Physics307L F09:People/Archer

Notebook
Lab Notebook

Report
none yet

Oscilloscope Lab
The raw data from the lab is here.

In summary, I measured the peak-to-peak voltage and period of multiple sine waves of three different amplitudes the peak-to-peak voltage and period of a sine wave with a large DC offset, as well as the fall time of a DC Voltage read through AC coupling, measured by placing cursors at the peak of the function and at the 90% decay point of the function, as well as automatic calculation in the oscilloscope. I measured everything else by visual inspection, cursor inspection, and automatic calculation in the oscilloscope.

I am satisfied with this result, since nothing seems to be too unexpected. I would attribute the fluctuations to random error. If I had more time, I might examine Fourier transform phenomena in the wave functions.

I am still confused by the nature of capacitive coupling.

I did not explore anything outside of the lab parameters. I have no suggestions for this lab. 

Planck's Constant Lab
The raw data for the lab can be found on the following pages:9/15/08 and 9/29/08.

In summary, I measured the stopping potentials (taken to be the maximum potentials measured) in a photodiode of multiple wavelengths of light diffracted from a mercury lamp at multiple levels of intensity, as well as the time taken to achieve this stopping potential for some of these wavelengths.

For Photon Theory Part A,

For Photon Theory Part B,



Passing different intensities of same-colored light has very little effect on stopping potential and thus very little effect on photon energy; the charging time therefore should not be affected.

Longer wavelengths of light have lower stopping potentials, while higher shorter wavelengths have higher potentials, by extension, shorter wavelengths have higher energies.

This lab supports a photon-based model of light, since the wavelength (rather than the intensity) has the greatest effect on stopping potential by far.

The slight drop in stopping potential is possibly due to the physical limitations of the photodiode used to capture wavelengths, which may not function properly for low intensities of light.

For Determination of Planck's Constant,



The slope of this linear fit is h/e (Planck's constant over elementary charge) and the y-intercept is W0/e (Work function over elementary charge).

From these 6 data sets of V vs. ν, we obtain these values:

Compared with the accepted value of 6.626e-34 J*s for h, this value obtained in the experiment is quite close, and is on exactly the right order of magnitude.

These results seem good, aside from the low-intensity anomalies in the first part of the experiment, through which error crept in. If I had more time, I might examine the intensity relationship for other wavelengths. I did take extra measurements in addition to what the experiment demanded, to get more accurate results.

Poisson Distribution Lab
The relevant pages of the lab notebook are 10/1/08, 10/3/08, and 10/6/08.

In this lab, I measured counts of background radiation with a photomultiplier tube. I took multiple readings with multiple dwell times.


 * The revised data have all anomalous readings removed. I have included analysis for original data for comparison.

The standard deviation is very close to the mean for small dwell times, but the quantities diverge for very large dwell times.

I am not entirely satisfied with these results: the standard deviations seem inaccurate for large dwell times.

If I had more time, I would compare these results with real Poisson distributions to check for consistency, and perform X2-analysis to find the probability distribution of the background radiation. I took far more sets of data than the original experiment required (12 as opposed to 3).



Charge to Mass Lab
The relevant pages of the lab notebook are 10/13/08 and 10/20/08.

In this lab, we activated a Helmholtz coil apparatus in order to measure the charge-to-mass ratio of an electron based on the deflection of an electron beam by the magnetic field generated from the Helmholtz coils, as well as the voltage used to accelerate the electron beam and the current used to generate that magnetic field.

We applied various combinations of voltages and currents until paths of electrons could be observed (left). Some of these paths glowed in the UV spectrum (center). Then the current and voltage were adjusted upward to obtain large circular paths (right), which were suitable to measure.

Using the formula (e/m) = 2*V/(B*r)^2 where we can calculate the following out of 12 sets of data:
 * V = accelerating voltage
 * B = magnetic field strength = 7.8 * 10^4 Wb/(A m^2) * I
 * I = current
 * r = deflection radius,

Therefore, we can say with 68% confidence that (e/m) = 3.829 ± 0.335 * 10^11. We also qualitatively measured the effects of activating deflection plates in the Helmholtz coil. Applying a current to the deflection plates in the indicated direction, the electron beam is deflected upward; applying current in the opposite direction, the beam is deflected downward.

Lab Questions:

1. We see the electron beam due to the bremsstrahlung effect, which exists due to the helium in the glass tube.

2. According to the NGDC, there is an effect of roughly 23 μT. Given the magnitude of our experimental field, we can ignore this.

3. If protons were emitted, the beam would always be deflected in the opposite direction.

4. According to Wikipedia frequency f = 1/t = B * (e/m), therefore t = 1/(B * (e/m)). For constant B, time t has no dependence on V.

5. According to the equation v = rB(e/m), velocity v = 0.05021±0.00190 *c. (Mean ± Standard Error of the Mean) For such speeds v << c, relativistic corrections would not matter much.

I acknowledge this website from which I got some equations.

