ON THE ROAD AGAIN

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Title: ON THE ROAD AGAIN

1
ON THE ROAD AGAIN

Final Destination Quantum Mechanics

2
Taking the Trip From Classical Physics to Quantum
Mechanics

What is Quantum Mechanics one may ask? Well, in a
nutshell, quantum mechanics is
The FUNdamental branch of physics replacing
classical Newtonian Mechanics and
Electromagnetism at the atomic and subatomic
levels.
Quantum mechanics provides explanations for many
phenomena that are unattainable through classical
mechanics
Namely quantization, wave particle duality,
the uncertainty principle, quantum entanglement

3
Dont be fooled, this will be no short trip

Quantum theory ideas did not originate overnight.
There were numerous experiments and observed
phenomena that eventually led to this modern way
of thought.
The move from General Relativity to Quantum
mechanics is a huge step, since the two theories
seemingly contradict each other. The two
fundamental issues yielding this contradiction
are
Classical is essentially a deterministic approach
while quantum mechanics is essentially
indeterministic
General relativity relies mainly on gravity while
quantum mechanics relies on three fundamental
forces, the strong, weak, and electromagnetic.
(though these forces are imperative in Quantum
Theory, we will leave out a discussion of them
here, for they will be covered in a latter
presentation) For the remainder.. We will look
at the major players on the road to the discovery
and development of this way of thought.)

4
Why are we going here?

Two fundamental discrepancies between
experimental observations and classical physics
were noticed in the late 1800s.
These two discrepancies (namely the ultra
violet catastrophe and the discrete spectral line
phenomena) caused scientist to re-examine several
established ideas and arrive at a new way of
thought.

5
EVERYONE JUMP IN THE VAN! Were hittin the road!

Problem 1 Energy and Blackbody radiation
Intro
A black body is a surface which absorbs all
radiation and at a given temperature T, can also
emit radiation
Thus, using the ?(?,T) energy function, holding T
constant, the individual wavelengths ? of the
radiation can be analyzed
At the turn of the 20th century, this in fact was
done and the observations were first recorded by
Otto Lummer and Ernst Pringsheim and then again
the following year by Heinrich Rubens and
Ferdinand Kurlbaum
The results gathered are shown in the following
figure

6
Results
7
Uh Oh!

According to the Equipartition Theorem (a
non-quantum theorem) every degree of freedom of a
system must share equally in the energy available
to the system,
Take for example, a blackbody radiation of
dimension l , then we know that wavelengths are
given by ? (2l )/ n, where n 1,2,3 .
Each of these represent a degree of freedom, and
therefore, by the equipartition theorem, should
share the energy equally.
Thus, since there are infinitely many waves as
the wavelength gets shorter, it would be assumed
that the majority of the light (ie radiation)
would be at the short wavelength end of the
spectrum, as shown by the dotted line

Notice the dotted line

9
Why is this a problem?Lets do the math

A major problem arises, since we know from
derivations that follow directly from the
equipartition theorem, done by Rayleigh and Sir
James Jeans, that through classical analysis, the
energy density function can be expressed as
where k is
Boltzmanns constant
But it is easily seen that by applying basic
calculus the limit
of as ?
approaches 0, is infinity. Obviously
contradicting the observed results shown in
the figure by the solid line. If this were
indeed the case, the results would be described
by the dotted line in the previous figure.
This discrepancy and blow up at short
wavelengths is often referred to as the
ultra-violet catastrophe and spurred much
thought as to how to remedy it.

10
FLAT TIRE!!Our classic car is getting old, time
to trade it in

The discrepancy between the observational results
and this equation is an intense problem. Since
the energy density equation derived by Jeans in
1905, followed directly from the well established
equipartition theorem, which was a consequence of
general relatively. Thus because these do not
correlate, it implies that the overlying theory
must be inadequate.

