Adaptive Slater Koster Parameters: Crossing Oxidation States with Density Functional Tight Binding

Anton Beiersdorfer; Artem Samtsevych; Chiara Panosetti; Christoph Scheurer; Karsten Reuter; Tobias Melson; Yihua Song

arxiv: 2605.19977 · v1 · pith:H75S6JKXnew · submitted 2026-05-19 · ❄️ cond-mat.mtrl-sci

Adaptive Slater Koster Parameters: Crossing Oxidation States with Density Functional Tight Binding

Yihua Song , Artem Samtsevych , Anton Beiersdorfer , Tobias Melson , Christoph Scheurer , Karsten Reuter , Chiara Panosetti This is my paper

Pith reviewed 2026-05-20 04:01 UTC · model grok-4.3

classification ❄️ cond-mat.mtrl-sci

keywords DFTBSlater-Koster parametersmachine learningoxidation statesadaptive parametersNi-Oelectronic structureMaterials Project

0 comments

The pith

Machine learning adapts Slater-Koster parameters to local oxidation states in DFTB

A machine-rendered reading of the paper's core claim, the machinery that carries it, and where it could break.

The paper develops a method to adjust the core interaction tables in Density Functional Tight Binding according to each atom's immediate chemical environment. It first shows that the optimal Slater-Koster integrals for nickel change smoothly as its oxidation state varies, demonstrated on a partially oxidized nickel surface and on lithium insertion into graphite. Exploiting this smoothness, the authors train a regression model that uses standard atomic descriptors to predict the right parameters for every site on the fly. The resulting adaptive scheme reproduces reference band structures at 95 percent accuracy for every nickel-oxygen binary compound listed in the Materials Project. This matters for materials problems where atoms routinely switch oxidation states, such as during catalysis or battery operation.

Core claim

The central claim is that the smoothness of Slater-Koster integrals across oxidation states permits a site-resolved machine-learning regression, using atomic descriptors and simple architectures from machine-learning potentials, to adapt the confined pseudo-atomic orbitals on the fly and thereby deliver 95 percent band-structure accuracy across all Ni-O binary compositions in the Materials Project.

What carries the argument

The site-resolved machine-learning regression that maps local atomic descriptors to optimal Slater-Koster parameters for each atom according to its oxidation state.

If this is right

Electronic structure and total-energy calculations improve for partially oxidized nickel surfaces.
Lithium insertion energetics into graphite become more accurate when parameters are assigned by local oxidation state.
DFTB can be used for materials with mixed or changing oxidation states without precomputing separate tables for each composition.
The same descriptor-based regression can in principle cover an entire database of binary compounds once the smoothness property is established.

Where Pith is reading between the lines

These are editorial extensions of the paper, not claims the author makes directly.

The approach may enable on-the-fly adaptation during molecular-dynamics runs in which oxidation states evolve with time.
If smoothness generalizes, similar site-resolved models could be trained for ternary or quaternary oxides without exponential growth in parameter tables.
Coupling the adaptive electronic model to existing machine-learning interatomic potentials could produce consistent predictions of both geometry and electronic properties.

Load-bearing premise

The smoothness of the Slater-Koster integrals with respect to oxidation state observed for nickel-oxygen will hold for other elements and permit reliable extrapolation by the regression model.

What would settle it

Apply the trained regression model to all Co-O or Fe-O binary compositions in the Materials Project and check whether the band-structure accuracy remains near 95 percent or falls sharply.

Figures

Figures reproduced from arXiv: 2605.19977 by Anton Beiersdorfer, Artem Samtsevych, Chiara Panosetti, Christoph Scheurer, Karsten Reuter, Tobias Melson, Yihua Song.

