No Correlated Electron Left Behind Sarom Sok April 29 , 2011
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No Correlated Electron Left Behind Electronic Structure Policies for the Common Chemist and Condensed Matter Physicist Sarom Sok April 29th, 2011 From the Killing Fields to the Self‐Consistent Field: The Adventures of a Cambodian Refugee in Quantum Chemistry • • • • General Introduction Hydrolysis of 1‐substituted Silatranes Solvent‐induced shift of p‐nitroaniline Benchmarking time‐dependent density functionals • The combined coupled‐cluster/effective fragment potential approach • Conclusions From the Killing Fields to the Self‐Consistent Field: The Adventures of a Cambodian Refugee in Quantum Chemistry • • • • General Introduction Hydrolysis of 1‐substituted Silatranes Solvent‐induced shift of p‐nitroaniline Benchmarking time‐dependent density functionals • The combined coupled‐cluster/effective fragment potential approach • Conclusions Introduction Time‐Independent Schrödinger Equation (TISE) Ĥ Ψ = E Ψ Electronic TISE within the Born‐Oppenheimer Approx. Hˆ elec Ψ elec = Eelec Ψ elec Electronic Hamiltonian Hˆ elec ∇i2 N M Z A 1 = −∑ − ∑∑ +∑ i =1 2 i =1 A=1 riA i < j rij N = ∑ h ( i ) + Vee i Introduction Electronic Hamiltonian ‐ Independent Particle Model Hˆ elec = ∑ h ( i ) i Hartree‐Fock Method • Independent Particle Model • Variational Principle • Slater Determinants Electron (i) feels an averaged repulsion field Hˆ HF = ∑ h ( i ) + ∑ VHF ( i ) i i Introduction Hartree‐Fock Method (Independent Particle Model) • Neglects instantaneous repulsion of electrons (too close) • Motion of electrons are uncorrelated Ecorrelation = Ψ HF | Hˆ HF | Ψ HF − Eexact Why is it important • Liquefaction of noble gases • According to Hartree‐Fock, the F2 molecule does not exist • Interaction of biologically important molecules Formal Scaling CBS Limit* Not Graduating O(n8) O(n7) O(n6) O(n5) O(n4) EHF Eexact Increase in Correlation Energy/Accuracy Problem: Electrons get too close in Hartree‐Fock method. Placing electrons in spatially different one‐electron functions (excitations into unoccupied orbitals). *complete basis set limit EFull CI Formal Scaling CBS Limit* Not Graduating O(n8) O(n7) O(n6) O(n5) O(n4) EHF Eexact Increase in Correlation Energy/Accuracy Full Configuration Interaction (CI) occ virt occ virt Ψ CI = Φ ref + ∑∑ Cia Φ ia + ∑∑ Cijab Φ ijab + i i < j a <b a single excitation *complete basis set limit double excitation occ virt ∑ ∑ i < j < k a <b < c triple excitation Bartlett, R. J.; Stanton, J. F. Rev. Comp. Chem. 1994, 5, 65 abc Cijkabc Φ ijk + ... N‐tuple excitation EFull CI Formal Scaling CBS Limit* Not Graduating O(n8) O(n7) O(n6) O(n5) O(n4) ECISD EHF Eexact Increase in Correlation Energy/Accuracy CI with Singles and Doubles Excitations (CISD) occ virt occ virt Ψ CI = Φ ref + ∑∑ Cia Φ ia + ∑∑ Cijab Φ ijab i *complete basis set limit a i < j a <b Bartlett, R. J.; Stanton, J. F. Rev. Comp. Chem. 1994, 5, 65 EFull CI Formal Scaling CBS Limit* Not Graduating O(n8) O(n7) O(n6) O(n5) O(n4) ECISD EMP2 EHF Eexact Increase in Correlation Energy/Accuracy Møller‐Plesset Second‐Order Perturbation Theory E *complete basis set limit ( 2) ⎡⎣( ij | ab ) − ( ia | jb ) ⎤⎦ = ∑∑ εi + ε j − ε a − εb i < j a <b occ virt Bartlett, R. J.; Stanton, J. F. Rev. Comp. Chem. 1994, 5, 65 2 EFull CI Formal Scaling CBS Limit* Not Graduating O(n8) O(n7) O(n6) O(n5) O(n4) ECCSD(T) ECISD ECCSD EMP2 EHF Eexact Increase in Correlation Energy/Accuracy Coupled‐Cluster Theory ( ) 1 ˆ2 1 ˆ3 ⎛ ⎞ ˆ ˆ Ψ CC = exp T Φ ref = ⎜1 + T + T + T + ... ⎟ Φ ref 2! 3! ⎝ ⎠ Tˆ = Tˆ + Tˆ + ... + Tˆ Includes contributions from 1 TˆN Φ ref = *complete basis set limit N 2 occ virt ∑ ∑ i < j < k <… a <b < c <… t abc… ijk… Φ abc… ijk… higher‐order disconnected excitations. T12T2, T22, T14 appears in CCSD. Bartlett, R. J.; Stanton, J. F. Rev. Comp. Chem. 1994, 5, 65 EFull CI Formal Scaling CBS Limit* Not Graduating O(n8) O(n7) O(n6) O(n5) O(n4) ECCSD(T) ECISD ECCSD EMP2 EHF Eexact Increase in Correlation Energy/Accuracy Density Functional Theory Hˆ DFT = ∑ h ( i ) + ∑ VHartree ( i ) + cHFexchange ∑ VExchange ( i ) + ∑ Vxc ( i ) i i i i δ Exc Vxc ( r ) = ; Exc = ∫ f ( ρα , ρ β , γ αα , γ αβ , γ ββ ,τ α ,τ β ) dr δρ ( r ) *complete basis set limit Summary • Electron correlation is important • Different approaches to account for electron correlation CAN WE CORRELATE ELECTRONS? Summary • Electron correlation is important • Different approaches to account for electron correlation CAN WE CORRELATE ELECTRONS? YES, WE CAN. Solvent‐induced shift of the lowest singlet π→π* charge‐transfer excited state of p‐nitroaniline Background • p‐nitroaniline – Prototypical donor‐π‐acceptor chromophore – Two mesomeric structures – Strong solvent‐dependent π→π* absorption band in near UV‐Vis region • Charge transfer from amino to nitro group across phenyl ring – Benchmark solvent models Neutral Zwitterionic Purpose • Test the performance and applicability of the combined time‐dependent density functional theory/effective fragment potential (TDDFT/EFP1) method TDDFT/EFP1 Time‐dependent Density Functional Theory ⎡A B ⎤ ⎡X ⎤ ⎡ 1 0 ⎤ ⎡ X ⎤ V ⎡ ρ ⎤ ( r, t ) ≈ V ⎡ ρ ⎤ ( r ) xc ⎣ ⎦ xc ⎣ t ⎦ ⎢ ⎥⎢ ⎥ = ω⎢ ⎥⎢ ⎥ ⎢ B A ⎥ ⎢Y ⎥ ⎢ 0 −1 ⎥ ⎢ Y ⎥ Adiabatic Approximation ⎢ ⎥ ⎣ ⎦ ⎣⎢ ⎦⎥ ⎣⎢ ⎦⎥ ⎣ ⎦ Use ground‐state density functionals Effective Fragment Potential Method (EFP1) Einteraction = ECoulomb + Epolarization + Eremainder H system = H abinitio + Vinteraction region EFP EFP region ab initio region Computational Details • Gas phase: B3LYP/DH(d,p) – Optimized and characterized • Condensed