a pipette it’s very
important to recognize the last remaining liquid is supposed to remain there, don’t force it out.
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When using either type of pipet, observe the following rules:
1. The pipet must be scrupulously clean before use: wash with water, rinse with tap water,
and then rinse with distilled water. If the pipet is clean enough for use, the water will not
bead up anywhere on the inside of the barrel.
2. To remove rinse water from the pipet (to prevent dilution of the solution to be measured),
rinse the pipet with several small portions of the solutions to be measured, discarding
the rinsing in a waste beaker for disposal. It is not necessary to fill the pipet completely with
the solution for rinsing.
3. The tip of the pipet must be kept under the surface of the liquid being measured out
during the entire time suction is being applied, or air will be sucked into the pipet.
4. Allow the pipet to drain for at least a minute when emptying to make certain the full capacity
of the pipet has been delivered. Remove any droplets of liquid adhering to the tip of the pipet
by touching the tip of the pipet to the side of the vessel that is receiving the sample. Do not
blow any remaining liquid out of the pipet tip (this is allowed for in the calibration of the
pipet).
5. If you are using the same pipet to measure out several different liquids, you should rinse the
pipet with distilled water between liquids, and follow with a rinse of several small portions
of the next liquid to be measured.
C. Burets
When samples of various sizes must be dispensed or measured precisely, a buret may be used. The
buret consists of tall, narrow calibrated glass tube, fitted at the bottom with a valve for controlling
the flow of the liquid. The valve is more commonly called a stopcock (See Figure 2-7.)
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Like a pipet, a buret must be scrupulously clean before use. The precision permitted in reading a
buret is 0.02 mL, but if the buret is completely clean, this level of precision is not attainable. Rinse
the buret with tap water, followed by several rinsing with distilled water. Before use, the buret
should be rinsed with several small portions of the solution to be used in the buret. The buret
should be tilted and rotated during the rinsing, to make sure that all rinse water is washed from it.
Discard the rinsing. After use, the buret should again be rinsed with distilled water. Many of the
reagent solutions used in burets may attack the glass of the buret if they are not removed. This
would destroy the calibration.
A common mistake make by beginning students is to fill the buret with the reagent solution to be
dispensed to exactly the 0.00 mark. This is not necessary or desirable in most experiments, and it
wastes time. The buret should be filled to a level that is comfortable for you to read (based on
your height). A precise initial liquid-level reading of the buret should be taken before the solution
is dispensed and again after the liquid is dispensed. The readings should be made to the nearest
0.02 mL. The volume of liquid dispensed is then obtained by simple subtraction of the two volume
readings. Always use a funnel when filling a buret, and always have the buret top below the eye
level when you are adding liquid.
Calculations
Density Calculations
In several places in the experiment, you will be asked to use the Water Density Table which lists
the density of water at various temperatures, so you can compare the volume as delivered by the
pipet or buret (this is what you observed during the experiment, quick, but not as accurate), with
the volume calculated from the mass of the water transferred (calculation offers much better
precision, but requires more time in the lab). Since the determination of mass is typically more
precise than the determination of volume, this serves as a check on the calibration marks on the
pipet or buret, and also on your skill in using them.
𝑑 =𝑚
𝑉
Suppose we measure the mass of a “5 mL” sample of water at 22°C and find it weighs 5.015 g.
Using the density of water at 22°C from Water Density Table (0.99780 g/mL), the calculated
volume of the sample of water would be given by
Volume = mass/density =5.015g/0.99780g/mL = 5.026 mL
Percent Error
Percentage error is a way to check your experimental technique as well as the equipment used,
against what is accepted by the science community. The percent error is based on the
experimentally determined values obtained by a student in the lab, against the literature values
accepted by science. If percent error is high it’s an indication that there is an experimental issue:
human error as a result of poor technique or flawed equipment providing inaccurate measurements;
most often it’s a combination of the two.
% 𝑒𝑟𝑟𝑜𝑟 =𝑒𝑥𝑝𝑒𝑟𝑖𝑚𝑒𝑛𝑡𝑎𝑙 𝑣𝑎𝑙𝑢𝑒 − 𝑙𝑖𝑡𝑒𝑟𝑎𝑡𝑢𝑟𝑒 𝑣𝑎𝑙𝑢𝑒
𝑙𝑖𝑡𝑒𝑟𝑎𝑡𝑢𝑟𝑒 𝑣𝑎𝑙𝑢𝑒𝑥100
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Procedure
Record all data and observations in the space provided below, please write legibly.