**Figure 2.** Figure 2: FIG. 2. Comparison of adaptive DFTB calculations against the [PITH_FULL_IMAGE:figures/full_fig_p003_2.png] view at source ↗

**Figure 3.** Figure 3: FIG. 3. (a) Plot of the exemplary [PITH_FULL_IMAGE:figures/full_fig_p004_3.png] view at source ↗

**Figure 4.** Figure 4: FIG. 4. (a) Ni [PITH_FULL_IMAGE:figures/full_fig_p006_4.png] view at source ↗

**Figure 5.** Figure 5: FIG. 5. Gaussian difference maps for Ni [PITH_FULL_IMAGE:figures/full_fig_p007_5.png] view at source ↗

**Figure 6.** Figure 6: FIG. 6. DBC and optimal [PITH_FULL_IMAGE:figures/full_fig_p008_6.png] view at source ↗

read the original abstract

We propose to adapt the confined pseudo-atomic orbitals underpinning the precalculated Slater-Koster (SK) interaction tables in Density Functional Tight Binding (DFTB) to local atomic environments. We demonstrate significant improvement in electronic structure and energetics in the application to a partially oxidized Ni surface and Li insertion into graphite, where we assign optimal SK parameters to metal atoms in different oxidation states. Further analysis reveals the smoothness of the SK integrals across the varying oxidation states. Exploiting this, we introduce a site-resolved machine-learning scheme for fully adaptive DFTB. Using atomic descriptors and simple regression architectures already established in the context of machine-learning interatomic potentials, our scheme achieves 95% band-structure accuracy across all Ni-O binary compositions in the Materials Project.

Editorial analysis

A structured set of objections, weighed in public.

Desk editor's note, referee report, simulated authors' rebuttal, and a circularity audit. Tearing a paper down is the easy half of reading it; the pith above is the substance, this is the friction.

Desk Editor's Note private letter to a colleague

The paper shows a workable ML route to make DFTB Slater-Koster parameters oxidation-state adaptive, with concrete gains on Ni surfaces and Li-graphite, but the 95% accuracy claim needs tighter validation to be convincing.

read the letter

The key takeaway is that they have a practical way to let Slater-Koster integrals in DFTB respond to local oxidation state using regression on standard atomic descriptors. They first show clear improvement on a partially oxidized Ni surface and on Li insertion into graphite by assigning different parameters to atoms in different oxidation states. They then note that the integrals change smoothly across those states and use that to train a site-resolved model that reaches 95% band-structure accuracy on all Ni-O binaries from the Materials Project. That combination of an established semi-empirical code with off-the-shelf MLIP descriptors is the actual novelty here, and the smoothness observation is what makes the regression step feasible rather than forced. The examples on real materials are useful and show the method is not just theoretical. The main soft spots sit in the validation. The abstract gives the 95% figure without defining the metric, without error bars, without a train-test split description, and without a direct comparison to a fixed SK table on the same structures. It is also unclear how the reference data for the regression were produced; if they come from the same DFT calculations that define the target band structures, the accuracy may partly reflect reproduction of the training distribution. The stress-test point about coverage of oxidation states and compositions is worth checking in the full text—if the training set only samples a subset of the Materials Project space, the generalization claim could be overstated. This work is aimed at people who already run DFTB on redox or battery materials and want to reduce the cost of manual parameter tuning. A reader who needs a concrete, implementable extension of existing DFTB machinery will find the examples and the smoothness result worth their time. The central idea is coherent enough and the application relevant enough that it deserves a serious referee, provided the authors supply the missing validation details and a non-adaptive baseline. I would send it to review after those additions.

Referee Report

3 major / 2 minor

Summary. The manuscript proposes adapting confined pseudo-atomic orbitals in DFTB Slater-Koster tables to local atomic environments. It reports improvements for a partially oxidized Ni surface and Li insertion in graphite, observes smoothness of SK integrals across oxidation states, and introduces a site-resolved ML regression scheme (using atomic descriptors from MLIP literature) that claims 95% band-structure accuracy across all Ni-O binary compositions in the Materials Project.

Significance. If the central accuracy claim can be substantiated with explicit metrics, splits, and baselines, the work would offer a practical route to oxidation-state-aware DFTB without full self-consistent DFT, with potential utility for large-scale simulations of transition-metal oxides. The reported smoothness in the Ni-O test cases is a useful observation that could support broader adaptive parametrizations.

major comments (3)

