1. Conical intersections in quantum chemistry
Spiridoula Matsika
Temple University
Department of Chemistry
Philadelphia, PA

2. Conical intersections Electronic structure methods for CIs
MRCI
CIS(2)
Three-state CIs and their consequences
QM/MM for excited states

3. Nonadiabatic events in chemistry and biology

4. Molecular Hamiltonian
e2/rij j
Z e2 /ri
Z e2 /rj
Z Z e2 /R  

5. The Born-Oppenheimer (adiabatic) approximation
Separate the problem into an electronic and a nuclear part
Nuclear
Electronic

6. When electronic states approach each other, more than one of them should be included in the expansion
Born-Huang expansion
If the expansion is not truncated the wavefunction is exact since the set Ie is complete
Derivative coupling

7. Two-state conical intersections
Two adiabatic potential energy surfaces cross (E=0).The interstate coupling is large facilitating fast radiationless transitions between the surfaces

8. The Noncrossing Rule
The adiabatic eigenfunctions are expanded in terms of states I which are diagonal to all other states. (the superscript e is dropped here)
The electronic Hamiltonian is built and diagonalized
The eigenvalues and eigenfunctions are:
J. von Neumann and E. Wigner, Phys.Z 30, 467 (1929)
Atchity, Xantheas and Ruedenberg, J. Chem. Phys., 95, 1862, (1991)

9. Degeneracy
H11(R)=H22 (R)
H12 (R) =0
Dimensionality: Nint-2, where Nint is the number of internal coordinates

10. Geometric phase effect (Berry phase)
If the angle  changes from  to  +2:
The electronic wavefunction is doubled valued, so a phase has to be added so that the total wavefunction is single valued

11. Evolution of conical intersections

12. The Branching Plane
The Hamiltonian matrix elements are expanded in a Taylor series expansion around the conical intersection
Then the conditions for degeneracy are
For displacements x,y, along the branching plane the Hamiltonian becomes (sx,sy are the projections of onto the branching plane) :
Atchity, Xantheas and Ruedenberg, J. Chem. Phys., 95, 1862, (1991)
D. R. Yarkony, J. Phys. Chem. A, 105, 6277, (2001)

13. The Branching Plane E h g g-h or branching plane seam
Tuning coordinate:
Coupling coordinate:
Seam coordinates E h g
g-h or branching plane
seam

14. topography asymmetry tilt
Conical intersections are described in terms of the characteristic parameters g,h,s

15. Three-state conical intersections
Based on the same non-crossing rule one can derive the dimensionality of a three-state seam. Using a simple 3x3 matrix degeneracy between three eigenvalues is obtained if 5 conditions are satisfied. So the subspace where these conditions are satisfied is Nint - 5.
H11(R)=H22 (R)= H33
H12 (R) = H13 (R) = H23 (R) =0
Dimensionality: Nint-5
J. von Neumann and E. Wigner, Phys.Z 30, 467 (1929)
J. Katriel and E. Davidson, Chem. Phys. Lett. 76, 259, (1980)
S. Matsika and D. R.Yarkony, J.Chem. Phys., 117, 6907, (2002)

16. Requirements of electronic structure methods for conical intersections
Accurate excited states
Gradients for excited states
Describe coupling
Correct topography of conical intersections
Correct description at highly distorted geometries (needed usually for S0/S1 conical intersections in closed shell molecules but not necessary for all ci) *

17. Excited states configurations
Doubly excited conf.
Ground state
Singly excited conf.

18. Configurations can be expressed as Slater determinants in terms of molecular orbitals. Since in the nonrelativistic case the eigenfunctions of the Hamiltoian are simultaneous eigenfunctions of the spin operator it is useful to use configuration state functions (CSFs)- spin adapted linear combinations of Slater determinants, which are eigenfunctiosn of S2 - +
Triplet CSF
Singlet CSF

19. Or in a mathematical language:
Slater determinant:
Configuration state function:

20. Electronic structure methods for conical intersections
Multireference methods satisfy these requirements
MCSCF and MRCI

21. Locate 2-state intersections
Additional geometrical constrains, Ki, , can be imposed. These conditions can be imposed
by finding an extremum of the Lagrangian
L (R,  , )= Ek + 1Eij + 2Eij + 3Hij + 4Hik + 5Hkj + iKi
The algorithms are implemented in the COLUMBUS suite of programs.
M. R. Maana and D. R. Yarkony, J. Chem. Phys.,99,5251,(1993)
S. Matsika and D. R. Yarkony, J.Chem.Phys., 117, 6907, (2002)
H. Lischka et al., J. Chem. Phys.,120, 7322, (2004)

