high temperature optical spectra of diatomic molecules ...structure of the molecular bands, neglects...
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High temperature optical spectra of diatomic molecules:
quantum-mechanical, semiquantumand semiclassical approach
Robert M. Beuc, Berislav Horvatić and Mladen Movre
Zagreb, Croatia
Outline
Reduced absorption coefficient of a dimer
Quantum calculation on the Fourier grid
Sodium resonance 3s-3p line pressure broadened byhelium atoms
Semiclassical approximation
Semiquantum approximation
Absorption spectra of potassium molecule
Cesium emission and absorption spectra
Hybrid approximation
Absorption spectra of rubidium molecule
According to the Beer-Lambert law, in terms of binary collisions, thetransmittance T((v,T) of a uniform atomic gas layer with a number density of
atoms n and length L is where k(v,T) is thereduced absorption coefficient of atomic dimer, is frequency of absorbed
photon and T is temperature.
LTknT ),(exp),( 2
Reduced absorption coefficient of a dimer
Λ'' and Λ' label the lower and the upperelectronic state. VΛ(R) is the interaction potential
Bound (quasi-bound) states: energy Ev,J,Λ , unity-normalized wave function , v vibrational andJ rotational quantum number
Free states: asymptotic kinetic energy ε , energy-normalized wave functions
)()()( 2
22
2
22 )1(
22RERRV
R
JJ
dR
d
ji
TkTkji
,
, ),(),(
,,Jv
,,J
1,),(,
JJJJ
vvtransitionTk
Neglecting the differences between even and odd J, assuming the applicabilityof the Q-branch approximation ∆J=0, the thermally averaged absorptioncoefficient [H.-K. Chung, K. Kirby, J.F. Babb, Phys. Rev. A, 1999, 2001]:
bound (quasi-bound) - bound (quasi-bound) transitions:
)()exp()()12(),(2
,
2/3
238
,
23
trTk
E
JvJv
vvJ
Tkh
hcbb hhgRDJwTkB
Jv
B
,,,, JvJvtr EEh
),(),(),(),(),(, TkTkTkTkTk fffbbfbb
hE Jv ,,
)exp()()12(),(22/3
238
,
23
Tk
E
JJv
vJ
Tkh
hcbf B
Jv
BRDJwTk
free - bound (quasi-bound) transitions:
bound (quasi-bound) –free transition:
hE Jv ,,
)exp()()12(),(22/3
238
,
23
TkJvJ
vJ
Tkh
hcfb BBRDJwTk
free-free transitions: h
)exp()()12(),(22/3
238
,
23
TkJJ
DJ
Tkh
hcff B
e
BRDdJwTk
D(R) is electronic transition dipole moment, w is statistical factor dependent on the symmetry of electronic states, is molecular reduced mass, g line profile.
Quantum calculation on the Fourier grid (QC)
The FGR method can be considered as a specialcase of Discrete Variable Representation wherefunctions are represented on finite number ofgrid points Ri (i=1…N) . We used a grid ofuniformly spaced points, Ri+1- Ri = ∆R, [D.T.
Colbert, W.H. Miller, J. Chem. Phys. 1992]. Energiesand wave functions can be determined bydiagonalization of NxN Hamiltonian matrixH=T+P :
ji
jiT
ji
ijjii
Rji222
2
2
2
2
8
2
13
2, 1
jiR
JJ
ijii
RVV ,
)1(
2, 2
22
)(
The method yields only a discrete set of continuum energies, but in the range spanned by the grid the corresponding unity-normalized wave functions do represent the states of a true continuum.
Solving the relevant radial Schrödinger equation on the grid one obtains a set ofdiscrete energies effectively describing a confined molecule, “a molecule in abox”, and the entire spectrum is of the bound–bound type.
The matrix elements of the transition dipole moment D(R) are computed as:
pN
i
iJiiJJJ RRDRRD1
, ,v, ,v,,v,,v )()()()(
The parameters of the grid are estimated in the following way:nB is the number of grid points per de Broglie wavelength atmaximal expected kinetic energy εkin .
RN was chosen in order to get closer to the atomic line centre.