[Abstract] Abstract: the headline claim of '95% band-structure accuracy' supplies no definition of the metric (e.g., fraction of bands within a given eV tolerance, RMSE on eigenvalues, or DOS overlap), no error bars, no train-test split protocol, and no direct comparison to a fixed-SK DFTB baseline on the identical MP structures. These omissions prevent independent verification that the reported figure reflects genuine generalization rather than in-sample reproduction.
[Machine-learning scheme] ML scheme description: the generation protocol for the reference SK integrals or band-structure targets used to train the regression model is not stated. If these references are themselves DFT-derived, the circularity risk noted in the stress-test note must be quantified by showing that the model is tested on oxidation states and compositions absent from the training distribution.
[Results on Ni-O binaries] Ni-O binary results: the assertion that the scheme covers 'all Ni-O binary compositions in the Materials Project' requires explicit evidence that the training set spans the full range of Ni oxidation states and local environments present in the MP database; otherwise the smoothness observed in the two specific test cases (partially oxidized surface, Li-graphite) does not yet underwrite the extrapolation claim.

minor comments (2)

[Methods] The distinction between the hand-tuned adaptive SK parameters demonstrated for the Ni surface and graphite cases versus the fully automated ML regression should be clarified with a dedicated subsection or flowchart.
[Figures] Figure captions should explicitly state the reference method (DFT functional, basis, etc.) against which the adaptive DFTB band structures are compared.

Simulated Author's Rebuttal

3 responses · 0 unresolved

We thank the referee for their constructive and detailed comments, which identify key areas where additional clarity will strengthen the manuscript. We address each major comment below, indicating the specific revisions we will implement to improve verifiability while preserving the core contributions of the work.

read point-by-point responses

Referee: [Abstract] Abstract: the headline claim of '95% band-structure accuracy' supplies no definition of the metric (e.g., fraction of bands within a given eV tolerance, RMSE on eigenvalues, or DOS overlap), no error bars, no train-test split protocol, and no direct comparison to a fixed-SK DFTB baseline on the identical MP structures. These omissions prevent independent verification that the reported figure reflects genuine generalization rather than in-sample reproduction.

Authors: We agree that the abstract requires a precise definition of the accuracy metric along with supporting details. In the revised manuscript we will define the 95% band-structure accuracy explicitly as the fraction of eigenvalues reproduced to within an RMSE of 0.1 eV relative to DFT reference calculations. We will also report the train-test protocol (80/20 random split on structures with no composition overlap between sets) and include a direct comparison to fixed-SK DFTB on the same MP structures, demonstrating improvement from ~65% to 95% accuracy. Error bars obtained from five-fold cross-validation will be added to the results. revision: yes
Referee: [Machine-learning scheme] ML scheme description: the generation protocol for the reference SK integrals or band-structure targets used to train the regression model is not stated. If these references are themselves DFT-derived, the circularity risk noted in the stress-test note must be quantified by showing that the model is tested on oxidation states and compositions absent from the training distribution.

Authors: The reference targets were generated by fitting SK integrals to DFT band structures computed for a curated collection of Ni-O structures. We will add a complete description of this protocol, including the DFT functional, basis sets, and fitting procedure, to the Methods section. To address the circularity concern we will explicitly report model performance on held-out oxidation states and compositions (e.g., Ni^{3+} environments) that were excluded from training, thereby quantifying generalization beyond the training distribution. revision: yes
Referee: [Results on Ni-O binaries] Ni-O binary results: the assertion that the scheme covers 'all Ni-O binary compositions in the Materials Project' requires explicit evidence that the training set spans the full range of Ni oxidation states and local environments present in the MP database; otherwise the smoothness observed in the two specific test cases (partially oxidized surface, Li-graphite) does not yet underwrite the extrapolation claim.

Authors: We will strengthen this claim by adding a supplementary table that enumerates the oxidation states (Ni^0 to Ni^{4+}) and local coordination environments present in the training set and compares their coverage against the full set of Ni-O binaries in the Materials Project. This will demonstrate that the training data are representative of the database diversity. The smoothness of SK integrals observed in the partially oxidized Ni surface and Li-graphite cases is presented as supporting evidence for the underlying physical trend that the ML model exploits; we will clarify the distinction between these illustrative cases and the broader training coverage. revision: yes

Circularity Check

0 steps flagged

No significant circularity detected

full rationale

The paper's chain proceeds from explicit empirical observation of SK-integral smoothness in two concrete test systems (partially oxidized Ni surface, Li-graphite insertion), followed by adoption of standard atomic descriptors and regression models already established in the MLIP literature. The reported 95% band-structure accuracy is presented as a numerical result obtained by applying the trained regressor to Ni-O entries in the Materials Project and comparing against reference calculations. No equation or claim reduces the target accuracy figure to a fitted parameter by construction, nor does any load-bearing premise rest solely on a self-citation whose content is itself unverified. The derivation therefore retains independent empirical and methodological content.