phase: B3LYP/DH(d,p) – NVT simulation with 150 EFP waters at 300K using Nosé‐Hoover thermostat • 20 ps equilibration followed by 20 ps production run • 2000 configurations sampled • Excitation energies: TD‐B3LYP/DH(d,p) TD‐B3LYP/EFP1 Simulated π→π* Excited‐State Spectrum for pNA in Water 0.75 0.50 0.25 0.00 4.25 Calculated gas‐phase excitation energy Normalized Intensity 1.00 4.00 HOMO π 3.75 LUMO π* 3.50 Vertical Excitation Energy (eV) 3.25 3.00 pNA + 150 EFP Waters Varying the Density Functional TDDFT/EFP1/DH(d,p)//B3LYP/EFP1/DH(d,p) eV Exptl.a, b, c TD‐ B3LYP TD‐ PBE0 TD‐ CAM CIS(D)d Gas phase 4.24 3.97 4.11 4.40 4.65 Condensed phase 3.26 3.37 3.44 3.50 3.65 ‐0.98 ‐0.60 ‐0.67 ‐0.90 ‐1.00 0.60 0.22 0.22 0.20 0.46 Solvent Shift π→π* Shift (condensed – gas) Line Width (FWHM) a Millefiori et al. Spectrochim. Acta 1977, 33A, 21‐27 b Thomsen et al. J. Phys. Chem. A 1998, 102, 1062‐1067 c Kovalenko et al. Chem. Phys. Lett. 2000, 323, 312‐322 d Kosenkov, D.; Slipchenko, L. V. J. Phys. Chem. A. 2011, 115, 392‐401 pNA + 150 EFP Waters The Bulk! Are We There Yet? TDDFT/EFP1/DH(d,p)//B3LYP/EFP1/DH(d,p) TDDFT/EFP1‐CPCM/DH(d,p)//B3LYP/EFP1/DH(d,p) eV Exptl.a, b, c TD‐ B3LYP TD‐ B3LYP TD‐ PBE0 TD‐ CAM TD‐ CAM CIS(D)d Gas phase 4.24 3.97 3.97 4.11 4.40 4.40 4.65 Condensed phase 3.26 3.37 3.37 3.44 3.50 3.51 3.65 ‐0.98 ‐0.60 ‐0.60 ‐0.67 ‐0.90 ‐0.89 ‐1.00 Solvent Shift π→π* Shift (condensed – gas) a Millefiori et al. Spectrochim. Acta 1977, 33A, 21‐27 b Thomsen et al. J. Phys. Chem. A 1998, 102, 1062‐1067 c Kovalenko et al. Chem. Phys. Lett. 2000, 323, 312‐322 d Kosenkov, D.; Slipchenko, L. V. J. Phys. Chem. A. 2011, 115, 392‐401 Increase in Zwitterionic Character pNA (electrons) q(N9) q(H10) q(H11) q (N14) q(O15) q(O16) Dipole (Debye) Gas phase ‐0.64 0.32 0.32 0.58 ‐0.40 ‐0.40 7.6 Condensed phase ‐1.02 0.54 0.54 0.65 ‐0.56 ‐0.56 16.2 Structural Parameter (angs. and degs.) Exptl.1 MP22 B3LYP/ B3LYP EFP1 R(C2‐C1) 1.41 1.41 1.42 1.43 R(C3‐C2) 1.37 1.39 1.39 1.38 R(C4‐C3) 1.39 1.40 1.40 1.42 R(C1‐N9) 1.35 1.38 1.36 1.35 R(C4‐N14) 1.45 1.47 1.46 1.41 R(N14‐O15) 1.23 1.25 1.24 1.26 θ(C2C1N9H10) 19.9 10.0 θ(C5C4N14O15) 0.0 7.9 Neutral Zwitterionic Solvent‐Shift Contributions TDDFT/EFP1/DH(d,p) (eV) Contribution TD‐B3LYP TD‐CAM‐B3LYP Solute Relaxation ‐0.09 ‐0.12 ‐0.22 Coulomb ‐0.41 ‐0.42 ‐0.39 Polarization ‐0.07 ‐0.10 ‐0.26 Remainder ‐0.03 ‐0.03 ‐0.03 Total ‐0.60 ‐0.67 ‐0.90 0.0 TD‐B3LYP -0.2 Energy (eV) TD‐PBE0 -0.4 -0.6 -0.8 -1.0 Solute Relaxation Coulomb Polarization Remainder Total Shift -0.09 eV -0.41 eV -0.07 eV -0.03 eV -0.60 eV Solute relaxation and polarization are sensitive to the choice of density functional Performance of TDDFT/EFP1 Single MD Snapshot TD‐B3LYP/DH(d,p) 150 DFT Waters 150 EFP1 Waters 3.33 3.49 Total Time (minutes) 25783.6 7.6 Total Memory 19.8 GB 0.06 