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The investigation of spectroscopic information is important for understanding the mechanisms of molecular photochemical and photophysical reactions. As a prototype to study the electronic structures and spectra of diatomic molecular systems, the vibration-rotational spectra of alkali dimer and its ions have aroused considerable research interest in the last two decades. Single-reference and multi-reference coupled cluster theory in combination with correlation consistent Gaussian basis set are adopted to study the ground-state potential energy curves of 7Li 2 (0,± 1)molecular systems. The correlation effect and relativistic effect of all the electrons are taken into account in the calculation. And the spectroscopic constants, including the equilibrium internuclear distance R e, the harmonic vibrational frequency ω e, the anharmonic constant ω e x e, the equilibrium rotational constant B e, and the dissociation energy D eof the molecular system and vibration-rotational energy level information of the ground states are obtained by solving the radial Schrödinger equations. The calculated spectroscopic constants of the neutral and positive ion system accord well with the experimental values; however for the negative ion system, the calculation of equilibrium internuclear distance needs further improving, and other spectroscopic constants are consistent well with the experimental values. The present computational results indicate that the ground state wave functions of neutral and positive ion systems have obvious single reference configuration characteristics, while the ground state of negative ion molecule system should be described with multireference configuration wave functions. The vibration-rotational energy levels of ground state with different theoretical methods are in good agreement with the experimental values. The vibrational-rotational energy levels and spectroscopic constants of neutral and positive ion systems are well reproduced, and some experimental information about spectrum is still lacking. Although the difference among the equilibrium internuclear distances for the ground state of the negative ion, obtained from different theoretical methods are still existent, the results of the vibrational level interval accord well with each other. This study provides useful information about spectrum for accurately investigating the electronic structures and spectra of the ground state of Li 2molecular system and its two isotopic molecules, especially for the negative ion system with little information about spectrum.
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Keywords:
- Li2molecule/molecular ion/
- multi-reference coupled cluster theory/
- spectroscopic constant/
- vibration-rotational energy level
