diff --git a/BSEdyn.tex b/BSEdyn.tex index 471e593..5bba572 100644 --- a/BSEdyn.tex +++ b/BSEdyn.tex @@ -230,7 +230,7 @@ Taking the optical gap (\ie, the lowest optical excitation energy) as an example \end{equation} which is itself a corrected version of the Kohn-Sham (KS) gap \begin{equation} - \Eg^{\KS} = \eps_{\LUMO}^{\KS} - \varepsilon_{\HOMO}^{\KS} \ll \Eg^{\GW} \simeq \EgFun, + \Eg^{\KS} = \eps_{\LUMO}^{\KS} - \varepsilon_{\HOMO}^{\KS} \ll \Eg^{\GW} \approx \EgFun, \end{equation} in order to approximate the optical gap \begin{equation} @@ -637,9 +637,10 @@ All the BSE calculations have been performed with our locally developed $GW$ sof \label{sec:resdis} %%%%%%%%%%%%%%%%%%%%%%%% +%%% TABLE I %%% \begin{table*} \caption{ - Excitation energies (in eV) for various molecules obtained with the aug-cc-pVTZ basis set at various levels of theory. + Singlet excitation energies (in eV) for various molecules obtained with the aug-cc-pVTZ basis set at various levels of theory. The dynamical correction is computed in the TDA. \label{tab:BigTab} } @@ -649,15 +650,12 @@ All the BSE calculations have been performed with our locally developed $GW$ sof \cline{3-7} \cline{8-12} Mol. & State & $\Eg^{\GW}$ & $\Om{m}{\stat}$ & $\Om{m}{\dyn}$ & $\Delta\Om{m}{\dyn}$ & $Z_{m}$ & $\Eg^{\GW}$ & $\Om{m}{\stat}$ & $\Om{m}{\dyn}$ & $\Delta\Om{m}{\dyn}$ & $Z_{m}$ - & CISD(D) & ADC(2) & CCSD & CC2 & CC3 \\ + & CIS(D) & ADC(2) & CCSD & CC2 & CC3 \\ \hline \ce{HCl} & $^1\Pi$(CT) & 13.43 & 8.30 & 8.19 & -0.11 & 1.009 & & & & & & 6.07 & 7.97 & 7.91 & 7.96 & 7.84 \\ \ce{H2O} & $^1B_1(n \ra 3s)$ & 13.58 & 8.09 & 8.00 & -0.09 & 1.007 & & & & & & 7.62 & 7.18 & 7.60 & 7.23 & 7.65 \\ & $^1A_2(n \ra 3p)$ & & 9.79 & 9.72 & -0.07 & 1.005 & & & & & & 9.41 & 8.84 & 9.36 & 8.89 & 9.43 \\ & $^1A_1(n \ra 3s)$ & & 10.42 & 10.35 & -0.07 & 1.006 & & & & & & 9.99 & 9.52 & 9.96 & 9.58 & 10.00 \\ - & $^3B_1(n \ra 3s)$ & & 8.14 & 7.98 & -0.15 & 1.014 & & & & & & 7.25 & 6.86 & 7.20 & 6.91 & 7.28 \\ - & $^3A_2(n \ra 3p)$ & & 9.97 & 9.89 & -0.07 & 1.008 & & & & & & 9.24 & 8.72 & 9.20 & 8.77 & 9.26 \\ - & $^3A_1(n \ra 3s)$ & & 10.28 & 10.13 & -0.15 & 1.012 & & & & & & 9.54 & 9.15 & 9.49 & 9.20 & 9.56 \\ \ce{N2} & $^1\Pi_g(n \ra \pis)$ & 19.20 & 10.11 & 9.66 & -0.45 & 1.029 & & & & & & 9.66 & 9.48 & 9.41 & 9.44 & 9.34 \\ & $^1\Sigma_u^-(\pi \ra \pis)$ & & 10.42 & 9.99 & -0.42 & 1.031 & & & & & & 10.31 & 10.26 & 10.00 & 10.32 & 9.88 \\ & $^1\Delta_u(\pi \ra \pis)$ & & 10.75 & 10.33 & -0.42 & 1.030 & & & & & & 10.85 & 10.79 & 10.44 & 10.86 & 10.29 \\ @@ -665,21 +663,12 @@ All the BSE calculations have been performed with our locally developed $GW$ sof & $^1\Pi_u$(R) & & 13.98 & 13.94 & -0.04 & 1.004 & & & & & & 