GB π→π* (eV) Summary • TD‐B3LYP/EFP1 – Reproduces the experimental red shift and – Within ~ 0.1 eV of the experimental condense phase value for the π→π* excitation energy • Solvent shift values and contributions (solute relaxation/polarization) are density functional sensitive • Increase in zwitterionic character of the ground‐ state upon solvation • Largest contribution to the solvent shift is from Coulomb interactions Benchmarking the performance of time‐dependent density functionals Excitation Types Excited T0 Tv Te vertical adiabatic Te with ZPE corrections Ground Benchmarking the Calculation of Vertical Excitations Excited T0 Tv Te vertical adiabatic Te with ZPE corrections Ground Time‐Dependent Kohn‐Sham Equations Adiabatic Approximation ⎡ 1 2 ⎤ ∂ K K K i ϕi ( r , t ) = ⎢ − ∇ + VTDDFT ( r , t ) ⎥ ϕi ( r , t ) ⎢⎣ 2 ⎥⎦ ∂t K ρ (r ,t ) K K K VTDDFT ( r , t ) = v ( t ) + ∫ K K dr ' + vXC [ρ ]( r , t ) r −r ' δE XC ⎡⎣ ρt ⎤⎦ K K ⎡ ⎤ vXC ( r , t ) ≈ K = vXC ⎣ ρt ⎦ ( r ) δρ ( r ) t Adiabatic Approximation Uses the density and density functional from the ground‐state Linear Response TDDFT Time domain K δρ ( r , t ) Fourier Transform Frequency domain K δρ ( r , ω ) ⎡A B⎤ ⎡X⎤ ⎡1 0 ⎤ ⎡X⎤ ⎢ ⎥⎢ ⎥ = ω⎢ ⎥⎢ ⎥ ⎢ B A⎥ ⎢Y⎥ ⎢ 0 −1 ⎥ ⎢ Y ⎥ ⎢⎣ ⎥⎦ ⎢⎣ ⎥⎦ ⎢⎣ ⎥⎦ ⎢⎣ ⎥⎦ Linear Response TDDFT • • • Excitation energies are determined as poles of the response function Non‐Hermitian eigenvalue problem Requires second functional derivative with respect to the electron density (non‐trivial for certain functional types) Linear Response TD‐DFT Classification of Density Functionals Classification Density Functional Dependence Local Density Approximation (LDA) f ( ρα , ρ β ) Generalized Gradient Approximation (GGA) f ( ρα , ρ β , γ αα , γ αβ , γ ββ ) f ( ρα , ρ β , γ αα , γ αβ , γ ββ ,τ α ,τ β ) meta‐Generalized Gradient Approximation (mGGA) Classification Amount of Hartree‐Fock Exchange Pure none Global Hybrid (GH) constant (all range) Range Separated Hybrid (RSH) varies (short‐ vs. long‐ range) Purpose • Study the performance of different time‐ dependent density functionals for the calculation of singlet, triplet, valence (π→π*, n→π*, n→σ*, σ→π*), and Rydberg vertically excited states • Offer recommendations for density functional usage for vertical excited‐estate calculations using time‐dependent density functional theory within the adiabatic approximation Computational Details • Ground state – Optimized and characterized using the 6‐31++G(3df,3dp) basis set and the respective functional used for vertical excited state calculations • Excited states – Vertical excitations performed on ground‐state optimized geometries using the same basis set and functional • Estimator of Performance – Mean Signed Error (MSE) – Mean Absolute Error (MAE) – Root Mean Square Error (RMS) Benchmark Set • 