Wednesday, November 28, 2012

Experiment: Planck’s constant form an LED




The purpose of this experiment is to experimentally determine Plack’s constant by an LED.
The equation used was qV=hc/λ. Solving for Planck’s constant, we get:  h = qVλ/c

Procedure:
We built the setup above to measure the voltage of the LED of various colors when it is dimmest.  In order to make the LED dim, we used varying amount of resistances.  To determine wavelength used a previous method in the color and spectra experiment.




Data:
LED
Voltage(V)
D(cm)
L(cm)
λ(nm)
h (Js)
% error
Red
1.43
28.5±1
86±1
629
4.80±0.20x10^ -34
27.6
Yellow
1.59
26.5±1
86±1
589
4.99±0.23x10^ -34
24.7
Green
1.92
23.5±1
86±1
527
5.40±0.27x10^ -34
18.6
Blue
2.00
22±1
86±1
496
5.27±0.31x10^ -34
20.3

Analysis:
The closest to the actual value of Planck’s constant of 6.62x10^-34 was the green LED with 5.40±0.27x10^ -34.  This large error was due to the low voltage read on the meter because of our set up.

ActivPhysics: 18.3



ActivPhysics: 18.3
The Laser

Q1:  Yes, N­­in­ = Nout+Ncavity­­+nexieted­:  9 = 2+2+5

Q2:  Random
Q3:  Random

Q4:  Emission is in the Same direction and doubled.

Q5:  Population inversion in pumping level of 80.
Q6: Spontaneous

Experiment: Color and Spectra



The purpose of this experiment was to experimentally measure the wavelength of the colors of light, hydrogen, and an unknown gas.

Procedure:
We used the setup below to find the distance of specific color bands through a diffraction gradient.


The equation used to find the wavelength was:

L is the length, which is 1.90m. D is the distance of the color band.  d is the slit spacing of the diffraction gradient, which is 1/500mm.


Data:
Light


D(cm)
λ(nm)
Shortest
40
412
Longest
77
751
Blue
49
499
Green
54
547
Yellow
58
584
Red
68
674
Using the shortest and longest wavelength, and the fact that average humans can see between 390nm to 750nm, we found an equation to help reduce the systematic error.
We plug in the calculated values of λ, and get a new wavelength that is more accurate. I will call this λ’.  


Hydrogen


The actual value for hydrogen was calculated by:




D(cm)
λ(nm)
λ'(nm)
actual values of λ(nm)
% error
End of violet
42
432
411
410
0.002
Middle of cyan
48
490
473
434
0.09
Red
67
665
658
656
0.003

Unknown Gas



D(cm)
λ(nm)
λ'(nm)
1st violet
43
441
421
Last red
74
726
723
Cyan
47
480
462
Green
53
537
523
1st yellow
59
593
582
Orange
61
611
602
Brightest red
65
647
640

Analysis:
The unknown gas was determined to be Neon because of its very distinctive pattern with many color bands.

ActivPhysics: 17.1 and 17.2



Q1:  The distance of the moving light clock is longer. If we assume the angle is 45­­0­­ then
distance is 1.414 times longer
Q2:  The time of the stationary light clock is 6.67s and the moving lock is 9.40s
Q3:  No, in your frame of reference the light clock does not travel a longer distance when
moving
Q4:  When velocity of the light clock decreases the time difference decreases.
Q5:  8.004s
Q6: Lorenz Factor = 1.1169~1.12

Relativity of Length
Q1:  The time measurement of the round trip does not matter.
Q2:  If measure form earth, it will be longer.
Q3:  As time decreases, the length needs to be smaller.
Q4:  L = 769.12

Experiment 12: CD Diffraction



The purpose of this lab was to calculate the grove spacing on a CD and DVD.

Procedure:
We shine a laser through a hole in a piece of cardboard to a CD or DVD.  We then measure the reflected interference maxima at a certain distance.

Data:
The equation used was sinθ = mλ/a. Then sine is replaced for values of length and slit distance, and solve the equation for a, the grove spacing.  We get:


λ is the lasers wavelength, and m is the order.

λ(nm)
m
y(cm)
L(cm)
a(nm)
CD
632
1
4±0.1
10
1702±51
DVD
632
1
15.1±0.1
10
752±61

Analysis:
The manufacturer’s standard value is 1600 nm for a CD.  We got 1702±51nm which does not exactly fall into our error range, but it is close.  The DVD has a much smaller slit spacing, which we calculated it to be 752±61nm.



Experiment 11: Measuring a human hair



The purpose of this lab was to accurately measure a human hair using the concepts of the interference of light though a slit.  To compare, we also used a micrometer to measure thickness as well.

Procedure: we taped a hair though a hole in an index card.  Then we passed a laser though it and measured the distance between the maxima and minima of the pattern produced.


Micrometer

The equation:
λ = dy/Lm
Solving for the diameter of hair d, we get d = λLm/y. 
The wavelength is given at 632nm. L is the distance to the projection, which was 1m.  Y is the distance between the maxima and minima.

Data

λ(nm)
m
y(cm)
L(m)
d(mm)
micrometer(mm)
Tim
632
5.5
0.58±0.5
1
0.60±0.057
0.05±0.005
Erwin
632
3
2.44±0.5
1
0.078±.002
0.06±0.005

Analysis
When we did Tim’s hair we used the small slit spacing to calculate m.  This gave us an order of magnitude of error.  We calculated 0.60±0.057mm, when the micrometer measured 0.05±0.005mm.  When we used my hair we used the large spacing.  The hair had a calculated diameter of 0.078±.002mm.  The micrometer measured 0.06±0.005mm.  My hair had a much closer value, even though it does not fall within our margin of error. For comparison, the average diameter for black hair the professor provided was 0.05mm.   

The large slit spacing was the actual interference pattern that needed to be used.  The small slits were probably some internal interference.

Monday, November 12, 2012

Final Project Proposal



Cloud Chamber

members
Erwin Peralta
Tim Elsen

We will make a cloud chamber with 99% isopropanol and felt a light source and sheet of metal and plastic container.  We intend to show cosmic radiation interaction with isopropanol to create visible trails.  The cosmic radiation will ionize the alcohol and condense them.  We study elements of magnetic deflections in a magnetic filed by introducing a magnet.  Americium from a smoke detector will be used to show particles as well.  


Criteria for success
  • Visibly see ionization trails cosmic or from Americium.
  • See the influence by adding a magnetic field 
Initial Design

Gantt Chart


Monday, November 5, 2012

Project Proposal

Me and Tim Elsen are planning to do a cloud chamber.

we will make a cloud chamber with 99% iso propanol and felt a light source and sheet of metal and plastic container.  We intend to show cosmic radiation interaction with  isopropanol to create visible trails.  The cosmic radiation will ionize the alcohol and condense them.  We want to make fairly visible trails.  study elements of magnetic difflection in a magnetic filed by introducing a magnet.