I-4
I. E-M Radiation and interaction with matter (particles)
McHale, Ch 3 / Struve, Ch1 / Bernath, Ch1 / Flygare, Ch11
For molecular spectra we take “hybrid” approach →
treat molecules with QM
E-M fields classically – (as waves)
Maxwell’s Eqn describe Classical E-M
E, B fields in phase
mutual perpendicular to k
n(Hz) → freq = 1/l
SI unit: or e = mp = 1.0 vacuum
e ~ 1 – 80 (H2O) material dependent
(no magnetic monopoles) B → magnetic induction
H → magnetic field
(m0e0)-1 = c2 speed of light - related to e0 electric permitivity
Alternate: (add current) current
- charge density x velocity
m0 - magnetic permeability
1st equation - relates to electro-statics – how fixed fields work
How do these relate to E-M? - they couple B, E (3rd, 4th equations)
by substitution can derive wave equations:
wave equations, 2nd order differential in space, time
Solve with general form – B, E will vary with this functionality
Can rewrite using a scalar and vector potential: f, A
if no charge Df = 0
satisfy
clearly E and B are in phase and orthogonal
Wave equation becomes: with solution of: A = A0ei(k.r – wt)
Wave Equations see Flygare: Chap 1
Maxwell eqn: (SI) (e0m0)-1 = c2 vacuum
1. mp = e = 1
2. m0, e0 cont
3. J = rv - current density
4. recall: - gradient operator
then: - divergence, - curl
and - LaPlacian operator
Meaning of equations:
1 → (Faraday) time dep → induce (since cancels )
2 → (Ampere-Oersted) time dependent electric (displacement) field produces
3 → (Coulomb Law) field relate to change
4 → no magnetic monopoles
Define scalar and vector potentials
Scalar Potential:
f: static (time independent) 1.
i.e. fits Max. eqn 1: – due to cross product, no B field)
note:
Poisson’s eqn - scalar potential from charge
(vacuum: LaPlace eqn: )
Vector Potential:
A: time varying consideration 2.
Subst. into Max. Eqn. #1
Constrain variables (f=0)
Scalar vector: (eqn. 5)
(but if use the Lorentz convention)
Wave equation for the scalar potential
Use the definitions with Maxwell #3:
from above take (eqn.5):
plug in and rearrange (no current):
Wave equation for the scalar potential -- Now some arithmetic:
Next take eqn (2):
substitute:
If J = 0 then
Solution:
let A
-k2A
wave vector: k~1/l: k
note: mp = 1 (non-magnetic medium) (refractive index- light)
propagation vector speed of light:
Poynting vector in vacuum n = 1.0
Now use equations
B
E E ІІ A
E, B are time oscillating (w) and spatial varying (k) fields E-M radiation
Interaction of Radiation and Matter
Turn Back to Molecules
In 542 you learned many problems need approximation → many particle systems
ex: Consider benzene 6 – C’s
6 – H’s
36 + 6 – electrons
Huge dimensionality – relatively small molecules.