14 small‐ to medium‐size compounds with 101 total experimental excited state energies – 101 excited states can be broken down into: • 63 singlets and 38 triplets states or • 60 valence and 41 Rydberg states – 60 valence states can be broken down into: • 30 π→π*, 26 n→π*, 3 n→σ*, 1 σ→π* benzene, butadiene, cyclopentadiene, ethylene, formaldehyde, furan, methylenecyclopropene, pyrazine, pyridine, pyrrole, s‐tetrazine, s‐trans acrolein, s‐trans glyoxal, water Benchmarked Density Functionals Functional Year SVWN BLYP PW91 PBE OLYP BHHLYP B3LYP PBE0 X3LYP CAM‐B3LYP 1980 1988 1992 1997 2001 1993 1994 1997 2004 2004 Type LDA GGA GGA GGA GGA GH‐GGA GH‐GGA GH‐GGA GH‐GGA RSH %HF 50 20 25 21.8 19 – 65 Functional Year VS98 PKZB TPSS M06‐L TPSSm revTPSS TPSSh M05 M05‐2X M06 M06‐2X M06‐HF M08‐HX M08‐SO 1998 1999 2004 2006 2007 2009 2004 2005 2006 2006 2006 2006 2008 2008 Type %HF mGGA mGGA mGGA mGGA mGGA mGGA GH‐mGGA GH‐mGGA GH‐mGGA GH‐mGGA GH‐mGGA GH‐mGGA GH‐mGGA GH‐mGGA 10 28 56 27 54 100 52.23 56.79 Convergence Issues Excited State Type Count non‐mGGA mGGA Singlet 63 35 Triplet 38 25 Excited State Type Count non‐mGGA mGGA Valence 60 28 Rydberg 40 32 Valence Excited State Type Count non‐mGGA mGGA π→π* 30 12 n→π* 26 16 n→σ* 3 0 σ→π* 1 0 Performance for Singlet and Triplet Exchange-Correlation (XC) Functional Triplet Total Singlet Total Total M08-SO M08-HX M06-HF M06-2X M06 M05-2X M05 TPSSh revTPSS TPSSm M06-L TPSS PKZB VS98 CAMB3LYP X3LYP PBE0 B3LYP BHHLYP OLYP PBE PW91 BLYP SVWN GH-mGGA mGGA RSH GH-GGA GGA LDA 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 Mean Absolute Error (eV) Singlets LDA, GGA, GH‐GGA • PBE0 (0.25 eV) • CAM (0.28 eV) • OLYP (0.89 eV) mGGA, GH‐GGA • M06‐2X (0.21 eV) • M06 (0.81 eV) Triplets LDA, GGA, GH‐GGA • B3LYP, X3LYP, PBE0 (0.32 eV) • CAM (1.10 eV) mGGA, GH‐GGA • M06‐2X (0.24 eV) • PKZB (0.57 eV) SVWN better than GGA for singlets and triplets! Performance for Valence and Rydberg Exchange-Correlation (XC) Functional Rydberg Total Valence Total Total M08-SO M08-HX M06-HF M06-2X M06 M05-2X M05 TPSSh revTPSS TPSSm M06-L TPSS PKZB VS98 CAMB3LYP X3LYP PBE0 B3LYP BHHLYP OLYP PBE PW91 BLYP SVWN Valence LDA, GGA, GH‐GGA • B3LYP, X3LYP, PBE0 GH-mGGA (< 0.30 eV) • CAM (0.84 eV) mGGA, GH‐GGA • M06 (0.25 eV) • M06‐HF (0.48 eV) mGGA • M06‐L (0.29 eV) Rydberg LDA, GGA, GH‐GGA RSH • CAM (0.22 eV) GH-GGA • PBE0 & BHHLYP (0.25 eV) mGGA, GH‐GGA GGA • M06‐2X (0.17 eV) • M06 (1.08 eV) LDA SVWN better than GGA 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 for Rydberg! Mean Absolute Error (eV) Performance for π→π* and n→π* Exchange-Correlation (XC) Functional Valence n-π* Valence π-π* Valence Total M08-SO M08-HX M06-HF M06-2X M06 M05-2X M05 TPSSh revTPSS TPSSm M06-L TPSS PKZB VS98 CAMB3LYP X3LYP PBE0 B3LYP BHHLYP OLYP PBE PW91 BLYP SVWN GH-mGGA