Growing a Pattern in the Laboratory

HandsOn 13 - Growing a Pattern in the Laboratory

III. Doing the Experiment

Doing the Experiment

Divide the tasks among your partner(s). You will need to measure and record the following during the experiment on a copy of Table :

Figure 4.3: Filling the electrodeposition cell with electrolytic solution (as described in the section "Doing the Experiment.''

1. The time at intervals of 20 seconds (longer or shorter depending on the way you assemble the cell; start with 20 seconds and after you have run the experiment once, reason whether you should use longer or shorter intervals).

2. The radius of the pattern at each recorded time.

3. The current at each recorded time.

Table 4.1: Data Table for Electrodeposition experiment. Units are as follows: $\Delta$ t and t in seconds; I in Amperes; $\Delta$ N and N_t in atoms. To calculate $\Delta$ N, use this algorithm: $\Delta$ N = I $\Delta$ t/q. For Cu^{2 +} and ZN^{2 +} ions, q = 3.2 ^.10^-19 Coulombs/ion.

$\Delta$ t t I r $\Delta$ N N_t

20 20

20 40

20 60

20 80

20 100

20 120

20 140

20 160

20 180

20 200

20 220

20 240

20 260

20 280

20 300

With respect to the radius, the growth may not be symmetric, and some branches may stop growing during the experiment. The investigator recording the "radius'' may choose to measure the overall radius of the entire pattern or the length of an "average'' branch.

A typical procedure might be that the timekeeper watches the clock and announces the time every 20 seconds. The second person reads the current on the ammeter, and the third measures the radius of the deposit. The timekeeper records these two numbers.

Hook up the circuit shown in Figure 4.2. Depending on the time available, you may want to try several experiments using different voltages. As a guide, 1 and 20 volts are probably the low and high values. Try a value between 10 and 15 volts to begin with.

Now it is time to grow your aggregate. The current will start at a low value, 10 milliamps or so, and rise to between 100 and 250 milliamps as the aggregate grows outward. Take care not to let the aggregate grow so large that it reaches the positive terminal. What might happen if it does?

Q4.8: Can you explain: asymmetries? branches, if your aggregate has them? size of the branches? color?

Digitize your electrodeposition aggregates by using a digital camera or a scanner. Since your aggregate is fragile, make sure you digitize the experiment immediately after you finish the experiment. You will need this digitized image for the section on measuring the fractal dimension.

Figure 4.4: Sample copper electrodeposition aggregate in the early stages of growth.

Figure 4.5: Zoom of the copper electrodeposition aggregate. Notice that the rough branches appear at both scales (e.g., at full scale and at the zoomed in scale).

Figure 4.6: Sample zinc electrodeposition aggregate. Notice the differences in structure from the Copper experiment.

Figure 4.7: Zoom of the zinc electrodeposition aggregate. Do you notice any differences between the copper and zinc experiments? Previous: II. Setting Up the Experiment

Next: IV. Data Analysis

$\Delta$ t	t	I	r	$\Delta$ N	N_t
20	20
20	40
20	60
20	80
20	100
20	120
20	140
20	160
20	180
20	200
20	220
20	240
20	260
20	280
20	300