Illustrated Guide to Home Chemistry Experiments

(Amelia) #1
Chapter 3: Equipping a Home Chemistry Laboratory 31

TABLE 3-3: Recommended supplemental laboratory glassware also have a minimum capacity, below which their readings
may be inaccurate.


Reasonably high capacity is important, because you will often
tare and weigh by difference. For example, before you begin
a procedure, you may weigh the beaker in which the reaction
will take place. Rather than weighing reagents directly, you
place the beaker on the balance and use the tare function to
“zero out” the balance, so that the balance shows a weight
of zero with the beaker on it. You then add the reagents to
the beaker. You can read the weight of the first reagent you
add directly on the display. You can determine the weight
of the second reagent you add by subtracting the original
weight from the new weight, and so on. When the reaction
is complete, you can filter the precipitate and determine the
weight of the product.

Accuracy and precision
Accuracy and precision (also called repeatability) are
separate but related characteristics. Accuracy specifies how
closely a balance indicates the true weight of a sample. For
example, if you weigh a calibration weight with a known weight
of 100.0000 g, an accurate balance indicates that weight to
within its resolution (e.g., an accurate centigram balance reads
100.00 g, and an accurate milligram balance reads 100.000 g).

Precision or repeatability specifies how closely repeated
weighings of the same sample agree. For example, if you weigh
the calibration weight nine times, a precise but inaccurate
balance may report weights of 100.83 g seven times, 100.82 g
once, and 100.84 g once. Although the indicated weights are far
from the true weight, which means the balance is inaccurate,
the separate weighings agree closely, which means the balance
is precise. Conversely, an accurate but imprecise balance may
report weights of 99.96 g, 99.97 g, 99.98 g, 99.99 g, 100.00 g,
100.01 g, 100.02 g, 100.03 g, and 100.04 g. No two weighings
gave the same result, which means the balance is imprecise,
but none of the results differed much from the actual weight,
which means the balance is accurate.

Repeatability is more important than accuracy. An inaccurate
balance can be calibrated by using a known weight and
adjusting the display accordingly. An imprecise balance cannot
be adjusted to be more precise.

Linearity
Linearity specifies the accuracy and precision of a balance
across its range of capacities from minimum to maximum. For
example, a centigram balance with a 200 g capacity should
have similar accuracy and precision whether you are weighing
a 1 g sample or a 195 g sample. The best way to test the
linearity of a balance is to weigh multiple items individually and
then together. For example, you might weigh three labeled bolts

SRISE oU SCIENCE
The major factor that relegates even the best
chemistry sets to the realm of scientific toys rather
than serious tools for doing real science is their lack of a
decent balance. There’s only so far you can go in learning
chemistry if your measurement methods consist of
using a scoop of this or three drops of that. Chemistry
in general and lab work in particular is founded on
accurate measurements, which makes a good balance
indispensable.

and get results of 34.18 g for bolt A, 44.77 g for bolt B, and 61.29
g for bolt C. When you weigh bolts A and B together, a balance
with good linearity will read 78.95 g (34.18 g + 44.77 g = 78.95
g). When you weigh bolts A, B, and C together, a balance with
good linearity will read 140.24 g. Other than the least-expensive
models, most decent electronic balances have good linearity
through most of their range of capacities.

Of course, price is often a major consideration for a home lab,
but I suggest you don’t skimp too much. If you’re on a tight
budget, choose a $60 model like the My-Weigh Dura 50 Digital
Scale (0.01 g/50 g). If you can afford more, choose the $100
My-Weigh iBalance 201 (0.01 g/200 g) shown in Figure 3-19,
which is what I used for the lab sessions in this book. If you need
a milligram scale, the least expensive model I can recommend is
the $170 My-Weigh GemPro 250 (0.001 g/50 g), although I think
the $220 Acculab VIC-123 Milligram Scale (0.001 g/120 g) or the
$270 Acculab VIC-303 (0.001 g/300 g) is a much better choice.

Most laboratory supply places carry balances suitable for home
labs. The best source we know of in terms of selection and price is
Precision Weighing Balances (www.balances.com).

FIGURE 3-19: My-Weigh iBalance 201 digital balance
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