11
Problem 1 Flat Tirenow we have Problem 2
running out of gas

The second phenomena leading to quantum theory
stems from the pattern of spectral lines emitted
by an element
When an electric arc passes through a sample of
gas, it is observed that only certain frequencies
of light are present.
When observing the spectral lines by separating
them with a prism, it is observed that the
wavelengths are distinct to the element emitting
the spectrum

12
Whats so bad about that?

This observation directly contradicts the
predictions of classical physics
According to classical physics, accelerated
particles must emit electromagnetic radiation,
and thus if they were moving randomly within the
atom, all the spectra would be emitted, thus
producing a continuous spectrum, however the
results showed a discrete distribution.
Due to this phenomena, scientist began
associating these spectral emission with stable
orbits, and an empirical formula was even
discovered through trial and error efforts, to
fit the observed reality.
This equation is
v R(1/m2 1/n2) known as Balmers Eq.
where v is the velocity of frequencies of
the lines, R is a universal constant, m is a
constant representing a particular series, and n
is an integer representing a particular line

13
What are we going to do?

Many models of the atom where constructed to try
to describe this phenomena. However, they nearly
all assumed a uniform distribution of the
positive charge.
However, in 1909, Hans Greiger and Ernst Marsden
disproved this theory through careful examination
of the scattering of a beam of charged particles.
What would be expected if the previous models
were in fact reality, would have been a uniform
scattering of the particles. However this was
not the case

14
What happened?

Grieger and Marsden used an experiment suggested
by Ernst Rutherford, a premier physicist and
often considered the Faraday of nuclear physics.
The experiment consisted of using gold tin foil
about 400 atoms thick with He particles as
their bombarding projectiles.
Most of the particles went straight through with
no deflection, which seemed to support classical
theory, since it is known that electrons are much
smaller and thus when all charge is equally
distributed, there would be little deflection
HOWEVER, this was not the case for all particle,
there were a given number that were scattered
back at angles larger than 90 degrees, implying
something else is going on.
Rutherford, examined the results and concluded
that the bulk of the atom and the majority of
positive charge, HAD to be concentrated at a
single point in the atom.

Thus, the concept of a nuclear atom model was
presented. However, this causes more problems.
With this model, under classical theory, it would
necessarily yield a continuous spectrum, since
there is no partitioning of the energy, thus no
constraints on either the frequency or
wavelength.
With classical theory again failing to explain
the observed phenomena, physicist began searching
for an explanation and theory that accurately
describes reality.

16
Now that we know the problems let fix them!
Lets meet the mechanics

The Big Wigs
-Max Plank
-Niels Bohr
-Albert Einstein
-de Broglie
Other notable participants (Max Born, John von
Neumann, Paul Dirac)

17
Who is Max Plank??

Brief Background
Planck came from traditionally intellectual
background, his great grandfather and grandfather
were both theology professors, while his father
was a law professor and uncle was a judge
He studied under Hermann Muller at Munichs
Königliches Maximiliangymnasium, where he was
taught mechanics, astronomy, and mathematics
An incredibly gifted child, he graduated at the
age of 16 and in 1874 began studying at
university of Munich

18
Background Continued

While at university, he was advised by his
professors not to study physics, because they
believed that nearly everything had already been
discovered and all that was left to do was fill
in a few holes
However, this did not discourage Planck, rather
he claimed that he was not in the field to make
revolutionary discoveries, but rather to gain a
fuller understanding of those theories already
established
This desire for complete understanding,
consequently led him to arguably, one of the
greatest discoveries in modern physics, since he
refused to accept that classical theory just
didnt explain reality.

19
Career background

Planck did very few experiments before entering
into the realm of theoretical physics. He was
more concerned with why things were happening,
than searching for new observational realities
He went to Berlin to study with two of the
premiere physicists of the time, Hermann von
Helmholtz and Kirchhoff
Studying entropy and thermodynamics, he was
eventually appointed to the position of
Kirchhoffs successor
These events gave him the background needed to
make his revolutionary discoveries

20
What exactly were Plancks findings??

Planck worked on the Blackbody radiation problem
Plank was hired by electrical companies to find a
way to produce the most light (radiation) using
the least amount of energy possible.
Since he had worked under Kirchhoff, Planck new
that Kirchhoff had already contemplated the
question of how the intensity of the radiation
emitted by a blackbody depends on the frequency
of the radiation
Thus, Planck decided to utilize a collection of
radiating harmonic oscillators in thermal
equilibrium to describe black body radiation

21
Quick Review

We know that classical methods had failed to
describe the observational reality as seen
through its discrepancy with the Ryleigh Jean
equation, since it failed to work for short
wavelengths.
There was also conjecture presented by Willheim
Weil that described the phenomena for short
wavelengths, but failed for long wavelengths.
Thus Planck decided to utilize both ideas and
interpolate between the two.

