AI Article Synopsis
- Predicting accurate bond-length alternations (BLAs) in long conjugated molecular chains has been a longstanding issue in electronic-structure theory, with traditional methods like Hartree-Fock and DFT showing significant limitations.
- The research identifies the many-electron self-interaction error (MSIE) as a key factor affecting the accuracy of these methods, but merely minimizing MSIE does not guarantee correct BLA predictions.
- Tuning the range-separation parameter for better BLA estimates can lead to increased MSIE as the molecular chain lengthens, highlighting that addressing MSIE is important but not sufficient for obtaining accurate BLAs.
Article Abstract
Predicting accurate bond-length alternations (BLAs) in long conjugated molecular chains has been a major challenge for electronic-structure theory for many decades. While Hartree-Fock (HF) overestimates BLA significantly, second-order perturbation theory and commonly used density functional theory (DFT) approaches typically underestimate it. Here, we discuss how this failure is related to the many-electron self-interaction error (MSIE), which is inherent to both HF and DFT approaches. We use tuned long-range corrected hybrids to minimize the MSIE for a series of polyenes. The key result is that the minimization of the MSIE alone does not yield accurate BLAs. On the other hand, if the range-separation parameter is tuned to yield accurate BLAs, we obtain a significant MSIE that grows with chain length. Our findings demonstrate that reducing the MSIE is one but not the only important aspect necessary to obtain accurate BLAs from density functional theory.
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| http://dx.doi.org/10.1063/1.4752431 | DOI Listing |
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