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Method Re/Å ωe/cm–1 ωexe/cm–1 Be/cm–1 De/eV vCCSD(T)/TZa 2.6992 346.3556 2.6687 0.6596 1.038 CCSD(T)/TZ 2.6770 350.5609 2.7163 0.6706 1.046 CCSD(T)/QZ 2.6742 351.7784 2.7238 0.6720 1.052 CCSD(T)/5Z 2.6734 352.0222 2.7285 0.6724 1.053 实验b 2.6734 351.42295 2.4417 0.66824 1.060 注:a未包含1s轨道电子关联;b激光诱导荧光傅里叶变换谱(LIF FTS)实验PKR拟合值[2,6]. Vibrational levels 本次结果 理论a 实验b 0 0 0 0 1 346.17 346.05 346.46 2 687.11 686.65 687.86 3 1022.78 1021.71 1024.08 4 1353.13 1351.15 1355.01 5 1678.11 1674.88 1680.54 6 1997.67 1992.81 2000.56 7 2311.72 2304.85 2314.95 8 2620.21 2610.92 2623.58 9 2923.03 2910.90 2926.35 10 3220.09 3204.70 3223.11 11 3511.29 3492.23 3513.74 12 3796.49 3773.36 3798.10 13 4075.58 4048.00 4076.05 14 4348.39 4316.02 4347.45 15 4614.78 4577.31 4612.16 16 4874.55 4831.74 4870.02 17 5127.52 5079.52 5120.86 18 5373.46 5319.52 5364.53 19 5612.14 5552.59 5600.84 20 5843.27 5778.25 5829.63 21 6066.57 5996.35 6050.69 22 6281.67 6206.72 6263.83 23 6488.16 6409.20 6468.84 24 6685.58 6603.59 6665.49 RMS 8.68(0.16%) 33.93(0.65%) — 注:aFCIPP计算值[3],bLIF FTS实验值[2,6]. v Bv/cm–1 Dv/10-4cm–1 Expt.[2,6] This work Expt.[2,6] This work 0 0.66907 0.66882 — 0.0987 1 0.66196 0.66171 — 0.0991 2 0.65479 0.65453 — 0.0996 3 0.64754 0.64728 — 0.1002 4 0.64019 0.63995 — 0.1007 5 0.63275 0.63252 — 0.1014 6 0.62521 0.62499 — 0.1021 7 0.61754 0.61733 — 0.1028 8 0.60974 0.60954 — 0.1037 9 0.60180 0.60160 — 0.1046 10 0.59368 0.59348 — 0.1056 11 0.58540 0.58518 — 0.1068 12 0.57692 0.57667 — 0.1080 13 0.56822 0.56793 — 0.1093 14 0.55918 0.55892 0.1097 0.1108 15 0.55000 0.54961 0.1119 0.1123 16 0.54055 0.53995 0.1143 0.1138 17 0.53061 0.52990 0.1146 0.1152 18 0.52044 0.51939 0.1180 0.1165 19 0.50992 0.50834 0.1215 0.1175 20 0.49885 0.49667 0.1246 0.1181 21 0.48726 0.48429 0.1265 0.1185 22 0.47845 0.47109 0.1182 0.1187 23 0.46246 0.45698 0.1340 0.1190 24 0.44913 0.44183 0.1401 0.1200 Species Method Re/Å ωe/cm–1 ωexe/cm–1 Be/cm–1 De/eV Li2+ 本次结果a 3.0986 262.7599 1.5640 0.5005 1.297 本次结果a2 3.1337 258.8211 1.5413 0.4893 1.279 本次结果a3 3.1038 262.3548 1.5669 0.4988 1.294 MPb 3.122 263.08 1.2954 0.4945 1.2976 CIc 3.099 263.76 — 0.5006 1.2945 DMCd 3.11 266.2 1.593 0.4753 1.2965 实验[5,7] 3.11 262 ± 2 1.7 ± 0.5 0.496 ± 0.002 1.2973 Li2- 本次结果a 3.0265 230.6457 1.5881 0.5247 0.850 本次结果a3 3.0396 231.1024 2.3115 0.5201 0.845 DMCd 3.10 235.3 3.166 0.4652 0.7733 MRDCIe 3.062 236.2 2.42 — 0.857 CCSD(T)f 3.00 240.7 3.166 0.5238 0.9085 实验[10] 3.094 ± 0.015 232 ± 35 — 0.502 ± 0.005 0.865 ± 0.022(D0) 注:aRCCSD(T)/5Z;a2vMRCCSD/TZ + 4s2p(未包含1s的电子关联);a3MRCCSD/TZ + 4s2p(包含1s的电子关联);bmodel potential (MP) method[25];cconfiguration interaction (CI) with effective core potential[4];ddiffusion quantum Monte-Carlo (DMC) method[12];emultireference singly and doubly CI (MRDCI)[11];fCCSD(T, full)/cc-pv5z[12]. v Li2+ Li2– 理论a 理论b 理论c 本次结果 理论c 本次结果 0 259.51 260 259.74 259.74 227.53 228.64 1 256.30 257 256.54 256.54 222.71 223.96 2 253.11 254 253.35 253.35 