the nobel prize in physics 1923 - ustcstaff.ustc.edu.cn/~xjun/transparencies02.pdf · 2013. 3....
TRANSCRIPT
Robert A. Millikan (22 March 1868 –
19 December 1953)
The Nobel Prize in Physics 1923
…I went out to the drug store that
afternoon and bought an atomizer and
some watch oil. Then I came back to
the laboratory and set up the following
apparatus:
… I saw a most beautiful sight. The field
was full of little starlets….
Millikan, The isolation of an Ion, a Precision Measurements of its Charge,
and the Correction of Stokes’s Law, Science, 1910
J. J. Thomson, (18 December 1856 – 30 August 1940)
The Nobel Prize in Physics 1906
plum-pudding model
Ernest Rutherford
30 August 1871 – 19 October 1937
The Nobel Prize in Chemistry 1908
"for his investigations into the disintegration of the elements, and the chemistry of radioactive substances"
Geiger–Marsden experiment
Geiger H. & Marsden E. (1909). "On a Diffuse Reflection of the α-Particles". Proceedings of the Royal Society, Series A 82: 495-500
“It was quite the most incredible event that has ever happened to
me in my life. It was almost as incredible as if you fired a 15-inch
shell at a piece of tissue paper and it came back and hit you. “
—Ernest Rutherford
Fc
rR
Fc
rR
E. Rutherford, The Scattering of α and β Particles by Matter and the Structure of the Atom, Philosophical Magazine. Series 6, vol. 21. May 1911
H. GEIGER and E. MARSDEN, The Laws of Deflexion of a Particles through Large Angles, Philosophical Magazine, Series 6, Volume 25, Number 148, April 1913
(1) Variation with angle. (2) Variation with thickness of scattering material. (3) Variation with velocity of incident a particles. (4) Variation with atomic weight of scattering material.
Angle
f
Scintillations per minute.
1
--------
sin4f
N x (sin4f / 2) Without
foil.
With
foil.
Corrected
for effect
without
foil.
Corrected
for decay,
N.
150 0.2 4.95 4.75 6.95 1.15 6.0
135 2.6 8.3 5.7 8.35 1.38 6.1
120 3.8 10.3 6.5 9.5 1.79 5.3
105 0.6 10.6 10.0 14.6 2.53 5.8
75 0.0 28.6 28.6 41.9 7.25 5.8
60 0.3 69.2 68.9 101 16.0 6.3
(1) Variation with angle
(2) Variation with thickness of scattering material.
I.
Number of
sheets of
mica
II.
Range R of a
particles after
leaving mica
III.
Relative
values of 1/n4
IV.
Number N of
scintillations
per minute.
V.
Nn4
0 5.5 1.0 24.7 25
1 4.76 1.-21 29.0 24
2 4.05 1.50 33.4 22
3 3.32 1.91 44 23
4 2.51 2.84 81 28
5 1.84 4.32 101 23
6 1.04 9.22 255 28
(3) Variation with velocity of incident a particles.
I.
Substance.
II.
Atomic
weight
.
A.
III.
Air
equivalen
t
in cm.
IV.
Number of
scintillations
per minute
corrected
for
decay
V.
Number N
of
scintillations
per cm. air
equivalent.
VI.
A3/2.
VII.
N x A3/2.
Gold....... 197 0.229 133 581 2770 0.21
Tin......... 119 0.441 119 270 1300 0.21
Silver...... 107.9 0.262 51.7 198 1120 0.18
Copper.... 63.6 0.616 71 115 507 0.23
Aluminium. 27.1 2.05 71 34.6 141 0.24
(4) Variation with atomic weight of scattering material.