13.64 & 13.32 & 13.43 & 13.15 & 13.22 \\ & $^1\Sigma_u^+$(R) & & 13.98 & 13.91 & -0.07 & 1.008 & & & & & & 13.75 & 13.07 & 13.26 & 12.89 & 13.12 \\ & $^1\Pi_u$(R) & & 14.24 & 14.21 & -0.03 & 1.002 & & & & & & 14.52 & 14.00 & 13.67 & 13.96 & 13.49 \\ - & $^3\Sigma_u^+(\pi \ra \pis)$ & & 9.50 & 8.46 & -1.04 & 1.060 & & & & & & 8.20 & 8.15 & 7.66 & 8.19 & 7.68 \\ - & $^3\Pi_g(n \ra \pis)$ & & 9.85 & 9.27 & -0.58 & 1.050 & & & & & & 8.33 & 8.20 & 8.09 & 8.19 & 8.04 \\ - & $^3\Delta_u(\pi \ra \pis)$ & & 10.19 & 9.24 & -0.95 & 1.060 & & & & & & 9.30 & 9.25 & 8.91 & 9.30 & 8.87 \\ - & $^3\Sigma_u^-(\pi \ra \pis)$ & & 10.89 & 10.06 & -0.82 & 1.058 & & & & & & 10.29 & 10.23 & 9.83 & 10.29 & 9.68 \\ \ce{CO} & $^1\Pi(n \ra \pis)$ & 16.46 & 9.54 & 9.19 & -0.34 & 1.029 & & & & & & 8.78 & 8.69 & 8.59 & 8.64 & 8.49 \\ & $^1\Sigma^-(\pi \ra \pis)$ & & 10.25 & 9.90 & -0.35 & 1.023 & & & & & & 10.13 & 10.03 & 9.99 & 10.30 & 9.99 \\ & $^1\Delta(\pi \ra \pis)$ & & 10.71 & 10.39 & -0.32 & 1.023 & & & & & & 10.41 & 10.30 & 10.12 & 10.60 & 10.12 \\ & $^1\Sigma^+$(R) & & 11.88 & 11.85 & -0.03 & 1.005 & & & & & & 11.48 & 11.32 & 11.22 & 11.11 & 10.94 \\ & $^1\Sigma^+$(R) & & 12.39 & 12.37 & -0.02 & 1.003 & & & & & & 11.71 & 11.83 & 11.75 & 11.63 & 11.49 \\ & $^1\Pi$(R) & & 12.37 & 12.32 & -0.05 & 1.004 & & & & & & 12.06 & 12.03 & 11.96 & 11.83 & 11.69 \\ - & $^3\Pi(n \ra \pis)$ & & 8.10 & 7.33 & -0.77 & 1.055 & & & & & & 6.51 & 6.45 & 6.36 & 6.42 & 6.30 \\ - & $^3\Sigma^+(\pi \ra \pis)$ & & 9.61 & 9.04 & -0.57 & 1.037 & & & & & & 8.63 & 8.54 & 8.34 & 8.72 & 8.45 \\ - & $^3\Delta(\pi \ra \pis)$ & & 10.20 & 9.69 & -0.50 & 1.036 & & & & & & 9.44 & 9.33 & 9.23 & 9.56 & 9.30 \\ - & $^3\Sigma_u^-(\pi \ra \pis)$ & & 10.79 & 10.38 & -0.42 & 1.034 & & & & & & 10.10 & 10.01 & 9.81 & 10.27 & 9.82 \\ - & $^3\Sigma_u^+$(R) & & 11.48 & 11.38 & -0.10 & 1.010 & & & & & & 10.98 & 10.83 & 10.71 & 10.60 & 10.45 \\ \ce{C2H4} & $^1B_{3u}(\pi \ra 3s)$ & & & & & & & & & & & 7.35 & 7.34 & 7.42 & 7.29 & 7.35 \\ & $^1B_{1u}(\pi \ra \pis)$ & & & & & & & & & & & 7.95 & 7.91 & 8.02 & 7.92 & 7.91 \\ & $^1B_{1g}(\pi \ra 3p)$ & & & & & & & & & & & 8.01 & 7.99 & 8.08 & 7.95 & 8.03 \\ @@ -693,7 +682,41 @@ All the BSE calculations have been performed with our locally developed $GW$ sof & $^1A_2(n \ra 3p)$ & & 8.87 & 8.85 & -0.02 & 1.002 & & & & & & 8.04 & 7.99 & 8.65 & 8.04 & 8.64 \\ & $^1B_1(\si \ra \pis)$ & & 10.18 & 9.77 & -0.42 & 1.032 & & & & & & 9.38 & 9.17 & 9.28 & 9.32 & 9.19 \\ & $^1A_1(\pi \ra \pis)$ & & 10.05 & 9.81 & -0.24 & 1.026 & & & & & & 9.08 & 9.46 & 9.67 & 9.54 & 9.48 \\ - & $^3A_2(n \ra \pis)$ & & 5.53 & 5.05 & -0.47 & 1.049 & & & & & & 3.58 & 3.46 & 3.56 & 3.59 & 3.57 \\ + \end{tabular} + \end{ruledtabular} +\end{table*} + +%%% TABLE II %%% +\begin{table*} + \caption{ + Triplet excitation energies (in eV) for various molecules obtained with the aug-cc-pVTZ basis set at various levels of theory. + The dynamical correction is computed in the TDA. + \label{tab:BigTab} + } + \begin{ruledtabular} + \begin{tabular}{llrrrrrrrrrrrrrrr} + & & \mc{5}{c}{BSE@{\GOWO}@HF} & \mc{5}{c}{BSE@{\evGW}@HF} \\ + \cline{3-7} \cline{8-12} + Mol. & State & $\Eg^{\GW}$ & $\Om{m}{\stat}$ & $\Om{m}{\dyn}$ & $\Delta\Om{m}{\dyn}$ & $Z_{m}$ + & $\Eg^{\GW}$ & $\Om{m}{\stat}$ & $\Om{m}{\dyn}$ & $\Delta\Om{m}{\dyn}$ & $Z_{m}$ + & CIS(D) & ADC(2) & CCSD & CC2 & CC3 \\ + \hline + \ce{H2O} & $^3B_1(n \ra 3s)$ & 13.58 & 8.14 & 7.98 & -0.15 & 1.014 & & & & & & 7.25 & 6.86 & 7.20 & 6.91 & 7.28 \\ + & $^3A_2(n \ra 3p)$ & & 9.97 & 9.89 & -0.07 & 1.008 & & & & & & 9.24 & 8.72 & 9.20 & 8.77 & 9.26 \\ + & $^3A_1(n \ra 3s)$ & & 10.28 & 10.13 & -0.15 & 1.012 & & & & & & 9.54 & 9.15 & 9.49 & 9.20 & 9.56 \\ + \ce{N2} & $^3\Sigma_u^+(\pi \ra \pis)$ & 19.20 & 9.50 & 8.46 & -1.04 & 1.060 & & & & & & 8.20 & 8.15 & 7.66 & 8.19 & 7.68 \\ + & $^3\Pi_g(n \ra \pis)$ & & 9.85 & 9.27 & -0.58 & 1.050 & & & & & & 8.33 & 8.20 & 8.09 & 8.19 & 8.04 \\ + & $^3\Delta_u(\pi \ra \pis)$ & & 10.19 & 9.24 & -0.95 & 1.060 & & & & & & 9.30 & 9.25 & 8.91 & 9.30 & 8.87 \\ + & $^3\Sigma_u^-(\pi \ra \pis)$ & & 10.89 & 10.06 & -0.82 & 1.058 & & & & & & 10.29 & 10.23 & 9.83 & 10.29 & 9.68 \\ + \ce{CO} & $^3\Pi(n \ra \pis)$ & 16.46 & 8.10 & 7.33 & -0.77 & 1.055 & & & & & & 6.51 & 6.45 & 6.36 & 6.42 & 6.30 \\ + & $^3\Sigma^+(\pi \ra \pis)$ & & 9.61 & 9.04 & -0.57 & 1.037 & & & & & & 8.63 & 8.54 & 8.34 & 8.72 & 8.45 \\ + & $^3\Delta(\pi \ra \pis)$ & & 10.20 & 9.69 & -0.50 & 1.036 & & & & & & 9.44 & 9.33 & 9.23 & 9.56 & 9.30 \\ + & $^3\Sigma_u^-(\pi \ra \pis)$ & & 10.79 & 10.38 & -0.42 & 1.034 & & & & & & 10.10 & 10.01 & 9.81 & 10.27 & 9.82 \\ + & $^3\Sigma_u^+$(R) & & 11.48 & 11.38 & -0.10 & 1.010 & & & & & & 10.98 & 10.83 & 10.71 & 10.60 & 10.45 \\ + \ce{C2H4} & $^3B_{1u}(\pi \ra \pis)$ & & & & & & & & & & & 4.62 & 4.59 & 4.46 & 4.59 & 4.53 \\ + & $^3B_{3u}(\pi \ra 3s)$ & & & & & & & & & & & 7.26 & 7.23 & 7.29 & 7.19 & 7.24 \\ + & $^3B_{1g}(\pi \ra 3p)$ & & & & & & & & & & & 7.97 & 7.95 & 8.03 & 7.91 & 7.98 \\ + \ce{CH2O} & $^3A_2(n \ra \pis)$ & 12.00 & 5.53 & 5.05 & -0.47 & 1.049 & & & & & & 3.58 & 3.46 & 3.56 & 3.59 & 3.57 \\ & $^3A_1(\pi \ra \pis)$ & & 8.15 & 7.32 & -0.83 & 1.067 & & & & & & 6.27 & 6.20 & 5.97 & 6.30 & 6.05 \\ & $^3B_2(n \ra 3s)$ & & 7.51 & 7.54 & 0.03 & 0.994 & & & & & & 6.66 & 6.39 & 7.08 & 6.44 & 7.03 \\ & $^3B_2(n \ra 3p)$ & & 8.62 & 8.61 & -0.00 & 0.998 & & & & & & 7.52 & 7.41 & 7.94 & 7.45 & 7.92 \\