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Lecture 3
The Schrödinger equation
(c) So Hirata, Department of Chemistry, University of Illinois at Urbana-Champaign. This material has
been developed and made available online by work supported jointly by University of Illinois, the
National Science Foundation under Grant CHE-1118616 (CAREER), and the Camille & Henry Dreyfus
Foundation, Inc. through the Camille Dreyfus Teacher-Scholar program. Any opinions, findings, and
conclusions or recommendations expressed in this material are those of the author(s) and do not
necessarily reflect the views of the sponsoring agencies.
The Schrödinger equation


We introduce the Schrödinger equation as
the equation of motion of quantum chemistry.
We cannot derive it; we postulate it. Its
correctness is confirmed by its successful
quantitative explanations of all known
experimental observations.*
*Some restrictions apply: There are observable effects due to the special
theory of relativity such as the spin-orbit coupling, intersystem crossing, and
other scalar relativistic effects. These effects can be substantial in heavy
elements. There are also observable quantum electrodynamics effects, which
cannot be described by the Schrödinger equation, either. They are small.
The Schrödinger equation

Classical mechanics fails in describing
motion in the atomic and molecular scales
and is simply incorrect. A new, correct
equation of motion is needed and it has to
acknowledge:


Quantized nature of energy,
Wave-particle duality.
The Schrödinger equation

The correct equation of motion that work for
small particles has been proposed by Erwin
Schrödinger.
Hamiltonian
Ĥ  E
Wave function
Energy
The Schrödinger equation
Erwin Schrödinger
Hamilton’s representation
of classical mechanics
Newton’s equation of motion = the conservation
of energy (kinetic + potential energies = constant)
Hamiltonian
Energy
H E
Classical
2
p
H
 V ( x)
2m
Kinetic energy
Potential energy
Hamilton’s representation
of classical mechanics
¶H
H =E®
=0
¶t
p2
H=
+ V (x)
v
2m
¶H ¶ p 2 ¶V (x) 2 p ¶ p ¶x ¶V (x)
®0=
=
+
=
+
= vma + v(-F)
¶t
¶t 2m
¶t
2m ¶t ¶t ¶x
® F = ma
v
ma
−F
The Schrödinger equation


In quantum mechanics, energy should be
conserved, just as in classical mechanics.
Schrödinger used the Hamilton’s equation as
the basis of quantum mechanics.
d
ĤY = EY; Ĥ = + V̂ (x)
2
2m dx
2
p
H  E; H 
 V ( x)
2m
2
Quantum
Classical
2
Hamilton’s representation
of classical mechanics


In classical mechanics, H is a function of p,
m, and x.
Once we know the mass (m), position (x),
and velocity (p = mv) of a particle, we can
know the exact trajectory (positions as a
function of time) of the particle from the
classical mechanics.
2
p
H  E; H 
 V ( x)
2m
The Schrödinger equation

However, the concept of trajectory is strictly
for particles only. Schrödinger needed to
modify the equation to account for the waveparticle duality.

Introduction of a wave function.
d
ĤY = EY; Ĥ = + V̂ (x)
2
2m dx
2
Wave function
2
The Schrödinger equation

The equation must also give energies that
are quantized

The operator form of equation.
H is now an operator
(it has a “^” hat sign)
d
ĤY = EY; Ĥ = + V̂ (x)
2
2m dx
2
2
Kinetic energy operator
What is “an operator”?

An operator carries out a mathematical
operation (multiplication, differentiation,
integrations, etc.) on a given function.
Value a
Function
f(x)
Value b
Darth Vader
Operator
F̂
Chancellor
function A(x)
function B(x)
The Schrödinger equation


Generally, when function A is acted on by an
operator, a different function (B) will return.
The Schrödinger equation says that the input
and output functions should be the same (Ψ),
apart from a constant factor (E).
Ĥ  E
Operator
Ĥ
function Ψ(x)
function EΨ(x)
Eigenvalues and
eigenfunctions

In general, operator Ω (omega) and a
function ψ (psi) satisfy the equation of the
form:
̂  
There are infinitely
many eigenfunctions
and eigenvalues
where ω is some constant factor, we call the
ω an eigenvalue ω of the operator Ω and the
ψ an eigenfunction of Ω. The equation of
this form is called eigenvalue equation.
The Schrödinger equation



A wave function associated with a well
defined energy is an eigenfunction of the H
operator with the eigenvalue being the
energy.
Not any arbitrary value of energy can be an
eigenvalue of the H operator.
This eigenvalue form of the Schrödinger
equation makes the energies quantized.*
*Strictly speaking, it is boundary conditions together with the eigenvalue form of
the equation that cause the energies to be quantized. We will learn about the
importance of boundary conditions in partial differential equations shortly.
The Hamiltonian operator

Ĥ is called the Hamiltonian operator.

