Difference between revisions of "Sonoluminescence"

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The next part of the amp circuit is the push pull pair which increases the current. A TIP 31C NPN and a TIP 32C PNP were used. To test that the amp circuit, you need to place a load resistor ( a 10 ohm will do), in series with a meter for impedance.  
 
The next part of the amp circuit is the push pull pair which increases the current. A TIP 31C NPN and a TIP 32C PNP were used. To test that the amp circuit, you need to place a load resistor ( a 10 ohm will do), in series with a meter for impedance.  
  
[[File:New_amp_circuit.jpg]]
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[[File:New amp circuit.png]]
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Connect the inductor to the PZT's on the flask. In our lab, we used a 100 ml quartz spherical flask. To test the voltage across the PZT's, find a voltage probe and connect it to the oscilloscope. With the function generator outputting a frequency of 20-25 kHz (may vary depending on the size and shape of the flask being used), tune the inductor until maximum amplitude. The voltage across the PZT's should be around several hundred Vpp.
 
Connect the inductor to the PZT's on the flask. In our lab, we used a 100 ml quartz spherical flask. To test the voltage across the PZT's, find a voltage probe and connect it to the oscilloscope. With the function generator outputting a frequency of 20-25 kHz (may vary depending on the size and shape of the flask being used), tune the inductor until maximum amplitude. The voltage across the PZT's should be around several hundred Vpp.
  
[[File:Sono_inductor]]
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[[File:Sono inductor.jpg]]
  
[[Filee:Sono_flask]]
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[[Filee:Sono flask.jpg]]
  
  

Revision as of 13:57, 10 December 2013

What we are trying to accomplish in the Sonoluminescence Project is to create a Single-Bubble Sonoluminescence (SBSL). The mechanisms of sonoluminescence are still unclear so our goal here is to collect as much light possible from the bubble for analysis. In order to do this, the bubble needs to be stable enough to emit a sufficient amount of light.

Our first step is to create a bubble. The basic set-up of our project is: Function Generator -> Amp Circuit -> Tunable Inductor -> Flask -> Oscilloscope.

We used a Rigol DG 1022 function generator and a Rigol DS 1102 oscilloscope throughout the project. It is best to take some time to get familiar with this equipment. Knowing how to scan, zoom and trigger a signal properly is important when analyzing the signal from the flask.

The amp circuit consists of an operational amplifier and a push pull transistor pair (commonly known as a Class B push pull output). The op amp is needed to increase the voltage because the maximum voltage from the function generator is 20 Vpp. In the beginning we used a CA 314 with an inverted 1.5 gain using a 150k ohm (R2) and a 100k ohm resistors (R1), but later increased the gain to about 8 using the adjustable resistor on the protoboard. The gain can be calculated using the ratio of the two resistors R2/R1. It is important to check that the op amp is working properly, so test each prong and make sure you get the expected voltages.

The next part of the amp circuit is the push pull pair which increases the current. A TIP 31C NPN and a TIP 32C PNP were used. To test that the amp circuit, you need to place a load resistor ( a 10 ohm will do), in series with a meter for impedance.

New amp circuit.png


When everything in the amp circuit is in place, the load resistor can be taken out and the tunable inductor can be connected to the output.

Connect the inductor to the PZT's on the flask. In our lab, we used a 100 ml quartz spherical flask. To test the voltage across the PZT's, find a voltage probe and connect it to the oscilloscope. With the function generator outputting a frequency of 20-25 kHz (may vary depending on the size and shape of the flask being used), tune the inductor until maximum amplitude. The voltage across the PZT's should be around several hundred Vpp.

File:Sono inductor.jpg

Filee:Sono flask.jpg


Now with everything in place, connect the microphone at the bottom of the flask to the oscilloscope. Water is degassed by boiling distilled water for 15 minutes and then poured into the flask. We first located the resonant frequency and then adjusted the driving voltage to maximum amplitude. To create an bubble, an eye dropper was used. If a bubble was successfully trapped, distortions of the acoustic signal can be seen at the peaks.


The next step for this project would be to set up a vacuum pump to speed up water preparation and to construct a resonating feedback circuit that will able to track the resonating frequency of the flask to increase the stability of the bubble.

Presentation:

Fall_2013