Line profile g can be approximated with a normalized rectangular instrumentalprofile:
max23
0
2
,
2/3
238 )()exp()()12(),(
J
J
trTk
E
JvJv
vv
Tkh
hchhgRDJwTk
B
Jv
B
h/1
Fully quantum-mechanical procedure based on the Fourier grid Hamiltonianmethod, is numerically robust but time consuming.
kinBnR
2
2
TkJ B
RN 2max
Sodium resonance 3s-3p linepressure broadened by helium atoms
Good agreement with:C. Zhu, J. F. Babb and A. Dalgarno, Phys.Rev. A:2006K Alioua , M Bouledroua ,A R Allouche and M Aubert-Frécon, J. Phys. B: 2008
Semiclassical approximation (SCA)
Introducing a continuous variable Y = J(J + 1) andchange
Any unity-normalized wave function Φv can be turnedinto an energy-normalized wave functionand the sum can be changed into the integral
J
dYJ0
)12(
vv
JvE
,,
1
dv
v
min
The absorption coefficient can be written as:
2
',,"",,"
0
2/3
238 )()exp(),(
min
23
YhYTkTkh
cRDdYdwTk
BB
Using energy-normalized wave functions in the WKB form, and the standard approximations, one obtains:
)),,,(cos()( 4)(),(
)(
2
2
,,,, 4
4
iiRYRV
RD
i
YhY RYRDii
i
Difference potential: )()()( RVRVR )()( RRdRd )(sgn ii R
Sumation is over the Condon points Ri satisfying the condition . hRi )(
Neglecting the rapidly oscillating terms , one obtains coherent quasi-static formula of the reduced absorption coefficient :
1
1
)(
)()(
)()(
1
)(
)(
)(
332 ),()exp(2)exp(),(
1
12224
n
i
iTB
k
RV
RR
RDRDRn
iT
Bk
RV
R
RDR
cTMwTk ii
ii
iiiii
i
ii
Elementary profile type:1. Difference potential Δ(R) is a monotonic function, one real Condon point R1
2. Difference potential Δ(R) is a monotonic function, one inflection point RI,one real Condon point R1 and complex pair of Condon points R2,3
3. Difference potential Δ(R) has extrema , two Condon points R1,2
If difference potential Δ(R) has more extremes, absorption profile can be
obtained by combining the elementary profiles.
Quasi-static formula generally gives a good description of the absorptioncoefficient, but diverges in difference potential extremes (classicalsingularity).
This divergence can be removed by mapping of the semi-classical canonicintegral phase, into the characteristic form of the elementary "fold" or"cusp" catastrophe.
0.5
0.0
0.5
Re R
2
1
0
1
2
E
0.5
0.0
0.5
Im R
2. Difference potential Δ(R) has one inflection point RI
transitive Pearcey approximation
),()exp(),()(
)(
)(
332 1
1
21
21
4
TLwTk cTB
k
RV
R
RDR
c
dzPYXL
z
Y
z
X
z
zXYYXYYX
c
2)exp(
0
),(),( 8/34/14/32/3
323
223
2783
223
278
4/12
)(3
2)()(TkRI
BIRTX
8/324
)(3
2)(),(TkRI
BIhRTY
dueyxP yuxuui
24
),( Pearcey integral
If Y(v,T)>5 or X(T)>5, what is the most common case, 1),( TLc
0)( IR
Lf x
Mf x
hf x x
gf x x
2 0 2 4 6 8 100.5
0.0
0.5
1.0
1.5
x
3. Difference potential Δ(R) has extrema in point Re
J.N.L. Connor, R.A. Marcus, J. Chem. Phys. 1971K.M. Sando, J.C. Wormhoudt , Phys. Rev. A 1973J. Szudy, W.E. Baylis, JQSRT 1975P.A. Vicharelli, C.B. Collins, SLS1983 R. Beuc and V. Horvatic: J. Phys. B: 1992R. Beuc, B. Horvatić, M. Movre, J. Phys. B, 2010 1.0
0.5
0.0
0.5
1.0
Re R
2
1
0
1
2
E
0.5
0.0
0.5
Im R
0)( eR
)()()( 1
ghLc )()()( 1
ghM c
dxeh x
x
Aix
3/2
2
3/1
0
)(
dxeg x
x
Aix
3/1
2
3/1
0
)(
)(),(31
2
)(
4 eRTk
h
eBTv
)()(
)()exp(2
)()exp()exp(),(
32
2
)(6
)(31
2)(
3/2
261
2
1
21
212
1
2
2
22
221
1
21
21
4
)(
)(4
8
2
)(
8
)(
)()(
)()(
)(
)(
)()(
)(
)(
332
ghRDe
M
LwTk
e
eReR
eeBTBkeRV
e
e
B R
RDRD
m
Tk
eR
R
Tk
m
fTB
k
RV
RR
RDRDR
fTB
k
RV
R
RDR
TB
k
RV
R
RDR
c
uniform Airy approximation
The standard semiclassical approximation does not give the rovibrationalstructure of the molecular bands, neglects the effects of turning points, butagrees perfectly with the averaged-out quantum-mechanical spectra.Also, the semiclassical theory can give a physical interpretation of the resultsobtained by fully quantum- mechanical calculations (W. H. Miller).
