Pseudopotentials, an Overlooked Source and Remedy of DFT Errors

Kuiyu Ye; Jiale Shen; Haitao Liu; Yuanchang Li; Shengbai Zhang

doi:10.1021/acs.jctc.5c01373

Pseudopotentials, an Overlooked Source and Remedy of DFT Errors

Kuiyu Ye
, Jiale Shen
, Haitao Liu
, Yuanchang Li
, Shengbai Zhang

Research output: Contribution to journal › Article › peer-review

Abstract

First-principles calculations rely heavily on pseudopotentials, yet their impact on accuracy is hardly addressed. In this work, we show that most pseudopotentials to date introduce errors, which manifest themselves as errors of atomic energy levels, leading to a defacto deviation from the Hohenberg-Kohn theorem. We consider the atomic-level adjusted pseudopotentials, whose interplay with exchange-correlation functional provides a pragmatic correction that balances accuracy and efficiency. We benchmark our theory with bandgap calculation for 54 semiconductors containing monovalent Cu. The results, compared to those from conventional studies, not only remove all erroneous metal predictions for 11 compounds, but also reduce the mean relative error from 80% to 20%. Overall accuracy even exceeds those of standard hybrid functionals and GW methods.

Original language	English
Pages (from-to)	12254-12261
Number of pages	8
Journal	Journal of Chemical Theory and Computation
Volume	21
Issue number	23
DOIs	https://doi.org/10.1021/acs.jctc.5c01373
Publication status	Published - 9 Dec 2025
Externally published	Yes

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10.1021/acs.jctc.5c01373

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title = "Pseudopotentials, an Overlooked Source and Remedy of DFT Errors",

abstract = "First-principles calculations rely heavily on pseudopotentials, yet their impact on accuracy is hardly addressed. In this work, we show that most pseudopotentials to date introduce errors, which manifest themselves as errors of atomic energy levels, leading to a defacto deviation from the Hohenberg-Kohn theorem. We consider the atomic-level adjusted pseudopotentials, whose interplay with exchange-correlation functional provides a pragmatic correction that balances accuracy and efficiency. We benchmark our theory with bandgap calculation for 54 semiconductors containing monovalent Cu. The results, compared to those from conventional studies, not only remove all erroneous metal predictions for 11 compounds, but also reduce the mean relative error from 80\% to 20\%. Overall accuracy even exceeds those of standard hybrid functionals and GW methods.",

author = "Kuiyu Ye and Jiale Shen and Haitao Liu and Yuanchang Li and Shengbai Zhang",

year = "2025",

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doi = "10.1021/acs.jctc.5c01373",

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T1 - Pseudopotentials, an Overlooked Source and Remedy of DFT Errors

AU - Ye, Kuiyu

AU - Shen, Jiale

AU - Liu, Haitao

AU - Li, Yuanchang

AU - Zhang, Shengbai

PY - 2025/12/9

Y1 - 2025/12/9

N2 - First-principles calculations rely heavily on pseudopotentials, yet their impact on accuracy is hardly addressed. In this work, we show that most pseudopotentials to date introduce errors, which manifest themselves as errors of atomic energy levels, leading to a defacto deviation from the Hohenberg-Kohn theorem. We consider the atomic-level adjusted pseudopotentials, whose interplay with exchange-correlation functional provides a pragmatic correction that balances accuracy and efficiency. We benchmark our theory with bandgap calculation for 54 semiconductors containing monovalent Cu. The results, compared to those from conventional studies, not only remove all erroneous metal predictions for 11 compounds, but also reduce the mean relative error from 80% to 20%. Overall accuracy even exceeds those of standard hybrid functionals and GW methods.

AB - First-principles calculations rely heavily on pseudopotentials, yet their impact on accuracy is hardly addressed. In this work, we show that most pseudopotentials to date introduce errors, which manifest themselves as errors of atomic energy levels, leading to a defacto deviation from the Hohenberg-Kohn theorem. We consider the atomic-level adjusted pseudopotentials, whose interplay with exchange-correlation functional provides a pragmatic correction that balances accuracy and efficiency. We benchmark our theory with bandgap calculation for 54 semiconductors containing monovalent Cu. The results, compared to those from conventional studies, not only remove all erroneous metal predictions for 11 compounds, but also reduce the mean relative error from 80% to 20%. Overall accuracy even exceeds those of standard hybrid functionals and GW methods.

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EP - 12261

JO - Journal of Chemical Theory and Computation

JF - Journal of Chemical Theory and Computation

IS - 23

ER -

Pseudopotentials, an Overlooked Source and Remedy of DFT Errors

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