mGGA RSH GH-GGA GGA LDA 0.0 0.1 0.2 0.3 0.4 0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2 1.3 1.4 1.5 Mean Absolute Error (eV) n→π* LDA, GGA, GH‐GGA • All GH‐GGAs (0.25 – 0.32 eV) • CAM (0.56 eV) mGGA, GH‐GGA • M06 (0.22 eV) • M06‐HF (0.58 eV) π→π* LDA, GGA, GH‐GGA • All LDA, GGA, GH‐GGA (0.27 – 0.36 eV) • CAM (1.14 eV) mGGA, GH‐GGA • M06‐L (0.25 eV) • M05 (0.50 eV) Summary Excited State Type Best non‐mGGA (MAE eV) Best mGGA (MAE eV) Singlet PBE0 , CAM (<0.28) M06‐2X (0.21) Triplet PBE0, B3LYP, X3LYP (<0.32) M06‐2X (0.24) Valence PBE0, B3LYP, X3LYP (<0.30) M06‐L, M06, M06‐2X (<0.30) Rydberg PBE0, BHHLYP, CAM (<0.25) M06‐2X (0.17) π→π* X3LYP, B3LYP (<0.27) M06‐L (0.25) n→π* PBE, B3LYP, X3LYP (0.28) M06 (0.22) PBE0 (0.28) M06‐2X (0.22) Overall • • • • • • SVWN does better than all GGAs overall DO NOT RECOMMEND any GGAs For pure density functionals use SVWN (0.54) or M06‐L (0.39) For GH‐GGAs use PBE0 For GH‐mGGAs use M06‐2X Avoid using CAM‐B3LYP for triplets The combined coupled‐ cluster/effective fragment potential approach Background • A majority of interesting chemical and all biological processes do not take place in a vacuum. • Such processes often occur in solution, on surfaces, and at active sites of biochemical systems. • Use of high level ab initio electronic structure methods is computationally prohibitive for large systems. Effective Fragment Potential (EFP) • A discrete approach to treating environmental effects. EFP • Effect of fragment molecules region contribute to the one‐electron ab initio region terms in ab initio Hamiltonian. H system = H abinitio + Vinteraction region Effective Fragment Potential Effective Fragment Potential (EFP1) Einteraction =ECoulomb + Epolarization + Eexchange repulsion/charge transfer Vinteraction = K L k =1 l =1 Elec Pol V μ , s + V ( ) ∑ k ∑ l ( μ, s ) + Distributed Multipolar expansion LMO polarizability expansion Jensen, J.H.; Gordon, M.S. Mol. Phys. 1996 , 89, 1313 Day, P.N.; Jensen, J.H.; Gordon, M.S.; Webb, S.P.; Stevens, W.J.; Krauss, M.; Garmer, D.; Basch, H.; Cohen, D. J. Chem. Phys. 1996, 105, 1968 Adamovic, I.; Freitag M.A.; Gordon, M.S. J. Chem. Phys. 2003 ,118, 6725 M Rep V ∑ m ( μ, s ) m =1 Fit to Functional Form Effective Fragment Potential (EFP1) • Interfaced with several ab initio methods – – – – – – – a Hartree‐Fock Theory (HF)a Density Functional Theory (DFT)b Second‐Order Møller‐Plesset Perturbation Theory (MP2)c Multi‐Configurational Self‐Consistent Field Theory (MCSCF)d Single Excited Configuration Interaction (CIS)e Time‐Dependent Density Functional Theory (TD‐DFT)f Multi‐Reference Perturbation Theory (MRPT)g Day, P.N.; Jensen, J.H.; Gordon, M.S.; Webb, S.P.; Stevens, W.J.; Krauss, M.; Garmer, D.; Basch, H.; Cohen, D. J. Chem. Phys. 1996, 105, 1968 b Adamovic, I.; Freitag