Semiquantum approximation (SQA)
2
,0,,0,2332 )()exp(),(
min
21
24
hTkTk
hc
RRDdwTkBB
Turning energy-normalized wave functions to unity-normalized wave functions one obtains
)()()exp(vv),(2
',0,v",0,"v
00
2/1
2332 ,0,v
24
trTk
E
Tkh
chhRRDddwTk
BB
Using standard semiclassical approximations, we calculated integral :
2
,0,,0, )()exp(
min
hTkRRDd
B
By comparison with the semi-classical form of reduced absorption coefficient,we get expression:
One can approximate the integrals by sums
and obtain a quantum-like (“quasiquantum” or “semiquantum”) expression.
)()()exp(),(2
',0,v'",0,v"
ν,v"
2/1
2332 ",v"
24
trTk
E
Tkh
chhgRRDwTk
BB
The semiquantum approximation is in very good agreement with fullyquantum calculations, while its computer time consumption can be lower byfour orders of magnitude.A disadvantage of this method is an unsatisfactory description of the discretestructure of molecular bands.However, even the low-resolution absorption spectroscopy may serve as avaluable tool for checking the accuracy of molecular electronic structurecalculations, and for gas temperature and number density diagnostics .
In order to evaluate this relation, one needs to know the vibrational energiesand the corresponding wave functions for J = 0 only.Semiquantum approximation gives good results if the distance between thevibrational transitions is comparable or less than the widthof the instrumental profile g.The semiquantum spectrum was collected in bins of the size Δhν = 10 cm-1
and smoothed out with a simple unity-normalized triangular profile having awidth of 50 cm-1.
,, vvtr EEh
R. Beuc, M. Movre, B. Horvatić, Eur. Phys. J. D, 2014
In the theoretical simulation we used ab initiopotential energy functions and the relevant transitiondipole moments [L. Yan, W. Meyer, unpublished results],experimentally determined potential functions for thesinglet transitions [C. Amiot, J. Mol. Spectrosc. (1991) and
C. Amiot, J. Vergès, C.E. Fellows, J. Chem. Phys. (1995)],and the long-range calculation [M. Marinescu, A.
Dalgarno, Phys. Rev. A (1995)].
Absorption spectra of potassium molecule
The quantum-mechanical calculationfor temperature T = 985 K.
Comparison of QC, SQA and SCA forvapor temperature T = 985 K.
For the calculation of theabsorption spectrum of the B–Xtransition, the computer time was:3000 s for the QC0.2 s for the SQA and SCA.
Comparison of QC, SQA and SCA fora range of temperatures.
We compare experiment [C. Vadla, R. Beuc,
V. Horvatic, M. Movre, A. Quentmeier, K.
Niemax, Eur. Phys. J. D,2006] and QC fortwo experimental temperatures. A slightincrease in the simulated B–X bandintensity may be attributed to theuncertainty in the ab initio transitiondipole moments.
Cesium emission and absorption spectra
B. Horvatić, R. Beuc, M. Movre, Eur. Phys. J. D, 2015
A recent ab initio [A. R. Allouche, M. Aubert-Frécon, J. Chem. Phys. 2012] calculationof Cs2 electronic potential curves and electronic transition dipole momentsprovided us with an input for the numerical simulation of Cs2 spectra.We investigated the red and near–infrared (600 – 1300 nm) absorption andemission spectrum of a cesium vapor for temperatures within the range 600 –1500 K using SQA.