Materials/Reagents Required
25 mL graduated cylinder
25 mL volumetric pipet and safety bulb
buret and clamp & stand
50 mL and 150 mL beakers
distilled water
thermometer
250 mL Erlenmeyer flask
A. The Graduated Cylinder
Part I – Your instructor will set up a display of several graduated cylinders filled with different
amount of colored water. Several sizes of cylinder are available (10-mL, 25-mL, 50-mL, and 100-
mL).
1. Examine each cylinder, paying particular attention to the marked scale divisions on the
cylinder. Read and record the volume of liquid contained in each graduated cylinder. Make
your reading to the level of precision permitted by each of the cylinders.
Check your readings of the liquid levels with the instructor before proceeding, and ask for
assistance if your reading differ from those provided by the instructor.
Part II – Fill a 250 mL Erlenmeyer flask with distilled water, place the thermometer in it. Place it
on the lab station to be used throughout this experiment.
1. Clean and wipe dry a 25-mL graduated cylinder and a 50-mL beaker (a rolled up paper
towel will enable you to dry the interior of the graduate). Weigh the beaker and record the
mass to the nearest milligram (0.01 gram). Record this value as “Mass of Beaker (empty)”
in your data section.
2. Fill the 25 mL graduated cylinder with distilled water, from your flask, so that the meniscus
of the water level lines up with the 25-mL calibration mark of the cylinder. Record the
volume in the graduated cylinder to the nearest centiliter (0.01 liter). Record this value as
“Volume of Water (observed)” in your data section.
3. Place distilled water in the 50-mL beaker from the graduated cylinder. (DO NOT add water
while the beaker is still on the balance; an accidental spill could damage the balance).
4. Weigh the 50-mL beaker, with the water, to the nearest milligram (0.01 gram) and record
this value as “Mass of Beaker + Water” in the data section.
5. Calculate the mass of the water delivered and record this value as “Mass of Water” in your
data section.
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6. Using the temperature of your water to determine the density of your water using the water
density table on page 13. Use the density from the table and the mass of your water to
calculate an accurate volume of water present in the beaker. Record this value as “Volume
of Water (calculated)” in your data section.
7. Compare the calculated volume of water (based on the mass of water) to the observed
volumes of water determined from the calibration marks on the graduated cylinder.
Calculate the percentage difference (% error) between the calculated volume of water and
the observed volume from the calibration marks on your graduated cylinder.
B. The Pipet Obtain a 25ml volumetric pipet and rubber safety bulb. Clean the pipet with tap water followed by
distilled water. Practice filling and dispensing distilled water from the pipet until you feel
comfortable with the technique. Ask you instructor for assistance if you have any difficulties in
the manipulation.
1. Clean and wipe dry a 150-mL beaker. Weigh the beaker to the nearest milligram (0.01g).
Record this value as “Mass of Beaker (empty)” in your data section.
2. Pipet 25.00 mL of the distilled water, from the flask on your lab station, into the clean
beaker you have weighed. Record this value as “Volume of Water (observed)” in your data
section.
8. Weigh the 150-mL beaker, with the water, to the nearest milligram (0.01 gram) and record
this value as “Mass of Beaker + Water” in the data section.
9. Calculate the mass of the water delivered and record this value as “Mass of Water” in your
data section.
10. Using the density value (from Section A, Part II) and the mass of the water, to calculate an
accurate volume of water present in the beaker. Record this value as “Volume of Water
(calculated)” in your data section.
11. Compare the calculated volume of water (based on the mass of water) to the observed
volumes of water determined from the calibration marks on the pipet. Calculate the
percentage difference (% error) between the calculated volume and the observed volume
from the calibration marks.
Compare the volume of water transferred (as determined by reading the pipet) with the calculated
volume of water (from the mass determinations). If there is any significant difference between the
two volumes you probably need additional practice in the operation and reading a pipet.