22. Derivative coupling
Similar to energy gradient

23. Geometric phase effect (Berry phase)
An adiabatic eigenfunction changes sign after traversing a closed loop around a conical intersection
The geometric phase can be used for identification of conical intersections. If the integral below is  the loop encloses a conical intersection

24. Radiationless decay in DNA bases
Implications in photoinduced damage in DNA
Absorption of UV radiation can lead to photocarcinogenesis
DNA and RNA bases absorb UV light
Bases have low fluorescence quantum yields and ultra-short excited state lifetimes
Fast radiationless decay can prevent further photodamage
Daniels and Hauswirth, Science, 171, 675 (1971)
Kohler et al, Chem. Rev., 104, 1977 (2004)

25. Exploring the PES of excited states using electronic structure methods
State-averaged multiconfigurational self-consistent field (SA-MCSCF)
Multireference configuration-interaction (MRCI)
MRCI1: Single excitations from the CAS (~1 million CSFs)
MRCI: Single excitations from CAS +  orbitals (~10-50 million CSFs)
MRCI: Single and double excitations from CAS + single exc. from  orbitals ( million CSFs)
Locate minima, transition states, and conical intersections
Determine pathways that provide accessibility to conical intersections

26. Conical intersections in nucleic acid bases
Uracil
Cytosine
S. Matsika, J. Phys. Chem. A, 108, 7584, (2004)
K. A. Kistler and S. Matsika, J. Phys. Chem. A, 111, 2650, (2007)
K. A. Kistler and S. Matsika, Photochem. Photobiol.,83, 611, (2007)

27. Three-state intersections in DNA/RNA bases
In pyrimidines:
In purines:
They connect different two-state conical intersections

28. Three-state conical intersections in nucleobases
Three state ci
Three state ci

29. Three-state conical intersections in cytosine
Multiple seams of three-state conical intersections were located for cytosine and 5M2P, an analog with the same pyrimidinone ring. S3 S2 S1 S0
ππ*/nNπ*/nOπ* GS
gs/ππ*/nNπ*
gs/ππ*/nOπ*

30. energy difference gradient vectors
coupling vectors
The branching space for the S1-S2-S3 (*,n*,n*)(ci123) conical intersection.
coupling vectors
energy difference gradient vectors
The branching space for the S1-S2-S3 (*,*,n*)(ci123’) conical intersection
energy difference gradient vectors

31. The three-state ci012 are connected to two state seam paths and finally the Franck Condon region.
K. A. Kistler and S. Matsika, J. Chem. Phys. 128, , (2008)

32. Phase effects and 3-state Conical Intersections
Different pairs of 2-state CIs exist around a 3-state CI. Around a S0/S1/S2 CI there can be S0/S1 and S1/S2 CIs  
Loop
f01
f12
f02
No CI +
One (or odd #) S0/S1
+ One (or odd #) S1/S2 -
Keat and Meating, J. Chem. Phys., 82, 5102, (1985)
Manolopoulos and Child, PRL, 82, 2223, (1999)
Han and Yarkony, J. Chem. Phys., 119, 11561, (2003)
Schuurman and Yarkony J. Chem. Phys., 124, , (2006)

33. We will now explore the phases on loops around the conical intersections that may or may not enclose a second ci
K. A. Kistler and S. Matsika, J. Chem. Phys. 128, , (2008)

34. Derivative coupling:
 constant

35. Plots of the derivative coupling along , f, the magnitude of f, and the energy of states S0, S1, and S2 for a loop around a regular two-state ci away from a three-state ci.
|f20|

36. Energies along four branching plane loops around point D.

37. f01
f12
f02
No CI +
One (or odd #) S0/S1
+ One (or odd #) S1/S2 -
0.07

38. The magnitude of the derivative coupling is shown for four branching plane loops around point D. f10, f20, f21, with respect to  are plotted.
Detail of c) above.