To do this, Planck used a thermo dynamical
argument to produce a two parameter ad hoc
expression which we will see later.
He did this through modification of classical
relations involving entropy of radiation
His argument was incredibly complex, and too
intense to derive currently, however, it is
imperative to note that it was incredibly based
on phenomological curve fitting
Basically, he was left with a curve that fit the
observed data perfectly, but had no solid
theoretical justification for his results.

23
Why Why Why

Thus, he returned to his studies in order to try
to derive a theoretical justification
To do this, he found that he was required to
utilize statistical mechanical techniques
(which allows for distributions to be describe on
its micro state) which had been introduced by
Boltzmann.
This was a big step, because he had been
extremely reluctant to accept these new
techniques, because he felt they were merely
axiomatic by nature
However, he claimed it was an act of despair I
was ready to sacrifice any of my previous
convictions about physics.

Though he was originally reluctant, he allowed
himself to accept these new techniques, which
allowed him to partition the total energy of the
system into discrete amounts
Therefore, his oscillators could only absorb and
emit discrete amounts of radiation which
consequently yielded the proper distribution.
Through these methods, he arrived at the notion
that the energy absorption and emission must be
quantized into discrete amounts e (modernly
referred to as quanta)

25
Final result!! ?

Thus, Planck had a theoretical basis and
therefore showed that the energy e , is related
to the frequency v by
e hv. where h is Plancks constant

26
Still Hesitant

Though he was certain that energy absorption and
emission had to be quantized, and was described
by the formula, he was still hesitant to accept
energy quantization in electromagnetic radiation.
He felt that Maxwells electrodynamics, which
claimed that an electromagnetic field could carry
continuously varying amounts of energy, had been
too successful to just disregard them
He spent much time trying to fit his prior
finding of e hv. into classical
electrodynamics, however, after many failed
attempts, he came to a final conclusion accepting
the reality of quanta, which has since been
accepted by nearly all physicists.
This is evident today, as we readily use the
notion of a photon, which is merely the name for
a quantized electromagnetic field.

27
So What?

How does this solve the problem which arises from
classical mechanics??
Look at the equation for wavelength
v c / ?
we see that Plancks equation e hv hc / ?
Thus, if energy is finite, there must exist a
shortest and a longest wavelength, and thus, if
very few quanta are released when ? is either
large or small.
Further, it is obvious from the equation that the
peak will occur at the most probable frequency.

28
Mile Marker 1

With Plancks recognition that energy could in
fact be discretely quantized, an entire new wave
of physical thought arose
Plancks findings are often considered the birth
of quantum mechanics.
However, this is merely the first step lets now
look to the problem of discrete emission of
spectral lines.

29
AN ATOMIC TRANSMISSION (uh transition)!Niels Bohr

Who is Niels Bohr?
Bohr made many notable contributions to physics,
namely
A model of the atomic structure
Electron orbital momentum is quantized by Lnh
Notion that electrons travel in discrete orbitals
Notion that when electrons drop from higher to
lower energy, it emits a photon
The principle of complementarity

30
Why we need him

Though he made notable contributions, we will
focus on his theory of atomic transitions
Bohr attended the University of Copenhagen and
then went to Manchester to work under Rutherford,
who (as we saw previously) was actively working
on developing an atomic model
This influenced Bohr greatly, and within four
months of working with Rutherford, he formulated
his theory.

31
Lets Derive the Theory

Bohr began by assuming Rutherfords model, ie an
electron of charge e and mass m in circular
orbit of radius r about the nucleus (charge e)
Thus, if a stable nuclear orbit is to be
attained, the electrostatic force of attraction
must yield the imperative centripetal force.

32
Where is this going?

Knowing this, and applying the law of
conservation of energy, Bohr derived the
following expression
which represents the frequency in relation to its
energy.
However, if we were to apply classical theory
(which implies that an accelerated particle emits
radiation wit frequency equal to that as seen
above) problems obviously arise.