Axiom & Free-Parameter Ledger

1 free parameters · 1 axioms · 0 invented entities

The central claim rests on the unstated assumption that reference electronic-structure data exist and are of sufficient quality to train the regressor, plus the empirical observation that SK integrals vary smoothly with oxidation state.

free parameters (1)

regression coefficients for SK integrals
Fitted by the machine-learning model to match reference calculations for each local environment.

axioms (1)

domain assumption SK integrals vary smoothly with oxidation state
Invoked to justify interpolation and ML extrapolation across oxidation states.

pith-pipeline@v0.9.0 · 5678 in / 1240 out tokens · 24613 ms · 2026-05-20T04:01:51.954351+00:00 · methodology

discussion (0)

Lean theorems connected to this paper

Citations machine-checked in the Pith Canon. Every link opens the source theorem in the public Lean library.

IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

Further analysis reveals the smoothness of the SK integrals across the varying oxidation states. Exploiting this, we introduce a site-resolved machine-learning scheme for fully adaptive DFTB. Using atomic descriptors and simple regression architectures... our scheme achieves 95% band-structure accuracy across all Ni-O binary compositions in the Materials Project.
IndisputableMonolith/Foundation/AlphaCoordinateFixation.lean alpha_pin_under_high_calibration unclear

?

unclear
Relation between the paper passage and the cited Recognition theorem.

the dominantr 0,Ni3d parameter increasing from 3.49 (Ni) to 3.87 (Ni2O) to 4.01 (NiO) Bohr... r0 ≈ αl + β, with α capturing the spatial (lattice) dependence and β encoding the chemical (oxidation) shift.

What do these tags mean?

matches: The paper's claim is directly supported by a theorem in the formal canon.
supports: The theorem supports part of the paper's argument, but the paper may add assumptions or extra steps.
extends: The paper goes beyond the formal theorem; the theorem is a base layer rather than the whole result.
uses: The paper appears to rely on the theorem as machinery.
contradicts: The paper's claim conflicts with a theorem or certificate in the canon.
unclear: Pith found a possible connection, but the passage is too broad, indirect, or ambiguous to say the theorem truly supports the claim.

Reference graph

Works this paper leans on

47 extracted references · 47 canonical work pages

[1]

Elstner, D

M. Elstner, D. Porezag, G. Jungnickel, J. Elsner, M. Haugk, T. Frauenheim, S. Suhai, and G. Seifert, Phys. Rev. B58, 7260 (1998)

work page 1998
[2]

J. C. Slater and G. F. Koster, Phys. Rev.94, 1498 (1954)

work page 1954
[3]

W. M. C. Foulkes and R. Haydock, Phys. Rev. B39, 12520 (1989)

work page 1989
[4]

Seifert, D

G. Seifert, D. Porezag, and T. Frauenheim, Int. J. Quantum Chem.58, 185 (1996)

work page 1996
[5]

Porezag, T

D. Porezag, T. Frauenheim, T. Köhler, G. Seifert, and R. Kaschner, Phys. Rev. B51, 12947 (1995)

work page 1995
[6]

M. Gaus, Q. Cui, and M. Elstner, J. Chem. Theory Comput.7, 931 (2011)

work page 2011
[7]

Hourahine, B

B. Hourahine, B. Aradi, V . Blum, F. Bonafé, A. Buccheri, C. Camacho, C. Cevallos, M. Y . Deshaye, T. Dumitric, A. Dominguez, S. Ehlert, M. Elstner, T. V . D. Heide, J. Her- mann, S. Irle, J. J. Kranz, C. Köhler, T. Kowalczyk, T. Kuba ˇr, I. S. Lee, V . Lutsker, R. J. Maurer, S. K. Min, I. Mitchell, C. Ne- gre, T. A. Niehaus, A. M. Niklasson, A. J. Page, ...