217.93 219.69 3 249.95 251 250.19 250.19 213.21 216.12 4 246.81 248 247.04 247.04 208.54 213.32 5 243.68 244 243.92 243.92 203.95 211.08 6 240.57 241 240.81 240.81 199.42 208.91 7 237.49 236 237.72 237.72 194.97 206.46 8 234.41 235 234.65 234.65 190.61 203.52 9 231.35 232 231.59 231.59 186.34 200.06 10 228.31 228 228.55 228.55 182.16 196.15 11 225.28 226 225.51 225.51 178.08 191.88 12 222.26 222 222.50 222.50 174.12 187.33 13 219.24 220 219.48 219.48 170.26 182.59 14 216.24 216 216.48 216.48 166.53 177.72 15 213.24 214 213.48 213.48 162.92 172.77 16 210.25 210 210.50 210.50 159.45 167.78 17 207.26 207 207.50 207.50 156.11 162.77 18 204.28 205 204.53 204.53 152.91 157.79 19 201.30 201 201.55 201.55 149.87 152.82 注:aCCSD(T, FULL)/aug-cc-Pcvqz[12];bMP[25];cDMC[12]. v Bv/cm–1 Dv/10-4cm–1 Li2+ Li2– Li2+ Li2- 0 0.49776 0.52021 0.07223 0.10558 1 0.49235 0.51129 0.07168 0.10438 2 0.48698 0.50214 0.07114 0.10106 3 0.48164 0.49226 0.07062 0.09317 4 0.47635 0.48106 0.07011 0.07966 5 0.47109 0.46824 0.06961 0.06296 6 0.46586 0.45407 0.06912 0.04741 7 0.46067 0.43920 0.06865 0.03586 8 0.45551 0.42426 0.06819 0.02862 9 0.45037 0.40969 0.06775 0.02462 10 0.44527 0.39571 0.06732 0.02265 11 0.44019 0.38238 0.06690 0.02180 12 0.43513 0.36971 0.06649 0.02155 13 0.43009 0.35766 0.06611 0.02159 14 0.42507 0.34617 0.06573 0.02177 15 0.42007 0.33520 0.06537 0.02201 16 0.41508 0.32469 0.06503 0.02226 17 0.41010 0.31461 0.06470 0.02252 18 0.40514 0.30492 0.06439 0.02276 19 0.40018 0.29558 0.06410 0.02300 20 0.39522 0.28656 0.06382 0.02324 21 0.39026 0.27784 0.06356 0.02347 22 0.38531 0.26939 0.06332 0.02370 23 0.38035 0.26120 0.06310 0.02392 24 0.37538 0.25324 0.06290 0.02416 v G(v)/cm–1 Bv/cm–1 Dv/10-4cm–1 6Li7Li 6Li2 6Li7Li 6Li2 6Li7Li 6Li2 0 0 0 0.72431 0.77978 0.1158 0.13429 1 360 373 0.71629 0.77082 0.11635 0.13495 2 714 741 0.70819 0.76176 0.11695 0.13568 3 1063 1102 0.70001 0.75260 0.11761 0.13647 4 1406 1457 0.69173 0.74333 0.11832 0.13735 5 1743 1805 0.68333 0.73392 0.11911 0.13832 6 2074 2148 0.67480 0.72436 0.11999 0.13939 7 2400 2484 0.66613 0.71462 0.12095 0.14058 8 2719 2813 0.65729 0.70469 0.12201 0.14189 9 3032 3135 0.64827 0.69453 0.12318 0.14335 10 3338 3451 0.63904 0.68412 0.12448 0.14496 11 3639 3760 0.62958 0.67343 0.12591 0.14673 12 3932 4062 0.61986 0.66242 0.12747 0.14863 13 4219 4356 0.60984 0.65104 0.12913 0.15062 14 4500 4643 0.59949 0.63924 0.13088 0.15262 15 4773 4922 0.58875 0.62695 0.13262 0.1545 16 5038 5193 0.57756 0.61407 0.13426 0.1561 17 5297 5456 0.56584 0.60052 0.13567 0.15725 18 5547 5710 0.55352 0.58617 0.13671 0.15786 19 5789 5956 0.54048 0.57089 0.13733 0.15794 20 6023 6192 0.52662 0.55456 0.13755 0.15775 21 6249 6418 0.51182 0.53703 0.13757 0.15778 22 6465 6633 0.49596 0.51815 0.1378 0.15879 23 6671 6838 0.47890 0.49776 0.13886 0.16187 24 6866 7031 0.46051 0.47564 0.14162 0.16834 -
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