33
Whats Wrong?

According to classical theory, the energy E could
be of any value and thus the atom should radiate
all frequencies, yielding a continuous spectrum.
However, we know this is not the case as seen
prior
Therefore, Bohr began working to attain a set of
discrete orbits such that it is stable only when
the electron is within one the these distinct
orbitals, and thus only emits radiation when
transitioning between them.

34
Follow the Leader

Knowing that Planck had quantized energy emitted
and absorbed in oscillators, Bohr decided to
quantize the energy of the photons released when
entering and leaving the stable orbits.
With this concept, he derived the equation
He introduces the factor of ½ because if the the
electron is initially at rest and its final state
is in the stable orbit, then it will have
velocity v, thus the average between the two is
simply v/2.
However, it must be noted that he did not come
up with this justification until he examined
Balmers equation (presented earlier) and found
that it was the ½ factor that allowed for an
accurate fit)

Therefore, he felt that the emitted radiation
would be some multiple of this, which led to the
n/2 factor.
By combining this derivation with the expression
of frequency in terms of energy, Bohr obtained
the expression
Further, when combined with the conservation of
energy law E(final) E(initial) hv, Balmers
equation is obtained, and thus, the spectral
lines emitted by Hydrogen are accurately depicted
by Bohrs expression.

36
Even Better!

Bohr also stated that using the same techniques
and theory, his derived expression, was
equivalent to quantizing angular momentum l
mvr.
This is very efficient, but similar to past
explanations, thus we will not derive here.

37
Does it Work?

Bohrs model works quantitatively for
one-electron atoms such as hydrogen, ionized
helium, and doubly ionized Lithium.
Though his original model only worked for these
few elements, his work made immediate impact and
commanded much attention.
After he presented his work in 1913, many
generalizations were made and a set of rules for
treating atoms was establishes (modernly referred
to as old quantum theory)

38
How we go from one to another

A three step process was employed to move from
classical to quantum theory when describing
atomic structure
Initially, classical theory is used to determine
the possible motions of the system
Secondly, quantum theory is employed to depict
the possible orbits
And finally, the law of energy conservation is
employed to fix the frequencies during an atomic
transition

39
Who Cares?

Does it really matter how Bohr arrived at his
model of the atom, or how Bohr determined that
the frequency of an atom depends on the negative
of its energy raised to the 3/2 power?
Does anyone need to know this besides scientific
historians and PHIL/PHYS 30389 students?
Probably not
However, insight into the process helps make the
discoveries more understandable

40
Brilliance or Backpedaling?

We see Plank makes an ad hoc attempt to make some
argument to justify his curve fitting
Then, against his will, he accepts the hypothesis
of quantization
Energy quantization providing the necessary
limitation on the blackbody radiation curve at
short wavelengths was not a moment of brilliance
but instead a drawn out process Plank himself
wanted to avoid

41
Brilliance or Backpedaling 2?

Bohr in a desperate panic to obtain a fit to the
data (our good friend the Balmer formula)
By 1913 Planks quantization of energy is highly
accepted so Bohr is not as adamant about avoiding
it
Bohr is conservative in his methods, for example
sought to quantize energy and not angular
momentum
His attempts to avoid numerous new principles
leads to the acceptance of his theory
Dont you appreciate their work better now???

42
Fork in the Road

At this point in history the theory of
indeterminism was a serious question for the
enlightened
Poincare, Høffding, and Kierkegaard all
incorporated quantum theory into their work
Høffding claimed that decisive events in life
proceed through discontinuities, or sudden
jerks, which faintly resembles atomic phenomena
These ideas were in the minds of scientists,
which helps explain why some were more inclined
to accept certain models of quantum theory

43
Team New School, turn left

Bohr, Heisenberg, Pauli, Jordon, and Born
All found in Copenhagen
Exclusive group who worked together and rarely
sought help from others
New School were inclined towards a discontinuous
structure in nature at the most fundamental level
and to a doctrine of complementary between
opposites
Discontinuousness was the language used by these
men to describe atomic phenomena
NOTE Causality was not the central question in
the development of the theory

44
New School does Philosophy

Because of the failures of some classical
approaches team New School took up new
philosophical positions on what was possible
Bohr believed the failure of the classical
mechanics explaining the electron theory of
metals was due to an insufficiency in the
classical principles
Pauli was convinced that a Continuum Field
theory, with particles as singularities, was not
possible
Pauli and Heisenberg decided electron orbitals
were meaningless because of the failure to apply
old quantum theory to molecular systems
There existed a clear desire to revolutionize the
concepts of the time