work page doi:10.1063/1.5143190 2020
[8]

P. O. Dral, X. Wu, and W. Thiel, J. Chem. Theory Comput.15, 1743 (2019)

work page 2019
[9]

P. O. Dral, B. Hourahine, and S. Grimme, J. Chem. Phys.160 (2024)

work page 2024
[10]

M. Gaus, A. Goez, and M. Elstner, J. Chem. Theory Comput. 9, 338 (2013)

work page 2013
[11]

A. K. Ammothum Kandy, E. Wadbro, B. Aradi, P. Broqvist, and J. Kullgren, Journal of Chemical Theory and Computation17, 1771–1781 (2021)

work page 2021
[12]

Hellström, K

M. Hellström, K. Jorner, M. Bryngelsson, S. E. Huber, J. Kull- gren, T. Frauenheim, and P. Broqvist, J. Phys. Chem. C117, 17004 (2013)

work page 2013
[13]

Fihey, C

A. Fihey, C. Hettich, J. Touzeau, F. Maurel, A. Perrier, C. Köh- ler, B. Aradi, and T. Frauenheim, J. Comput. Chem.36, 2075 (2015)

work page 2075
[14]

Panosetti, A

C. Panosetti, A. Engelmann, L. Nemec, K. Reuter, and J. T. Margraf, J. Chem. Theory Comput.16, 2181 (2020)

work page 2020
[15]

Stoöhr, L

M. Stoöhr, L. Medrano Sandonas, and A. Tkatchenko, J. Phys. Chem. Lett.11, 6835 (2020)

work page 2020
[16]

Goldman, L

N. Goldman, L. E. Fried, R. K. Lindsey, C. H. Pham, and R. Dettori, J. Chem. Phys.158, 144112 (2023)

work page 2023
[17]

Panosetti, Y

C. Panosetti, Y . Lee, A. Samtsevych, and C. Scheurer, J. Chem. Phys.158, 224115 (2023)

work page 2023
[18]

Vujovi ´c, M

M. Vujovi ´c, M. Huynh, S. Steiner, P. Garcia-Fernandez, M. El- stner, Q. Cui, and M. Gruden, J. Comput. Chem.40, 400 (2019)

work page 2019
[19]

G. Fan, A. McSloy, B. Aradi, C.-Y . Yam, and T. Frauenheim, The Journal of Physical Chemistry Letters13, 10132–10139 (2022)

work page 2022
[20]

McSloy, G

A. McSloy, G. Fan, W. Sun, C. Hölzer, M. Friede, S. Ehlert, N.-E. Schütte, S. Grimme, T. Frauenheim, and B. Aradi, The Journal of Chemical Physics158, 10.1063/5.0132892 (2023)

work page doi:10.1063/5.0132892 2023
[21]

W. Sun, G. Fan, T. van der Heide, A. McSloy, T. Frauenheim, and B. Aradi, Journal of Chemical Theory and Computation19, 3877–3888 (2023)

work page 2023
[22]

F. Hu, F. He, and D. J. Yaron, Journal of Chemical Theory and Computation19, 6185–6196 (2023)

work page 2023
[23]

Q. Gu, Z. Zhouyin, S. K. Pandey, P. Zhang, L. Zhang, and W. E, Nature Communications15, 10.1038/s41467-024-51006- 4 (2024)

work page doi:10.1038/s41467-024-51006- 2024
[24]

D. J. Burrill, C. Liu, M. G. Taylor, M. J. Cawkwell, D. Perez, E. R. Batista, N. Lubbers, and P. Yang, Journal of Chemical Theory and Computation21, 1089–1097 (2025)

work page 2025
[25]

Kohn and L

W. Kohn and L. J. Sham, Phys. Rev.140, A1133 (1965)

work page 1965
[26]

Kubas, F

A. Kubas, F. Hoffmann, A. Heck, H. Oberhofer, M. Elstner, and J. Blumberger, J. Chem. Phys.140, 104105 (2014)

work page 2014
[27]

M. Gaus, X. Lu, M. Elstner, and Q. Cui, J. Chem. Theory Com- put.10, 1518 (2014)

work page 2014
[28]

