Intermolecular Forces with Evaporation of Alcohols Using Go Direct™ Temperature

Today we will be investigating evaporation
and intermolecular attractions with two of our Go Direct Temperature Probes. In this
experiment, temperature probes are placed in various liquids. Evaporation occurs
when the probe is removed from the liquids container. This evaporation is an
endothermic process that results in a temperature decrease. The magnitude of the
temperature decrease like viscosity and boiling temperature can be related to the
strength of the intermolecular forces of attraction. In this experiment, you will
study temperature changes caused by the evaporation of several liquids and relate
the temperature changes to the strength of intermolecular forces of attraction.
Here we are going to compare two different types of alcohols, 1-propanol
and ethanol. We will also need filter paper and small rubber bands.
It is recommended that you do this experiment with two Go Direct
Temperature Probes, but it can also be done with one at a time. The Go Direct
Temperature Probes can be connected via USB or via Bluetooth to your platform.
Your platform can be a Chromebook, Mac computer, Windows computer, iOS or
Android device. To get started make sure you have downloaded the free Graphical
Analysis 4 app from our website, or the appropriate App Store. Since I will
be taking data via Bluetooth, I will first turn on my temperature
probes. I’ll then launch my GA4 app and select sensor data collection. I will connect to my two temperature
probes and press done. For this experiment, I want to change the duration
to 300 seconds. To do that I tap on the mode button and change the end
collection time to 300 seconds. Then press done. Now that my software is
set up, I want to prepare my temperature probes. I wrap a small piece of filter
paper around the tip of the temperature probe and tighten it with a rubber band.
My propanol and ethanol samples are ready. To begin the experiment I want a few
data points to get a baseline before evaporation begins. So go ahead and place
the temperature probes in your solutions and let them equilibrate for a few seconds
making sure their temperature readings are stable. Then press the collect button and
collect a few data points for a nice baseline for your initial temperature
reading. Then remove the temperature probes and place them on the edge of
the desk or an elevated surface, make sure that it’s not touching anything.
At the end of 300 seconds the data collection will stop. For each of the liquids, we are interested
in the minimum temperature and the maximum temperature. The difference between these
two values will give us our delta T, the temperature change during evaporation.
To display these values I can tap along the graph or for a more accurate
representation I can look at the data statistics. First, let me close out of the
examine line, and then click on the graph tools icon and select view statistics.
Temperature probe one has a minimum of 10.83 degree Celsius and a maximum
temperature of 21.63 degree Celsius. Temperature probe two has a minimum
temperature of 16.07 degree Celsius and a maximum of 21.65 degree Celsius. The
difference between the minimum and maximum temperatures are my delta T. I can also
directly use this delta Y value. By looking at the delta T values for
ethanol and 1-propanol along with their molecular weights, we should be able to
predict where the trace for 1-butanol would land on this graph. We can even draw
that prediction with the graphical analysis draw prediction tool. First,
let’s close out of the statistics box and then from the graph tools icon select add
prediction. Using your cursor draw where you would expect 1-butanol to land. It is
not important that you predict the exact delta T value, simply estimate a
logical value that is higher, lower or in-between the previous delta T
values. I’m going to predict that 1-butanol would land in between 1-propanol
and ethanol. I can even name my prediction 1-butanol and select save. Now I want to test that prediction along
with other chemicals to further explore intermolecular forces. For more
information about the Vernier Go Direct Temperature Probe and our Go Direct line
of sensors, visit our website or email [email protected]

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