From 1924-1927 Heisenberg worked on his version
of the quantum model
Of note are his operators, which have the
unusual property that the order of multiplication
matters (AB?BA usually)
We now know this is usually the case when A and B
are (n x n) matrices, ngt1, and is standard
matrix multiplication
The new math seemed mysterious yet worked
extremely well, seemed promising.and for real
there were no other alternatives
This new math is discrete (as opposed to
continuous) which appealed to and suited well New
Schools understanding of the nature of the atom

46
Team Old School, turn right

Einstein, Louis de Broglie, and Schrodinger
Not as closed at Team New School
Considered the continuous wave as the basic
physical entity subject to a causal description
Team Old School avoids the notion of
discontinuity and other radical ideasmaking them
team Old School

47
Einsteins influence

Einstein views the foundational questions of
physics (such as relativity, quantum theory,
unified field theory) as the search for a
rational, causal reasoning which can be
comprehended in terms of objective realitywhich
suggests a continuity of basic physical processes
In 1909 Einstein used Blackbody radiation to
show the radiation exhibited wave and particle
behaviors
However after showing that the direction a
molecule has after emitting radiation is left to
chance, Einstein proclaimed it a mistake of the
theory

48
De Broglie

In 1923 he started the theory of wave mechanics
to try to understand the dual nature of a photon
Interested in the dual nature of light, proposed
a model of a particle that followed the
trajectory determined by its associated waves
De Broglie turned mathematical analogy between
waves and particles into theory
Later Schrödinger gave a plausibility argument
for his wave equation

49
Review

New School
From Copenhagen school
Discontinuous school
Saw need to revolutionize current principles
Old School
Not From Copenhagen school
Continuous school
Committed to continuous wave as basic physical
entity subject to causal description

50
Fight!

The 2 quantum theories did not coexist long
Their collision lead to the eventual consistent
interpretation of quantum mechanics
We will now see how the Copenhagen (Old School)
interpretation established dominance over all
other lesser versions of quantum theory

51
Philosophy actual effects something!

Old school is from an older generation which is
less likely to accept philosophical ideas such as
indeterminism and randomness in nature
New School more willing to accept radical
theories, such as indeterminism and unusual
atomic motions

52
Subatomic Kombat

Heisenbergs Matrix mechanics had no physical
interpretation, but worked quitewell.
Heisenberg thought classical mechanics could not
be changed in order to make sense of quantum
phenomena without destroying the theory, hence
the need for a new theory
Heisenberg bothered by Schrödinger unique
formalism concerned with continuous,causal,
visible properties
But it turns out

53
Matrix Mechanics and Wave Mechanics Formalisms
are Mathematically Equivalent!
54
The Race is On

There became a great push to determine the
correct interpretation of Matrix Mechanics
For calculation purposes many scientist were
adopting the Wave-Mechanics model
Heisenberg had personal ambitions and could not
let Old School steal his subatomic thunder
For the love of god the fate of the direction of
theoretical physics was at stake!!!

New School worked together in Copenhagen as a
team to push the matrix mechanics model
Heisenbergs uncertainty principle helped
establish New School as the leading school of
quantum thought
Meanwhile Old School is doing their own thing
working on individual projects
Thus Copenhagen is able to take charge and
influence a centurys worth of thought

At the 1927 Slovay Congress, de Broglie suggested
a synthesis of the wave andparticle nature of
matter.
Pauli used a specific example to criticize de
Broglies theory de Broglie and others responded
poorly or not at all, leaving the Copenhagen
theory to be accepted.
Experience has shown the consistency of the
Copenhagen interpretation and that fundamental
atomic phenomena are discrete
Physical reality is whatever quantum mechanics
is capable of describing Cushing on Borhs
thoughts
The subjective epistemological criterion of the
need for classical concepts to describe the
results of measurements Cushing on Copenhagens
thoughts

Copenhagen interpretation refers to a common set
of principles shared by a group of scientists who
follow Bohr.
Differences between Old School should be clear
New School was by no means in total agreement
over quantum theory
The next presentation will explain this!!