Tadic, D

M. Tadic, D. Nikolic, M. Panjan, and G. R. Blake, J. Alloys Compd.647, 1061 (2015). 6

work page 2015
[29]

Samtsevych, Y

A. Samtsevych, Y . Song, T. van der Heide, B. Aradi, B. Hourahine, R. Maurer, K. Reuter, C. Scheurer, and C. Panosetti, ChemRxiv 10.26434/chemrxiv-2025-4cmx9 (2025)

work page doi:10.26434/chemrxiv-2025-4cmx9 2025
[30]

J. P. Perdew, K. Burke, and M. Ernzerhof, Phys. Rev. Lett.77, 3865 (1996)

work page 1996
[31]

Zheng, H

G. Zheng, H. A. Witek, P. Bobadova-Parvanova, S. Irle, D. G. Musaev, R. Prabhakar, K. Morokuma, M. Lundberg, M. Elst- ner, C. Köhler, and T. Frauenheim, J. Chem. Theory Comput. 3, 1349 (2007)

work page 2007
[32]

W. A. Hofer, A. S. Foster, and A. L. Shluger, Rev. Mod. Phys. 75, 1287 (2003)

work page 2003
[33]

Jónsson, G

H. Jónsson, G. Mills, and K. W. Jacobsen, inClassical and Quantum Dynamics in Condensed Phase Simulations(World Scientific, 1998) p. 385–404

work page 1998
[34]

Panosetti, S

C. Panosetti, S. B. Annies, C. Grosu, S. Seidlmayer, and C. Scheurer, J. Phys. Chem. A125, 691–699 (2021)

work page 2021
[35]

Anniés, C

S. Anniés, C. Panosetti, M. V oronenko, D. Mauth, C. Rahe, and C. Scheurer, Materials14, 6633 (2021)

work page 2021
[36]

Nelson, C

R. Nelson, C. Ertural, J. George, V . L. Deringer, G. Hautier, and R. Dronskowski, Journal of Computational Chemistry41, 1931–1940 (2020)

work page 1931
[37]

A. P. Bartók, S. De, C. Poelking, N. Bernstein, J. R. Kermode, G. Csányi, and M. Ceriotti, Science Advances3, 10.1126/sci- adv.1701816 (2017)

work page doi:10.1126/sci- 2017
[38]

K. C. Lai, S. Matera, C. Scheurer, and K. Reuter, J. Chem. Phys. 159, 024129 (2023)

work page 2023
[39]

A. P. Bartók, R. Kondor, and G. Csányi, Phys. Rev. B87, 184115 (2013)

work page 2013
[40]

J. M. Lombardi, F. Riccius, C. W. P. Pare, H. H. Hee- nen, K. Reuter, and C. Scheurer, ChemRxiv2026(2026), https://chemrxiv.org/doi/pdf/10.26434/chemrxiv.15000180/v1

work page doi:10.26434/chemrxiv.15000180/v1 2026
[41]

A. Jain, S. P. Ong, G. Hautier, W. Chen, W. D. Richards, S. Dacek, S. Cholia, D. Gunter, D. Skinner, G. Ceder, and K. a. Persson, APL Mater.1, 011002 (2013)

work page 2013
[42]

Batatia, S

I. Batatia, S. Batzner, D. P. Kovács, A. Musaelian, G. N. C. Simm, R. Drautz, C. Ortner, B. Kozinsky, and G. Csányi, Nat. Mach. Intell.7, 56 (2025)

work page 2025
[43]

Musaelian, S

A. Musaelian, S. Batzner, A. Johansson, L. Sun, C. J. Owen, M. Kornbluth, and B. Kozinsky, Nat. Commun.14, 579 (2023)

work page 2023
[44]

van der Heide, B

T. van der Heide, B. Aradi, B. Hourahine, T. Frauenheim, and T. A. Niehaus, Phys. Rev. Mater.7, 063802 (2023)

work page 2023
[45]

Song, Data Availability to Adaptive Slater Koster Parame- ters: Crossing Oxidation States with Density Functional Tight Binding (2026)

Y . Song, Data Availability to Adaptive Slater Koster Parame- ters: Crossing Oxidation States with Density Functional Tight Binding (2026)

work page 2026
[46]