It is an operator for energy.
d
Ĥ = + V̂ (x)
2
2m dx
2
Kinetic
energy
2
Potential
energy
The Hamiltonian operator

The kinetic energy operator is the operator for
kinetic energy:
p
d
®2
2m
2m dx
= h / 2p ( is called the h bar)
2

2
2
How can this classical to quantum translation be
justified?
The Hamiltonian operator


Again, this form is postulated, not derived. We
can try to imagine the thinking process of
Schrödinger who came up with this translation.
First, we see that postulating
2
2
2
p
 d

2
2m
2m dx
is the same as postulating
d
p  i ; i   1
dx
The Hamiltonian operator
d
p  i
dx
2
2
d
d
d
d


2
2
p 2  i   i    i 



dx 
dx 
dx 2
dx 2
p2
2 d 2

2m
2m dx 2
i 
2
 1  1
2
d ( AB) dA
dB

B
A
dx
dx
dx
The momentum operator

Let us call
d
 i
dx

the momentum operator and try to justify it.
We will apply this to “the simple wave” to see
that it is indeed an operator for a momentum.
The simple wave

A function describing a simple sinusoidal wave
with wave length λ (lambda) and frequency ν (nu):
 2

 ( x, t )  A cos
x  2t 
 

 2

 ( x, t )  A sin 
x  2t 
 

The simple wave

Euler’s relation
ei  cos   i sin 
2
3
4
x
x
x
ex  1 x    
2! 3! 4!
x2 x4
x3 x5
cos x  1    ; sin x  x    
2! 4!
3! 5!

Let us use a function to represent a wave
e
 2

i
x  2t 
 

The momentum operator

We act the momentum operator on the
simple wave
d
p  i
dx
e
 2

i
x  2t 
 

 2

i
x  2t 
 

d
d
 2
 i   i e
 i i
dx
dx
 
h
2 h 2
 i
 
2 


e

 2

i
x  2t 
 

The momentum operator



The simple wave is an eigenfunction of
the momentum operator with the
eigenvalue h / λ.
d
h
 i   
dx

According to de Broglie relation:
h
p

The momentum operator makes sense.
Time-dependent
Schrödinger equation


We have seen the effect of an operator that
differentiates with respect to x (position).
What if we differentiate with respect to t
(time)?
 2

i
x  2t 
 

d
d
i   i e
 i i 2 e
dt
dt
2 h
 i
2  h
2
 2

i
x  2t 
 

Time-dependent
Schrödinger equation



To reiterate the result:
d
i   h
dt
A sinusoidal wave is an eigenfunction of an
operator d with an eigenvalue of hv.
i
dt
According to Planck, hv is the energy of an
oscillator with frequency v.
Time-dependent
Schrödinger equation

We have found an operator for energy:
d
E  i
dt

Substituting this into the time-independent
Schrödinger equation, we have timedependent Schrödinger equation
d
ˆ
H  i
dt
Summary



We have introduced the Schrödinger
equation – the equation of motion of quantum
mechanics and “the whole of chemistry.”*
The time-independent Schrödinger equation
mirrors Hamilton’s representation of the
classical mechanics and physically
represents conservation of energy.
It incorporates the wave-particle duality and
quantization of energy.
*In the words of Paul Dirac.
Summary
Classical
Quantum
x̂
Position
x
Momentum
p = mv
 id / dx
Potential energy
V
Vˆ
Energy
E
Equation
H=E
Ĥ  E
Hˆ   id / dt 
Wave-particle duality
No. Particle only
Yes via the wave
function
Quantization
Continuous and nearly
arbitrary
Eigenvalues and
quantized
E or id / dt 