1. Time independent Hoo = Eoo Stationary States mo  m
Time dependent
[Ho + V(t)] = iħ/t
m 
o
Harry Kroto 2004

2. Time independent Hoo = Eoo Stationary States mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
m 
o
Harry Kroto 2004

3. Time independent Hoo = Eoo Stationary States mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
Ee (t) = Eeocos 2t
m 
o
Harry Kroto 2004

4. Time independent Hoo = Eoo Stationary States mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
Ee (t) = Eeocos 2t
Ee(t) Radiation field
m 
o
Harry Kroto 2004

5. e Electric dipole moment
Time independent
Hoo = Eoo
Stationary States
mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
Ee (t) = Eeocos 2t
Ee(t) Radiation field
e Electric dipole moment
m 
o
Harry Kroto 2004

6. e Electric dipole moment  = mam(t) m
Time independent
Hoo = Eoo
Stationary States
mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
Ee (t) = Eeocos 2t
Ee(t) Radiation field
e Electric dipole moment
 = mam(t) m
m 
o
Harry Kroto 2004

7. e Electric dipole moment  = mam(t) m
Time independent
Hoo = Eoo
Stationary States
mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
Ee (t) = Eeocos 2t
Ee(t) Radiation field
e Electric dipole moment
 = mam(t) m
m 
o
Harry Kroto 2004

8. e Electric dipole moment = mam(t) m
Time independent
Hoo = Eoo
Stationary States
mo  m
Time dependent
[Ho + V(t)] = iħ/t
V(t) = -Ee(t) e
Ee (t) = Eeocos 2t
Ee(t) Radiation field
e Electric dipole moment
= mam(t) m
am(t) indicates how the population of state m varies in time
m 
o
Harry Kroto 2004