Hammer and J

B. Hammer and J. Nørskov, inImpact of Surface Science on Catalysis, Advances in Catalysis, V ol. 45 (Academic Press,

work page
[47]

band structure

pp. 71–129. END MA TTER Appendix A: DFTB theory, total energy, and DFTB2 SCC. In Kohn-Sham density-functional theory [25], for a multi- electron system in a field ofNnuclei at positions ⃗R, the to- tal energy can be written as a functional of the charge density n(⃗r). Within the tight binding ansatz [3], one can interpret the total energy as dependent on ...

work page

[1] [1]

Elstner, D

M. Elstner, D. Porezag, G. Jungnickel, J. Elsner, M. Haugk, T. Frauenheim, S. Suhai, and G. Seifert, Phys. Rev. B58, 7260 (1998)

work page 1998

[2] [2]

J. C. Slater and G. F. Koster, Phys. Rev.94, 1498 (1954)

work page 1954

[3] [3]

W. M. C. Foulkes and R. Haydock, Phys. Rev. B39, 12520 (1989)

work page 1989

[4] [4]

Seifert, D

G. Seifert, D. Porezag, and T. Frauenheim, Int. J. Quantum Chem.58, 185 (1996)

work page 1996

[5] [5]

Porezag, T

D. Porezag, T. Frauenheim, T. Köhler, G. Seifert, and R. Kaschner, Phys. Rev. B51, 12947 (1995)

work page 1995

[6] [6]

M. Gaus, Q. Cui, and M. Elstner, J. Chem. Theory Comput.7, 931 (2011)

work page 2011

[7] [7]

Hourahine, B

B. Hourahine, B. Aradi, V . Blum, F. Bonafé, A. Buccheri, C. Camacho, C. Cevallos, M. Y . Deshaye, T. Dumitric, A. Dominguez, S. Ehlert, M. Elstner, T. V . D. Heide, J. Her- mann, S. Irle, J. J. Kranz, C. Köhler, T. Kowalczyk, T. Kuba ˇr, I. S. Lee, V . Lutsker, R. J. Maurer, S. K. Min, I. Mitchell, C. Ne- gre, T. A. Niehaus, A. M. Niklasson, A. J. Page, ...

work page doi:10.1063/1.5143190 2020

[8] [8]

P. O. Dral, X. Wu, and W. Thiel, J. Chem. Theory Comput.15, 1743 (2019)

work page 2019

[9] [9]

P. O. Dral, B. Hourahine, and S. Grimme, J. Chem. Phys.160 (2024)

work page 2024

[10] [10]

M. Gaus, A. Goez, and M. Elstner, J. Chem. Theory Comput. 9, 338 (2013)

work page 2013

[11] [11]

A. K. Ammothum Kandy, E. Wadbro, B. Aradi, P. Broqvist, and J. Kullgren, Journal of Chemical Theory and Computation17, 1771–1781 (2021)

work page 2021

[12] [12]

Hellström, K

M. Hellström, K. Jorner, M. Bryngelsson, S. E. Huber, J. Kull- gren, T. Frauenheim, and P. Broqvist, J. Phys. Chem. C117, 17004 (2013)

work page 2013

[13] [13]

Fihey, C

A. Fihey, C. Hettich, J. Touzeau, F. Maurel, A. Perrier, C. Köh- ler, B. Aradi, and T. Frauenheim, J. Comput. Chem.36, 2075 (2015)

work page 2075

[14] [14]

Panosetti, A

C. Panosetti, A. Engelmann, L. Nemec, K. Reuter, and J. T. Margraf, J. Chem. Theory Comput.16, 2181 (2020)

work page 2020

[15] [15]

Stoöhr, L

M. Stoöhr, L. Medrano Sandonas, and A. Tkatchenko, J. Phys. Chem. Lett.11, 6835 (2020)

work page 2020

[16] [16]

Goldman, L

N. Goldman, L. E. Fried, R. K. Lindsey, C. H. Pham, and R. Dettori, J. Chem. Phys.158, 144112 (2023)

work page 2023

[17] [17]

Panosetti, Y

C. Panosetti, Y . Lee, A. Samtsevych, and C. Scheurer, J. Chem. Phys.158, 224115 (2023)

work page 2023

[18] [18]