C. The Buret Obtain a buret and set it up in a clamp on your lab bench. Fill the buret with tap water, and check
to make sure that there are no leaks from the stopcock before proceeding. If the stopcock leaks,
have the instructor examine the stopcock to make sure that all the appropriate washers are present.
If the stopcock cannot be made leak proof, replace the buret.
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1. Fill the buret with distilled water to a point somewhat below the zero mark. Determine the
precise liquid level in the buret to the nearest 0.01 mL. Record this value as “Volume of
Water (initial)” in your data section.
2. Clean and wipe dry a 150-mL beaker. Weigh the beaker to the nearest milligram (0.01g).
Record this value as “Mass of Beaker (empty)” in your data section.
3. Place the weighted beaker beneath the stopcock of the buret. Open the stopcock of the buret
and run water into the beaker until approximately 25 mL of water has been dispensed.
Determine the precise liquid level in the buret to the nearest 0.01 mL. Record this value as
“Volume of Water (final)” in your data section.
4. Calculate the volume of water that has been dispensed from the buret by subtraction of
(final volume – initial volume) = total volume delivered. Record this value as “Volume
of Water (observed)” in your data section.
5. Weigh the 150-mL beaker, with the water, to the nearest milligram (0.01 gram) and record
this value as “Mass of Beaker + Water” in the data section.
6. Calculate the mass of the water delivered and record this value as “Mass of Water” in your
data section.
7. Using the density value (from Section A, Part II) and the mass of the water, to calculate
an accurate volume of water present in the beaker. Record this value as “Volume of
Water (calculated)” in your data section.
8. Compare the calculated volume of water (based on the mass of water) to the observed
volumes of water determined from the calibration marks on the buret. Calculate the
percentage difference (% error) between the calculated volume and the observed volume
from the calibration marks.
Compare the volume of water transferred (as determined by reading the buret) with the calculated
volume of water (from the mass determinations). If there is any significant difference between the
two volumes you probably need additional practice in the operation and reading of the buret.
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A. The Graduated Cylinder
Part I
Cylinder Observed
Volume Uncertainty in your reading (pick one)
10ml
________
±10ml
±1ml
±0.1ml
±0.01ml
50ml
________
±10ml
±1ml
±0.1ml
±0.01ml
500ml
________
±10ml
±1ml
±0.1ml
±0.01ml
Check your readings of the liquid levels with the instructor before proceeding
Instructor’s signature: _________________
Part II
Mass of Beaker (empty): __________
Mass of Beaker + Water: __________
Mass of Water: __________
Volume of Water (observed): __________
Density of Water (from density table): __________
Volume of Water (calculated): __________
Difference: observed volume – calculated volume: __________
Calculations for % Error:
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B. The Pipet
Mass of Beaker (empty): __________
Mass of Beaker + Water: __________
Mass of Water: __________
Volume of Water (observed): __________
Density of Water (from density table): __________
Volume of Water (calculated): __________
Difference: observed volume – calculated volume: __________
C. The Buret
Mass of Beaker (empty): __________
Volume of Water (initial): __________
Volume of Water (final): __________
Volume of Water (observed): __________
Mass of Beaker + Water: __________
Mass of Water: __________
Density of Water (from density table): __________
Volume of Water (calculated): __________
Difference: observed volume – calculated volume: __________
Calculations for % Error:
Calculations for % Error:
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Post-Lab Questions
1. Define the following terms: (Use your lecture notes or this lab, not Google!)
a. Precision –
b. Accuracy –
c. % error –
2. Based on your results in this experiment, briefly discuss the relative precision
and accuracy permitted by each piece of lab equipment below:
Equipment Precision Accuracy
graduated cylinder
high high
moderate moderate
low low
pipet
high high
moderate moderate
low low
buret
high high
moderate moderate
low low
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3. Each of these three types of glassware has its advantages and disadvantages
with regard to ease of use. Please briefly discuss below.
Glassware Advantage Disadvantage
Graduated
Cylinder
Pipet
Buret
4. Suppose a 1.0-mL air bubble is trapped in the tip of your buret and you don’t
notice it before measuring out liquid samples with the buret. What percentage
error would be introduced in a 35.0mL sample of liquid if the air bubble comes
out of the tip of the buret while the liquid sample is being transferred? (Show
calculations for full credit!!!!)