Here we will discuss variants of two methods
Perturbation Theory – extend to time dependent
Variation Theory – modify for Hartree-Fock (elect structure calculation)
Time dependent Perturbation Theory – Struve, Ch 1
Levine, Ch 9.9 - 10
Electrostatic fields McHale, Ch 3 - moments
Molecule has changes qe and dipole m
en – change of nth particles or electron nucleus
rn – position of nth particles or electron nucleus
Energy of interaction with electrostatic field
where is the scalar potential at the origin
is the electric field
is the quadrupole tensor element ij
Magnetic fields since no magnetic monopoles
where is the magnetic field
[recall is actual field (magnetic indulation), is applied field]
Time Independent Perturbation Theory
Recall if both , let
Connections to energy depend on ,
higher connections → more powers or more terms from use higher order f:
Effect of perturbation is to mix the states with it on, initial state now has some fraction of other states so can say there is some probability
here:
of
having the characteristics of
aside: If time dependant, can view state as evolving in time can change its nature
Polarizability – above we have
but this only addresses “permanent” dipole moment of molecule – applies force to changes, separates them and induces a dipole
modify
classical E:
in general, a is a tensor – molecular response more complex
Compare this to 2nd order perturbation theory see terms to power E2 are
a note eigen slip
Molecules and atoms with biggest electron systems or most loosely bound elections → big a
ex: H = 0.667 Å3, Li = 24.3 Å3, Cs = 59.6
Now light radiation is an electro-magnetic field
interaction will parallel this E = -m – E
but here E = E(t) and B = B(t)
used to modify the approach
Time dependent fields
Maxwell equations lead to description of E-M field
and are in phase, but oriented 90º apart expressed ??? a vector potentialand
the Coulomb Gauge:
f = 0 (free space)
then:
(from) ( II )
(from, and ) ()
We can show [Struve, p.11] that effect on H is:
conservative potential
i.e. change interaction inside the molecule
expand
H0 remember
0 Coulob operator
time independent
2nd term in A2 ~ 0 since fields (pert.) small
time variation let
To use Time dependent Perturbation Theory McHale, Ch 4 consider
time independent w/f
when form complete set
when wave functions must change but – recall expand in complete set
now if is turned off, molecule will be in a time independent state
or cn = 1
cn = 0 nk
Time dependent Schrödinger Equation goes:
multiply left by and use to get orthogonal normality condition
(mn)
rearrange to:
now recall initially ck = 1
cn≠k = 0
so can approximate (i.e. for “short” time)
time variation of wave function is in coefficient: (on “weak” perturb)
where
operative equation:
integrate to give:
can do higher orders but they are not normally needed unless very big
perturbations – ex. laser-intense fields
For linear spectroscopy:
so substitute
expand
1st term:
assume (i.e. E = Ex, B = By, k = k2)
from Struve:
so
Electric dipole transition
dipole moment
expression correct
continuing
Now recall
so probability that at a time = t
system will be in a state
conditions
integral if
Draw get 1, otherwise get 0
now if , delta function not exactly connect get a very sharp peaked
function center at w = -wkm
Also should do this for real part of and result is sine function
(no integral)
Now one can go beyond level to include terms from
prep in y, pull on x
these give rise to
M1 (Lz) E2
magnetic dipole: M1
electric quadrupole: E2
and others could follow
M1 – responsible for EPR, NMR transitions can be important in trans metal spectra
and central to optical activity
E2 – rare but can occur (Electric quadrupole)
Relative sizes: recall expansion
visible light l ~ 5000 Å
infrared light ~ 100,000 Å
r ~ size molecule – medium benzene ~ 5 Å
visible/benzene
uv a little bigger (factor 5)
in order magnitude smaller
Then recall probability bigger reduction yet!
So M1 and E2 effects can be neglected for most molecules except nmr, epr, CD
Selection rules – since for E1
E1 need to have is odd must be even
a) must be opposite parity (odd, even)
b) polarization will affect transitions of oriented molecules
[if gas on liquid average one ]
rotation must have permanent dipole / vibration elect dipole must change
E2, M1 – similar but
a) same parity (even, even) (odd, odd)
b) Orientation can affect
Operate E1 – m-wave, IR, uv-vis absorption (electronic)
M1 – ESR, NMR, CD, weak electronic
E2 – same select rules as Raman, 2 phota but not mechanical
Error in last lecture:
McHale, Chap 4
agree:
Assume ck = 1, cm = 0, mk start at t = 0
Probability:
Note: integral from 0t because assume that cm = 0 at t = 0 (and before)
small correction (after expansion and electric dipole approximation):
Real part eiwt
Substitution:
Now consider probability term, time integral:
so there are 2 terms, one dominates in absorbance
where w = wmk , emission: w = - wmk
Return to probability – square the integral, absorbance: choose w = wmk
on ( – ) term dominant
Dw = wmk – w
Plot: : (wmk – w)
Long time: Note:
Transition Rate:
absorption stimulate
emission
Formal Golden Rule: d(Dv) = 2p d(Dv)
Probability linear in time → longer expose sample to light
the higher probability of a transition
Rate is what we measure experimentally – flex of light
stimulate an absorbance (loss of flex rate abs)
Uncertainty – lifetime
f(Dw, t) has a width:
dt → lifetime of state or duration on pulse (especially f-sec)
Ch 4.3 Book does nice relationship of density of photon states
and the rate of transition. Development not central
Ch 4.4 Then a detailed discussion of polarizability. We will put
this off until we address scattering. Now focus on dipole
Ch. 3 Frequency dependent polarizability – note complex due to relax
here t is a relaxation of state, is rate of decay
express quantum mechanically
this picture misses live widths → relaxation → complex function
can insert into denomination.
