1. Exact factorization of the time-dependent electron- nuclear wave function: A fresh look on potential energy surfaces and Berry phases Co-workers: Ali Abedi (MPI-Halle) Neepa Maitra (CUNY) Nikitas Gidopoulos (Rutherford Lab)

2. with Full Schrödinger equation: convention: Greek indices  nuclei Latin indices  electrons Hamiltonian for the complete system of N e electrons with coordinates and N n nuclei with coordinates, masses M 1 ··· M N n and charges Z 1 ··· Z N n.

3. Born-Oppenheimer approximation for each fixed nuclear configuration solve Make adiabatic ansatz for the complete molecular wave function: and find best χ BO by minimizing w.r.t. χ BO :

4. Nuclear equation Berry connection is a geometric phase In this context, potential energy surfaces and the Berry potential are APPROXIMATE concepts, i.e. they follow from the BO approximation.

5. Nuclear equation Berry connection is a geometric phase In this context, potential energy surfaces and the Berry potential are APPROXIMATE concepts, i.e. they follow from the BO approximation. “Berry phases arise when the world is approximately separated into a system and its environment.”

6. GOING BEYOND BORN-OPPENHEIMER Standard procedure: and insert expansion in the full Schrödinger equation → standard non-adiabatic coupling terms from T n acting on χ J,K depends on 2 indices: → looses nice interpretation as “nuclear wave function” In systems driven by a strong laser, hundreds of BO-PES can be coupled. Drawbacks: Expand full molecular wave function in complete set of BO states:

7. Potential energy surfaces are absolutely essential in our understanding of a molecule.... and can be measured by femto-second pump-probe spectroscopy: Zewail, J. Phys. Chem. 104, 5660, (2000)

8. fs laser pulse (the pump pulse) creates a wavepacket, i.e., a rather localised object in space which then spreads out while moving.

9. The NaI system (fruit fly of femtosecond spectroscopy) The potential energy curves: The ground, X-state is ionic in character with a deep minimum and 1/R potential leading to ionic fragments: R The first excited state is a weakly bound covalent state with a shallow minimum and atomic fragments. Na + I Na + + I - PE R

10. The non-crossing rule “Avoided crossing” Na + + I - Na + I ionic covalent ionic

11. NaI femtochemistry The wavepacket is launched on the repulsive wall of the excited surface. As it keeps moving on this surface it encounters the avoided crossing at 6.93 Ǻ. At this point some molecules will dissociate into Na + I, and some will keep oscillating on the upper adiabatic surface.

12. Na + + I - Na + I The wavepacket continues sloshing about on the excited surface with a small fraction leaking out each time the avoided crossing is encountered.

13. I.Probing Na atom products: Steps in the production of Na as more of the wavepacket leaks out each vibration into the Na + I channel. Each step smaller than last (because fewer molecules left)

14. Effect of tuning pump wavelength (exciting to different points on excited surface) 300 311 321 339 λ pump /nm Different periods indicative of anharmonic potential T.S. Rose, M.J. Rosker, A. Zewail, JCP 91, 7415 (1989)

15. GOAL: Show that can be made EXACT Concept of EXACT potential energy surfaces (beyond BO) Concept of EXACT Berry connection (beyond BO) Concept of EXACT time-dependent potential energy surfaces for systems exposed to electro-magnetic fields Concept of ECACT time-dependent Berry connection for systems exposed to electro-magnetic fields

16. Theorem I The exact solutions of can be written in the form where for each fixed First mentioned in: G. Hunter, Int. J.Q.C. 9, 237 (1975)

17. Immediate consequences of Theorem I: 1.The diagonal of the nuclear N n -body density matrix is identical with  in this sense, can be interpreted as a proper nuclear wavefunction. proof: 1 2. and are unique up to within the “gauge transformation”

18. proof:Let and be two different representations of an exact eigenfunction  i.e. 11

19. Eq.  Eq.  where Theorem II: satisfy the following equations: G. Hunter, Int. J. Quant. Chem. 9, 237 (1975). N.I. Gidopoulos, E.K.U.G. arXiv: cond-mat/0502433

20. Eq.  and  are form-invariant under the “gauge” transformation is a (gauge-invariant) geometric phase the exact geometric phase Exact potential energy surface is gauge invariant. OBSERVATIONS: Eq.  is a nonlinear equation in Eq.  contains  selfconsistent solution of  and  required Neglecting the terms in , BO is recovered There is an alternative, equally exact, representation (electrons move on the nuclear energy surface)

21. Proof of Theorem I: Choose: with some real-valued funcion Given the exact electron-nuclear wavefuncion Then, by construction,

22. Proof of theorem II (basic idea) first step: Find the variationally best and by minimizing the total energy under the subsidiary condition that. This gives two Euler equations: Eq.  Eq.  prove the implication ,  satisfy Eqs. ,    :=  satisfies H  =E  second step:

23. How do the exact PES look like?

24. + + -5 Å+5 Å 0 Å x y R + –– (1)(2) MODEL (S. Shin, H. Metiu, JCP 102, 9285 (1995), JPC 100, 7867 (1996)) Nuclei (1) and (2) are heavy: Their positions are fixed

27. Exact Berry connection Insert: with the exact nuclear current density J ν

28. Eqs. ,  simplify:   Consider special cases where is real-valued (e.g. non-degenerate ground state  DFT formulation)

29. Density functional theory beyond BO What are the “right” densities? first attempt A HK theorem is easily demonstrated (Parr et al). This, however, is NOT useful (though correct) because, for one has: easily verified using n = constant N = constant

30. next attempt NO GOOD, because spherical for ALL systems Useful densities are: (diagonal of nuclear DM) is a conditional probability density Note: is the density that has always been used in the DFT within BO

31. now use decomposition then 1 (like in B.O.) HK theorem

32. KS equations nuclear equation stays the same Electronic equation: Electronic and nuclear equation to be solved self-consistently using:

33. Time-dependent case

34. Time-dependent Schrödinger equation with Hamiltonian for the complete system of N e electrons with coordinates and N n nuclei with coordinates, masses M 1 ··· M N n and charges Z 1 ··· Z N n.

35. Theorem T-I The exact solution of can be written in the form where for any fixed. A. Abedi, N.T. Maitra, E.K.U.G., PRL 105, 123002 (2010)

36. Eq.  Eq.  Theorem T-II satisfy the following equations A. Abedi, N.T. Maitra, E.K.U.G., PRL 105, 123002 (2010)

37. EXACT time-dependent potential energy surface EXACT time-dependent Berry connection

38. Example: H 2 + in 1D in strong laser field exact solution of Compare with: Hartree approximation: Standard Ehrenfest dynamics “Exact Ehrenfest dynamics” where the forces on the nuclei are calculated from the exact TD-PES Ψ(r,R,t) = χ(R,t) ·φ(r,t)

39. The internuclear separation (t) for the intensities I 1 = 10 14 W/cm 2 (left) and I 2 = 2.5 x 10 13 W/cm 2 (right)

40. Dashed: I 1 = 10 14 W/cm 2 ; solid: I 2 = 2.5 x 10 13 W/cm 2 Exact time-dependent PES

41. Summary: is an exact representation of the complete electron-nuclear wavefunction if χ and Φ satisfy the right equations Eqs. ,  provide the proper definition of the --- exact potential energy surface --- exact Berry connection both in the static and the time-dependent case Multi-component (TD)DFT framework TD-PES useful to interpret different dissociation meachanisms (namely Eqs. ,  )