11 singlet and 19 tripletelectronic transitions Λ'' Λ' contribute to theabsorption spectrum.The computing time was 6– 60 seconds , dependingon the temperature.
In the LTE approximation, the spectralradiance of a uniform emitting layer(thickness L, atomic number density N)is:
1
1),(
/
)/exp(1),(
2
2
2
3
Tkh
TkhTLkN
c
h
B
B
e
eTI
(a) optically thick medium κN 2L >> 1, N 2L = 3 ·1034 cm-5
(b) optically thin mediumκN 2L << 1), N 2L = 1029 cm-5
Absorption spectra for a range oftemperatures.
Absorption spectra of rubidium dimer
R. Beuc, M. Movre, V. Horvatic, C. Vadla, O. Dulieu and M. Aymar , Phys.Rev. A, 2007
In the framework of FGH method, energies and wavefunctions for coupled states can be determined bydiagonalization of 2N x 2N matrix H
bso
soA
VV
VV
T
TH
0
0
ji
jiT
ji
ijjii
Rji222
2
2
2
2
8
2
13
2, 1
jiR
JJ
ibAjibAi
RVV ,
)1(
2,,, 2
2
)(
jiisojiso RVV ,,)(
A-X absorption band is formedby a transition from ground0+
g(X1Σ+
g) state to excitedstates 0+
u(A1Σ+
u) and 0+u(b
1Πu)coupled by spin-orbitinteraction Vso(R).
)1(,v,,v JJBEE J ,0,v,0,v,,v,,v )()( RDRD JJ
bound
TkBB
hEB
BB
RD
Tk
E
Tkh
cbb B
vv
BBwTk
'v,"v
)()(,v2/3
238
, )exp()exp(),(vv
,
vv
2
,0,v,0,v23
,
,
If the dominant contribution to the spectrum consists of bound-bound transitions,and if the distance between the rotational lines is less than the width of theinstrumental profile, the absorption coefficient can be determined using thevibrational band continuum approximation (VBCA); [R.W. Patch, W.L.
Shackleford, S.S. Penner. JQSRT, 1962, L.K. Lam, A. Gallagher, and M.M. Hessel, J.Chem.Phys. 1977].
VBCA gives good results, if the dominant contribution comes from the transitionbetween the lowest vib-rotational states, where following conditions are satisfied
Hybrid approximation
vv
vv
v
v
v
v
vv
vv
BB
Eh
B
EE
B
EE
BB
EhvvEEG
,
'
',',, ,min),,,,(
',',,','
',',,
,min
1)',,,(
vvvv
vvv
EEEEEEEE
EEEEEvvEEE
Using good properties of SQA and VBCA, we introduced a hybrid approximation (HA) of the reduced absorption coefficient:
,
2
',0,v'",0,v"
)',,,(2/1
2332
,
,
)()(,v2/3
238
)()()exp(
),,,,()exp()exp(),(
24
,
2
,0,v,0,v23
trTk
vvEEE
Tkh
c
VV
vv
TkBB
hEB
BB
RD
Tk
E
Tkh
c
hhgRRDw
vvEEGwTk
BB
Bvv
vv
vvBB
The first contribution to k(v,T) is the VBCA of transitions for which and
, and the second contribution is the SQA of all other transitions. ,, JvEE
'J,,' vEE
0
20
,0
v
v
D
BxEE
0
20
,0
v
v
D
BxEE
,, JvEE )1(,v,,v JJBEE J ,0,,, vJv
,, JvEE )1(,v,,v JJBEE J ,0,,, vJv
Theoretical simulations of rubidium A-X band at a temperature of 740 K.
QC
HA
750 800 850 900 950 1000 1050 11000
5. 10 36
1. 10 35
1.5 10 35
2. 10 35
2.5 10 35
nm
kcm5
QC
VBCA
SQA
750 800 850 900 950 1000 1050 11000
5. 10 36
1. 10 35
1.5 10 35
2. 10 35
2.5 10 35
nm
kcm5
Comp. time:QC=2618 sVBCA=126 sHA=16 s SQA=0.3 s
The hybrid approximation improves the description of the molecular bandsstructure at a cost of an acceptable increase of the computer time.
Thank you for your attention
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