Allows quantum mechanic definition of oscillation strength
convenient method of categorizing transition:
How is this evidenced in matter?
Aside: refraction: speed light in vacuum – C (const)
speed light in material –
refractive index =
most non-magnetic m ~ m0 (4p x 10-7 ) ?
relative permitivity
actually complex – real → dispersion (refraction)
imaging → absorption
since index normally > 1, = 1 vacuum, refraction
– will cause denaturation from path on charge n
– will be greater at an absorbance
Absorbance – attenuation intensity:
b = x
g = 2,3 e c
at w ~ wkm
absorbance relates to probability of charge state
McHale,Ch. 3 Polarizability is response of material to electric field
induced dipole moment:
if model e response to force as Hook Law → harmonic oscillation →
multiplication:
see text – time dependent:
Kuernes Kronig:
QM:
see similar resonance big a
Now see oscillation strength:
relative permetivity response of medium to field
E – apparent field / E0 – applied
dielectric constant – factor reduction Coulombic force
Apply field induces polarization (P) in medium to oppose it
Elective susceptibility
l = er - 1
isotropic medium
Parallel polarizability:
if using frequency
same with refraction
since: n2(w) = er(w)
plus into
Now:
so absorb coefficient:
for solution:
relate to dipole expression (Einstein?)
McHale, Ch 6; Struve, Ch 8; Bernath, Ch 1
Einstein relationships are phenormalized expressions of rates of ???
up r12 = N1 B12 r(n) N1 – population lower state
B12 – stimulated rate constant at n
down r21 = N2 (B21 r(n) + A21) r(n) – energy density
A21 – spontaneous rate
note: only interested in n = n12 → resonant frequency
simple kinetics – no light
radiative lifetime: 1st order decay
if light on a long time system comes to equilibrium
N1 B12 r = N2(B21 r + A21) and
solve for DE = hn
(relating r(n) to kinetics)
if let r(n) be a black body light source (also equilibrium)
(gives denomination term)
see that A21 depends strongly on n3 → probability of spontaneous emission increase
as go to the uv
Two emission processes
Compare rates high n → uv – spontaneous dominance
low n → IR – stimulated dominance
Important → spontaneous (fluorescence) – incoherent
→ stimulated (e.g. laser) – same properties as
incident photoreduction and polarization
So how do lasers work in vis-uv (note kT ~ 200 cm-1 – for IR)
non-equilibrium devices → population inversion
must make N2 > N1 (non ???)
Recall Lumbert Law: dI = -g I dx I = I0 e-gx
positive absorption loss of intensity
negative emission (stimulated) amplification
relate power/volume to energy density/time:
assume B12 = B21
relate to einstein: (correct c for n) non degenerate B12 r(n)
r(n) → nI(n)g(n)/c
Lumbert Law:
now back to macroscopic: complex part
of induced polarization
~ 2n(w) k(w)
Relate back to Golden Rule:
rethink Coulent Law:
assume electronic/no stimulated emission
I in increment dx (cross section: 1-unit) (N2 ~ 0)
Beens Law: -dI = 2.303 a(n)CIdx I = I0e-acx a(n) = e(n)
(C-cone M, a(n) – malar absorption (per cm) molec abs
Combine to get rate:
( u(n) energy density )
To account for bandwidth
but normally r(n) constant over bandwidth – take out and compare to relationship for B12
so if meamic spectra, integrate, connect for path and core
can determine B12 experimentally also
in D2
(devices for homework!)
McHale 6.6? Line shapes
Homogenous → “all affect same way” → typical lifetime
time and freq complementary variable (inverse)
Fourier Transform relate then: (on correlation function)
Lomentzian: FWHM
(very long tails)
This concept for single state transition →
for electronic –vibration (mix) or (rotation-vibration) the
distribution of states (if unresolved) shape
Bernath, p31 Inhomogenous broadening → collection of molecules has a distribution
Fig 1-22 of resonant freq n12
Gaussian dist