I am not satisfied with the results. Although they are on the right order of magnitude (~10^11), they are roughly twice the accepted value of 1.76e11. Perhaps I made a calculation error, or perhaps there is a systemic error I did not identify.

If I had more time I would attempt to find the source of this error. I would also attempt to physically rotate the tube to determine the effects of deflecting the electron beam, and to further explore the effects of the Earth's magnetic field. I would also try to check my data against data taken against constant current, as well as data taken against constant voltage. 

Further Analysis and Notes
The mean and standard error of the mean (SEM) values for voltage, current, magnetic field strength, and beam radius are included not for any intrinsic value, but because we originally believed they might have aided in the calculation of the SEM value for the charge-to-mass ratio through the principle of propagated error.

They were useful for computing the mean of the ratio. However, they were useless for the SEM since the values of voltage, current, and beam radius are not independent. As such, traditional formulas for error propagation for independent variables do not apply, and since we have all values in the computer, we can compute the SEM directly (which we ultimately did).

The mean of e/m ratios was calculated from inputting the means of the variables into the equation for e/m. The SEM of e/m was calculated from the (automatic) standard deviation function applied over each individual e/m ratio as calculated from corresponding sets of voltage, current, and beam radius, divided by the square root of the number of ratios. (All other SEM values were calculated in a similar way; the standard deviation of the set of all values, divided by the square root of the size of the data set).

The MATLAB M-file used to compute all quantities is here: function RatioLab format long;clc V = [268.4 244.7 290.4 264.2 289.4 283.6 231.7 292.2 255.1 281.2]; Vmean = mean(V) I = [1.283 1.208 1.180 1.409 2.099 1.330 1.002 1.418 1.380 1.265]; Imean = mean(I) r = [4.0 3.5 3.8 4.2 4.0 3.6 3.9 4.1 4.6 3.6 4.5 4.7 3.7 3.5 3.0 3.3 2.0 1.7 1.8 2.0 4.1 3.5 3.9 4.1 3.9 3.6 4.1 4.4 3.6 3.4 3.3 3.5 2.7 2.5 2.6 2.9 4.3 3.8 4.0 4.2]; Bmean = 7.8e-4 * Imean rmean = mean(r)/100 ratiomean = 2 * Vmean/((Bmean * rmean)^2) % mean VSEM = std(V)/sqrt(length(V)) ISEM = std(I)/sqrt(length(I)) rSEM = std(r)/sqrt(length(r)) BSEM = 7.8e-4 * std(I)/sqrt(length(I)) r = [4.0 3.5 3.8 4.2;4.0 3.6 3.9 4.1;4.6 3.6 4.5 4.7 ;3.7 3.5 3.0 3.3 ;2.0 1.7 1.8 2.0 ;4.1 3.5 3.9 4.1; 3.9 3.6 4.1 4.4; 3.6 3.4 3.3 3.5 ;2.7 2.5 2.6 2.9; 4.3 3.8 4.0 4.2]; ratio = 2 .* V./(((7.8e-4 .* I) .* mean(r'/100)).^2) ratioSEM = std(ratio)/sqrt(length(ratio)) % standard error of the mean vel = mean(r'/100) .* (7.8e-4 .* I) .* ratio velmean = mean(vel) velC = velmean/3.0e8 velSEM = std(vel)/sqrt(length(vel)) velCSEM = velSEM/3.0e8

Balmer Series Lab
The raw data from the lab is on the notebook pages from 10/27/2008, 11/3/2008, and 11/16/2008.

In this lab, we observed the wavelengths of light emitted from various elemental lamps in order to determine the Rydberg constant.

First, we had to calibrate the spectrometer by shining a mercury lamp at it, and comparing the measured wavelengths with accepted values. Then we measured the visible second-order emmission spectra from regular hydrogen and deuterium lamps (also known as the "Balmer series") with the spectrometer in order to determine the Rydberg constant, as well as a krypton lamp to determine how well our equipment could resolve.

Our spectrometer seemed to be able to visibly resolve wavelengths within ~1 nm of each other and no closer. We determined this by observing the violet end of the krypton spectrum.

The value for the Rydberg constant for hydrogen was measured as 10964446.07 ± 7548.89 1/m (mean ± SEM). Compared with the official value of 10967758 1/m, we find an astonishingly low 0.0302% error (thus we note that the mean value is within one standard deviation the accepted value).

The value for the Rydberg constant for deuterium was calculated as 11055173 1/m, which has a 0.7970% difference from the Rydberg constant for hydrogen. Qualitatively, however, there is no clear difference between the spectra for regular hydrogen and deuterium.

I am satisfied with the results; I obtained a value very close to the canonical value for the Rydberg constant with multiple measurements, with small error that appears random.

Although I did not have time to calculate the precise canonical differences in second-order wavelengths from hydrogen to deuterium, I was able to take 3 sets of measurements each.

Astonishingly, all sets of measurements were extremely consistent; I obtained the same values for wavelengths on each of 3 measurements of both the hydrogen and deuterium spectra. I do not know why that is the case.

Other
User Page