M.A.; Gordon, M.S. J. Chem. Phys. 2003 ,118, 6725 c Song, J.; Gordon, M.S.; Unpublished work. d Krauss, M.; Webb, S. P. J. Chem. Phys. 1997, 107, 5771 e Arora, P.; Gordon, M.S. J. Chem. Phys. A. 2010, 114, 6742‐6750. f Yoo, S.; Zahariev, F.; Sok, S.; Gordon, M.S. J. Chem. Phys. 2008, 129, 144112 g DeFusco, A.; Gordon, M.S. J. Phys. Chem. A. 2011, ASAP, April 14, 2011. Coupled‐Cluster Theory (CC) The solution of the electronic Schrödinger equation, Ĥ Ψ = E Ψ is approximated by, Tˆ Ψ ≈ Ψ CC = e Φ ref leading to, Tˆ Tˆ ˆ He Φ ref = E e Φ ref J. Čížek J. Chem. Phys.; 1966, 45, 4256 J. Čížek Adv. Chem. Phys.; 1969, 14, 35 J. Čížek J. Paldus Int. J. Quant. Chem.; 1971, 5, 359 Crawford, T. D.; Schaefer III, H. F. Rev. in Comp. Chem.; 2000, 14, 33 Formal Scaling of CC Methods CCSD N6 CCSD(T) N7 CR‐CC(2,3) N7 EOM‐CCSD N6 EOM‐CCSD(T) N8 CC/EFP1 • Perform coupled‐cluster calculation using a HF/EFP1 reference wavefunction, ˆ ˆ Ψ CC = eT Φ ref = eT Φ HF/EFP1 • This can be extended to the excited‐state using equation of motion coupled‐cluster†, ˆ Tˆ Φ Ψ EOM-CC = Rˆ Ψ CC = Re HF/EFP1 1 abc… ˆ ˆ ˆ ˆ ˆ R = R0 + R1 + R2 + … , Rn Ψ = ∑ rijkabc…… Ψ ijk … n! †Stanton, J. F.; Bartlett, R. J. J. Chem. Phys. 1993, 98, 7029 and references therein Application of CC/EFP1 NO3‐ (H2O)15 Solvation • Nitrates – Most abundant naturally occurring ion in our environment (sea salt aerosols in troposphere) – Photochemistry (Surface vs. interior)a • MD simulations with Polarizable Force Field Methods: cross over from surface to interior 300 – 500 waters • QM/MM (MP2/EFP) Monte Carlo/Simulated Annealing: cross over from surface to interior ≈ 32 waters • MP2/DH(d,p) optimized geometries at 32 waters show E(interior) – E(surface) = 0.5 kcal/mol a Miller, Y.; Thomas, J. L.; Kemp, D. D.; Finlayson‐Pitts, B. J.; Gordon, M. S.; Tobias, D. J.; Gerber, R. B. J. Phys. Chem. A. 2009, 113, 12805‐12814 Computational Details NO3‐ (H2O)15 Solvation • Lowest surface and interior structures – MP2/EFP1/DH(d,p) Monte Carlo/Simulated Annealing simulations • CCSD(T)/EFP1/6‐31+G(d) single‐point energy – Calculation: 26 minutes on 1 cpu w/ 6.3 GB memory • Compare with fully ab initio calculations CCSD(T)/6‐31+G(d) – EFP1 waters are converted to ab initio waters – Calculation: 2 days on 72 cpus w/ 52.5 GB dist. mem. NO3‐ Solvation 15 Waters Surface A 0 (0) [0] 15 Waters Surface B 0.3 (1.6) [‐1.3] CCSD(T)‐EFP1/6‐31+G(d)//MP2‐EFP1/DH(d,p) (CCSD(T)/6‐31+G(d)//MP2‐EFP1/DH(d,p)) [Difference: EFP – Full ab initio] 15 Waters Interior 6.7 (1.0) [ 5.6] Computational Details π→π* Solvent‐Shift of pNA • Condensed phase: B3LYP/DH(d,p) – NVT simulation with 150 EFP waters at 300K using Nosé‐Hoover thermostat • 20 ps equilibration followed by 20 ps production run • Excitation Energies – EOM‐CCSD/EFP1/DH(d,p) – EOM‐CCSD/EFP1/6‐31+G(d) π→π* Solvent