Physics307L:People/Knockel/Notebook/070912: Difference between revisions

Millikan's oil drop experiment (charge of the electron)

Experimenters: Nikolai Joseph and Bradley Knockel

Goal

I want to measure the charge of an electron by measuring the charge on a bunch of oil droplets and seeing if I can find that my calculated charges are integer multiples of some fundamental charge. The actual value is [math]\displaystyle{ e=1.60\times10^{-19} C }[/math].

Equipment

• power source (should go up to 500 V direct current)
• atomizer (to spray oil droplets)
• 2 multimeters
• banana cords
• banana plug patch cords
• DC transformer for light
• micrometer
• THE MILLIKAN DEVICE! (scope, viewing chamber, light, level, focusing wire, thermistor, etc.) (Model AP-8210 by PASCO scientific)

Setup

1. plugged in power supply to wall and Millikan device (turned off)
2. hooked up multimeter using banana plug patch cords to check voltage from power supply
3. leveled the Millikan device
4. plugged in the light using DC transformer
5. focused viewing scope with focusing wire
6. aimed the lamp/light/filament
7. turned on power supply and checked it's voltage using first multimeter
8. attached another multimeter to the thermistor

Values (given to as many significant figures as are reasonably certain)

Known:

• [math]\displaystyle{ d=7.59\times 10^{-3} m }[/math] (plastic spacer width using micrometer)
• [math]\displaystyle{ \rho=8.86\times 10^2 \frac{kg}{m^3} }[/math] (density of oil given on bottle)
• [math]\displaystyle{ g=9.8 \frac{m}{s^2} }[/math] (gravitational acceleration)
• [math]\displaystyle{ p=8.5\times10^4 Pa }[/math] (air pressure in Albuquerque)
• [math]\displaystyle{ b=8.20\times10^{-3} Pa\cdot m }[/math] (some stupid constant)

To be found when taking data:

• [math]\displaystyle{ T }[/math] (temperature from thermistor)
• [math]\displaystyle{ V }[/math] (Voltage between plates in viewing chamber)
• [math]\displaystyle{ v_f=\frac{distance}{time} }[/math] (velocity of oil droplet falling in no field)
• [math]\displaystyle{ v_r=\frac{distance}{time} }[/math] (velocity of oil droplet rising in a field)

To be calculated later using averages of the above values:

• [math]\displaystyle{ \eta }[/math] (viscosity of air as a function of T found in a table)
• [math]\displaystyle{ a=\sqrt{\left(\frac{b}{2p}\right)^2+\frac{9\eta v_f}{2g\rho}}-\frac{b}{2p} }[/math] (radius of droplet)
• [math]\displaystyle{ q=\frac{4}{3}\pi\rho g d\frac{a^3}{V}\frac{\left(v_r+v_f\right)}{v_f} }[/math] (charge of oil droplet)

Procedure

We will spray oil droplets into the viewing chamber using the atomizer by pumping droplet rich air into it. We then select a drop that is barely falling through the viewing chamber in no electric field (we want drops that have little mass). We measure the speed at which it falls, [math]\displaystyle{ v_f }[/math]. We then create an electric field that causes the droplet to rise and measure the speed, [math]\displaystyle{ v_r }[/math]. We take many measurements of both of these speeds over and over on the same droplet. We will periodically introduce alpha particles which will change the charge of the oil droplet to be either more positive or negative depending on how the collision between the oil and alpha particles occur. We will record the new velocities.

This process takes practice, and one must be sure that the oil droplet being observed does not gain or lose charge unexpectedly.

Data

Results

Analysis/Conclusions