Experiment
6
Boyle's Law: Pressure-Volume Relationship in
Gases.
The primary objective of this
experiment is to determine the relationship between the pressure and volume
of a confined gas. The gas we use will be air, and it will be confined in a
syringe connected to a Pressure Sensor (see Figure 1). When the volume of
the syringe is changed by moving the piston, a change occurs in the pressure
exerted by the confined gas. This pressure change will be monitored using a
Pressure Sensor. It is assumed that temperature will be constant throughout
the experiment. Pressure and volume data pairs will be collected during this
experiment and then analyzed. From the data and graph, you should be able to
determine what kind of mathematical relationship exists between the pressure
and volume of the confined gas. Historically, this relationship was first
established by Robert Boyle in 1662 and has since been
Figure 1
MATERIALS
Power Macintosh or Windows PC
Vernier Gas Pressure Sensor or Pressure Sensor
20-mL gas syringe
Vernier computer interface
Logger Pro
PROCEDURE
1. Prepare the Pressure Sensor and an air sample for data collection.
a. Plug
the Pressure Sensor into Channel 1 of the computer interface.
b. With the 20-mL syringe
disconnected from the Pressure Sensor, move the piston of the syringe until
the front edge of the inside black ring (indicated by the arrow in Figure 1)
is positioned at the 10.0 mL mark.
c. Attach the 20-mL syringe
to the valve of the Pressure.
·
Newer Vernier Gas Pressure Sensors have a white stem
protruding from the end of the sensor box-attach the syringe directly to the
white stem with a gentle half-turn.
·
Older Vernier Pressure Sensors have a 3-way valve at the end
of a plastic tube leading from the sensor box. Before attaching the 20-mL
syringe align the blue handle with the stem of the 3-way valve that
will not have the syringe connected to it, as shown in the figure at
the right-this will close this stem. Then attach the syringe directly to the
remaining open stem of the 3 way valve.
Chemistry with
Computers
6-1
2. Prepare the computer for
data collection.
- Prepare the computer
for data collection by opening the Experiment 6 folder from Chemistry
with Computers. Then open the experiment file that matches the
sensor you are using.
- On the Graph window, the
vertical axis has pressure scaled from 0 to 250 kPa. The horizontal
axis has volume scaled from 0 to 20 mL.
3.
Click Collect to begin data collection.
4. Collect the pressure
vs. volume data. It is best for one person to take care of the gas
syringe and for another to operate the computer.
a. Move the piston to position the front edge of the inside black ring (see
Figure 3) at the 5.0-mL line on the syringe. Hold the piston firmly in this
position until the pressure value stabilizes.
Figure 3
b.
When the pressure reading has stabilized, click Keep Type "5.0" in
the edit box. Press the ENTER key to keep this pair. Note: You can choose to
redo a point by pressing the ESC key (after clicking Keep , but before
entering a value).
c.
Continue the procedure for volumes of 7.5, 10.0, 12.5, 15.0,17.5, and 20.0
mL.
d.
Click Stop when you have finished collecting data.
5. In your data table,
record the pressure and volume data pairs displayed in the Table window (or,
if directed by your instructor, print a copy of the Table window).
6.
Examine the graph of pressure vs. volume. Based on this graph, decide
what kind of mathematical relationship you think exists between these two
variables, direct or inverse. To see if you made the right choice:
a. Click the Curve Fit button.
b.
Choose Variable Power (y = Ax/\n) from
the list at the lower left. Enter the value of n in the
Degree/Exponent edit box that represents the relationship shown in
the graph (e.g., type "1" if direct, "-1" if inverse). Click Try Fit .
c.
A best-fit curve will be displayed on the graph. If you made the correct
choice, the curve should match up well with the points. If the curve does
not match up well, try a different exponent and click Try Fit again. When
the curve has a good fit with the data points, then click
OK
7. Once you have confirmed that the graph represents either a direct or
inverse relationship, print a copy of the -Graph window, with the graph of
pressure vs. volume and its best-fit curve displayed. Enter your
name(s) and the number of copies you want to print.
DATA AND CALCULATIONS
|
Volume (mL) |
Pressure
(kPa) |
Constant,
k (P/V or PV) |
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PROCESSING THE DATA
1. If the volume is doubled from 5.0 mL to 10.0 mL,
what does your data show happens to the pressure? Show the pressure values in
your answer.
2. If the volume is halved from 20.0 mL to
10.0 mL, what does your data show happens to the pressure? Show the pressure
values in your answer.
3. If the volume is tripled from 5.0 mL to 15.0 mL,
what does your data show happened to the pressure? Show the pressure values in
your answer.
4. From your answers to the
first three questions and the shape of the curve in the plot of pressure
versus volume, do you think the relationship between the pressure and volume of
a confined gas is direct or inverse? Explain your answer.
5. Based on your data, what would you expect the pressure
to be if the volume of the syringe was increased to 40.0 mL? Explain or show
work to support your answer.
6. Based on your data, what
would you expect the pressure to be if the volume of the syringe was decreased
to 2.5 mL? Explain or show work to support your answer.
7. What experimental factors
are assumed to be constant in this experiment?
8. One way to determine if a
relationship is inverse or direct is to find a proportionality constant, k, from
the data. If this relationship is direct, k = P/V. If it is inverse, k =
PV. Based on your answer to Question 4, choose one of these formulas and
calculate k for the seven ordered pairs in your data table (divide or multiply
the P and V values). Show the answers in the third column of the Data and
Calculations table.
9. How constant were the values for k you obtained
in Question 8? Good data may show some minor variation, but the values for k
should be relatively constant.
10. Using P, V, and k, write an
equation representing Boyle's law. Write a verbal statement that correctly
expresses Boyle's law.
Chemistry with Computers
6-3