39. QM/MM for solvent effects

40. Including the solvent effects
Basics of QM/MM
M: solvent charges
i: electrons
: nuclei

41. A Hybrid QM/MM approach using ab initio MRCI wavefunctions
Quantum Mechanics:
MCSCF/ MRCISD using COLUMBUS
Molecular Mechanics/Dynamics
TINKER or MOLDY
Coupling between QM-MM regions
Averaged solvent electrostatic potential following the Martin et al. scheme
Martin et al. J. Chem. Phys. 116, (2002), 1613

42. General scheme Solve Schrodinger Eq. HQM=E -> q0
Molecular dynamics -> average potential
(HQM+HQM/MM)=E
Compute energy and solute properties
( excitation energies)

43. Polarization Uncoupled method Polarization of solute:
Do not change the partial charges of the solute during the MD simulation
Polarization of solute:
Partial charges (Mulliken):
MRCI initial: C , O , H
final: , ,
MCSCF initial: , ,
final: , ,
Polarization of the solvent:

44. General scheme Solve Schrodinger Eq. HQM=E -> q0
Molecular dynamics -> average potential
Until convergence
(HQM+HQM/MM)=E -> q
Compute energy and solute properties
( excitation energies)

45. Average electrostatic potential on a grid
f* Rvdw
f=0.8
S0=1.2 Å
S1=1.15 Å
4 shells
624 points S0 S1

46. qi Vj
Grid A: inside the surface to calculate the solvent induced electrostatic potential
Grid B: outside to obtain q
Least squares fitting for q
Error in fitting: 150 cm-1

47. Blueshift (cm-1) in formaldehyde
Exp: ~1700 cm-1
1A2
Exp.: eV
MCSCF: eV
MRCI: eV
MCSCF/PCM
595
CASSCF/ASEP
1470
MRCISD/COSMO
1532
CCSD/MM(TIP3P)
2139
CCSD/MM(SPCpol)
2803
MRSDCI
1500
MCSCF
1580
MRSDCI(no solute pol)
970
CASSCF/MC
CASSCF/MC (pol)
1A1
CAS+MRCI(4,3) /aug-cc-pvtz
Z. Xu and S. Matsika, J. Phys. Chem. A,110, 12035, (2006)

48. Dipole moment shifts Gas phase Solution phase MCSCF MRCI exp
Method
1.66
0.38
MRCISD/COSMO
1.74
0.52
CASSCF/ASEP
2.270
1.305
CC2/MM(TIP3P)
2.306
0.982
CASSCF/MC
2.455
1.490
CC2/MM(SPCpol)
1.95
1.237
CCSD/MM(TIP3P)
2.683
1.420
CCSD/MM(SPCpol)
1.78
0.59
MCSCF/MM
2.597
0.67
MRCISD/MM
/D
/D
Method
2.98
0.54
MRCISD/COSMO
3.00
0.65
CASSCF/ASEP
3.377
1.269
CASSCF/MC
3.442
1.206
CC2/MM(TIP3P)
3.597
1.187
CCSD/MM(TIP3P)
3.662
1.426
CC2/MM(SPCpol)
3.816
1.406
CCSD/MM(SPCpol)
2.91
0.64
MCSCF/MM
3.09
0.68
MRCISD/MM

49. Solvatochromic Shifts in Uracil
6.57
S3(nO’π*)
6.31
5.79
S2(ππ*)
(=6.47 D)
+0.41 (=2.67 D)
Energy (eV)
4.80
S1 (nOπ*) S0
(=4.30 D)
EOM-CCSD/MM: S1: eV, S2: eV (Epifanovsky et al., JPC A, (2008)

50. Solvatochromic shifts in Cytosine
+0.83 (=2.86 D)
5.93
nOp*
(=2.93 D)
5.29
nNp*
pp*
+0.25 (=5.29 D)
Energy/ eV
(=6.14 D)
EOM-CCSD/MM: S1: +0.25eV, S2: +0.57eV (Vallet and Kowalski, JCP,125, )

51. Conclusions
Two- and Three-state conical intersections are ubiquitous in polyatomic molecules.
Multireference configuration interaction electronic structure theory methods can be used to describe these features. Single reference methods are more challenging and varios problems need to be overcome
Three-state conical intersections connect two-state seams
Three-state conical intersections can affect couplings and possibly the dynamics. Phase changes can be used as signature for the presence of these conical intersections.
A QM/MM method using MRCI wavefunctions can describe solvation effects on excited states

52. Acknowledgments Dr. ZongRong Xu Dr. Dimitri Laikov Kurt Kistler
Kandis Gilliard
Madiyha Muhammad
Benjamin Mejia
Elizabeth Mburu
Chris Kozak
Financial support by:
NSF CAREER Award
DOE
Temple University