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Transcript
PHY 102: Waves & Quanta
Topic 14
Introduction to Quantum Theory
John Cockburn (j.cockburn@... Room E15)
•Wave functions
•Significance of wave function
•Normalisation
•The time-independent Schrodinger Equation.
•Solutions of the T.I.S.E
The de Broglie Hypothesis
In 1924, de Broglie suggested that if waves of wavelength
λ were associated with particles of momentum p=h/λ,
then it should also work the other way round…….
A particle of mass m, moving with velocity v has
momentum p given by:
p  mv 
h

Kinetic Energy of particle
2
2
2
2
p
h
 k
KE 


2
2m 2m
2m
If the de Broglie hypothesis is correct, then a stream of
classical particles should show evidence of wave-like
characteristics……………………………………………
Standing de Broglie waves
Eg electron in a “box” (infinite potential well)
V=
V=
V=0
Electron “rattles” to and fro
V=
V=
V=0
Standing wave formed
Wavelengths of confined states
In general, k =nπ/L, n= number of
antinodes in standing wave
2L
3

;k 
3
L
2
  L;k 
L
  2L ; k 

L
Energies of confined states
 k
 n
E

2
2m
2mL
2
2
2
En  n 2 E1

E1 
2
2mL
2
2
2
2
Energies of confined states
En  n E1
2

E1 
2
2mL
2
2
Particle in a box: wave functions
From Lecture 4, standing wave on a string has form:
y ( x, t )  ( A sin kx) sin( t )
Our particle in a box wave functions represent
STATIONARY (time independent) states, so we write:
 ( x)  A sin kx
A is a constant, to be determined……………
Interpretation of the wave function
The wave function of a particle is related to the probability
density for finding the particle in a given region of space:
Probability of finding particle between x and x + dx:
 ( x ) dx
2
Probability of finding particle somewhere = 1, so we have
the NORMALISATION CONDITION for the wave
function:

  ( x)

2
dx  1
Interpretation of the wave function
Interpretation of the wave function
Normalisation condition allows unknown constants in the
wave function to be determined. For our particle in a box
we have WF:
nx
 ( x)  A sin kx  A sin
L
Since, in this case the particle is confined by INFINITE
potential barriers, we know particle must be located
between x=0 and x=L →Normalisation condition reduces
to :
L
  ( x)
0
2
dx  1
Particle in a box: normalisation of wave functions
  ( x)
0
 nx 
A  sin 
dx  1
 L 
0
L
L
2
dx  1
2
2
nx
 ( x) 
sin
L
L
2
Some points to note…………..
So far we have only treated a very simple one-dimensional
case of a particle in a completely confining potential.
In general, we should be able to determine wave functions
for a particle in all three dimensions and for potential
energies of any value
Requires the development of a more sophisticated
“QUANTUM MECHANICS” based on the SCHRÖDINGER
EQUATION…………………
The Schrödinger Equation in 1-dimension
(time-independent)
 d  ( x)


V
(
x
)

(
x
)

E

(
x
)
2
2m dx
2
2
KE Term
PE Term
Solving the Schrodinger equation allows us to calculate
particle wave functions for a wide range of situations (See
Y2 QM course)…….
Finite potential well
WF “leakage”, particle has finite probability of being found in barrier:
CLASSICALLY FORBIDDEN
Solving the Schrodinger equation allows us to calculate
particle wave functions for a wide range of situations (See
Y2 QM course)…….
Barrier Penetration (Tunnelling)
Quantum mechanics allows particles to travel through “brick walls”!!!!
Solving the SE for particle in an infinite potential well
V ( x)  0
0xL
So, for 0<x<L, the time independent SE reduces to:
 2 d 2 ( x)

 E ( x)
2
2m dx
d 2 ( x) 2mE ( x)

0
2
2
dx

General Solution:
1/ 2
 2mE 
 ( x)  A sin  2 
  
1/ 2
 2mE 
x  B cos 2 
  
x
1/ 2
 2mE 
 ( x)  A sin  2 
  
1/ 2
 2mE 
x  B cos 2 
  
x
Boundary condition: ψ(x) = 0 when x=0:→B=0
1/ 2
 2mE 
 ( x)  A sin  2 
  
x
Boundary condition: ψ(x) = 0 when x=L:
1/ 2
 2mE 
 (0)  A sin  2 
  
n 
E
2
2mL
2
L0
2
2
nx
 ( x)  A sin
L
In agreement with the “fitting waves in boxes” treatment earlier………………..