Shift of p‐nitroaniline Excitation Energy (eV) Method‐EFP1/Basis Set//B3LYP‐EFP1/DH(d,p) EOM‐CCSD/ DH(d,p) EOM‐CCSD/ 6‐31+G(d) CIS(D)/ 6‐31+G(d)a Gas 4.24 3.97 4.73 4.57 4.65 Condensed 3.26 3.37 3.45 3.41 3.65 ‐0.98 ‐0.60 ‐1.28 ‐1.16 ‐1.00 0.60 0.22 0.26 0.27 0.46 π→π* Shift Line Width (FWHM) a Kosenkov, D.; Slipchenko, L. V. J. Phys. Chem. A. 2011, 115, 392‐401 Millefiori et al. Spectrochim. Acta 1977, 33A, 21‐27 c Thomsen et al. J. Phys. Chem. A 1998, 102, 1062‐1067 d Kovalenko et al. Chem. Phys. Lett. 2000, 323, 312‐322 b Normalized Intensity Exptl.b, c, d TD‐B3LYP/ DH(d,p) 1.0 EOM‐CCSD/DH(d,p) Condensed‐phase 0.8 Spectrum of π→π* state of pNA 0.6 0.4 0.2 0.0 4.2 4.0 3.8 3.6 3.4 3.2 Vertical Excitation Energy (eV) 3.0 Summary • Nitrate solvation – Largest error is on the order of 5 kcal/mol – Delocalized system may be difficult to treat with the CC/EFP1 method • pNA solvent shift – Calculated shift is less than 0.18 eV from experimental shift • The CC/EFP1 method offers a significant step towards a full treatment of solvent effects with CC theory Acknowledgements • • • • • • • • • Iowa State University ‐Summer REU w/ Kai‐Ming Ho Mark Gordon – exp ( thanks ) = 1 + thanks + 1 thanks 2 + 1 thanks3 + ... 2! 3! Mike Schmidt – GAMESS and coding Dr. Federico Zahariev – all things dealing with ρ ( r ) D. Soohaeng Yoo –MD simulations and TDDFT/EFP1 Dr. Albert Defusco – EFP energy decomposition Dr. Lyudmila Slipchenko – CC/EFP1 Dr. Tony Smith and Dr. Luke Roskop Leo C. DeSesso; personal attorney Acknowledgements It takes a village research group to raise a child scientist kidult. [Ancient] [Older] [Old] [Current] [REU @ISU] ; Equations: Time‐Independent Schrödinger Ĥ Ψ = E Ψ Hˆ = Tˆe + Tˆn + Vˆen + Vˆee + Vˆnn 2 2 M N M N M ∇ Z Z AZB ∇ 1 i A A ˆ H =∑ −∑ − ∑∑ +∑ +∑ i =1 2 A =1 2 M A i =1 A=1 riA i < j rij A< B rAB N Hˆ elec Ψ elec = Eelec Ψ elec Hˆ elec within the Born‐Oppenheimer Approximation N M ∇ ZA 1 = −∑ − ∑∑ +∑ i =1 2 i =1 A =1 riA i < j rij N 2 i E = Eelec + Enucl Equations: Independent Particle Model (IPM) Hˆ IPM Ψ IPM = EIPM Ψ IPM N Hˆ IPM = ∑ h ( i ) i N Ψ IPM = ∏ φi i N EIPM = ∑ ε i i =1 h ( i ) φi = ε iφi Equations: Basis Set φi = basis functions ∑ α cα i χ i Linear Combination of Atomic Orbitals (LCAO) Used in this talk: DH(d,p) 6‐31G(d) 6‐31+G(d) 6‐31++G(d) 6‐311++G(3df,3pd) EFP Equations and Density Matrix E = E + ∑ Pμ ,ν Vμν + VN ( efp ) μ ,ν Vμν = ∫ dr1φμ (1) V * ( efp ) VN = ∑ Z AV ( efp ) ( efp ) (1) φν (1) ( A) A V ( efp ) K = ∑V k Elec k L M (1) + ∑ Vl (1) + ∑ V (1) l Pol m Rep m Line Width w/ EFP Fragments w/ EFP Fragments Removed Difference • Rotation about –NO2 group during solvation in the ground state contributes to redshift. Farztdinov, V. M.; Schanz, R.; Kovalenko, S. A.; Ernsting, N. P.; J. Phys. Chem. A; 2000, 104, 11486