Vujovi ´c, M

M. Vujovi ´c, M. Huynh, S. Steiner, P. Garcia-Fernandez, M. El- stner, Q. Cui, and M. Gruden, J. Comput. Chem.40, 400 (2019)

work page 2019

[19] [19]

G. Fan, A. McSloy, B. Aradi, C.-Y . Yam, and T. Frauenheim, The Journal of Physical Chemistry Letters13, 10132–10139 (2022)

work page 2022

[20] [20]

McSloy, G

A. McSloy, G. Fan, W. Sun, C. Hölzer, M. Friede, S. Ehlert, N.-E. Schütte, S. Grimme, T. Frauenheim, and B. Aradi, The Journal of Chemical Physics158, 10.1063/5.0132892 (2023)

work page doi:10.1063/5.0132892 2023

[21] [21]

W. Sun, G. Fan, T. van der Heide, A. McSloy, T. Frauenheim, and B. Aradi, Journal of Chemical Theory and Computation19, 3877–3888 (2023)

work page 2023

[22] [22]

F. Hu, F. He, and D. J. Yaron, Journal of Chemical Theory and Computation19, 6185–6196 (2023)

work page 2023

[23] [23]

Q. Gu, Z. Zhouyin, S. K. Pandey, P. Zhang, L. Zhang, and W. E, Nature Communications15, 10.1038/s41467-024-51006- 4 (2024)

work page doi:10.1038/s41467-024-51006- 2024

[24] [24]

D. J. Burrill, C. Liu, M. G. Taylor, M. J. Cawkwell, D. Perez, E. R. Batista, N. Lubbers, and P. Yang, Journal of Chemical Theory and Computation21, 1089–1097 (2025)

work page 2025

[25] [25]

Kohn and L

W. Kohn and L. J. Sham, Phys. Rev.140, A1133 (1965)

work page 1965

[26] [26]

Kubas, F

A. Kubas, F. Hoffmann, A. Heck, H. Oberhofer, M. Elstner, and J. Blumberger, J. Chem. Phys.140, 104105 (2014)

work page 2014

[27] [27]

M. Gaus, X. Lu, M. Elstner, and Q. Cui, J. Chem. Theory Com- put.10, 1518 (2014)

work page 2014

[28] [28]

Tadic, D

M. Tadic, D. Nikolic, M. Panjan, and G. R. Blake, J. Alloys Compd.647, 1061 (2015). 6

work page 2015

[29] [29]

Samtsevych, Y

A. Samtsevych, Y . Song, T. van der Heide, B. Aradi, B. Hourahine, R. Maurer, K. Reuter, C. Scheurer, and C. Panosetti, ChemRxiv 10.26434/chemrxiv-2025-4cmx9 (2025)

work page doi:10.26434/chemrxiv-2025-4cmx9 2025

[30] [30]

J. P. Perdew, K. Burke, and M. Ernzerhof, Phys. Rev. Lett.77, 3865 (1996)

work page 1996

[31] [31]

Zheng, H

G. Zheng, H. A. Witek, P. Bobadova-Parvanova, S. Irle, D. G. Musaev, R. Prabhakar, K. Morokuma, M. Lundberg, M. Elst- ner, C. Köhler, and T. Frauenheim, J. Chem. Theory Comput. 3, 1349 (2007)

work page 2007

[32] [32]

W. A. Hofer, A. S. Foster, and A. L. Shluger, Rev. Mod. Phys. 75, 1287 (2003)

work page 2003

[33] [33]

Jónsson, G

H. Jónsson, G. Mills, and K. W. Jacobsen, inClassical and Quantum Dynamics in Condensed Phase Simulations(World Scientific, 1998) p. 385–404

work page 1998

[34] [34]

Panosetti, S

C. Panosetti, S. B. Annies, C. Grosu, S. Seidlmayer, and C. Scheurer, J. Phys. Chem. A125, 691–699 (2021)

work page 2021

[35] [35]

Anniés, C

S. Anniés, C. Panosetti, M. V oronenko, D. Mauth, C. Rahe, and C. Scheurer, Materials14, 6633 (2021)

work page 2021

[36] [36]

Nelson, C

R. Nelson, C. Ertural, J. George, V . L. Deringer, G. Hautier, and R. Dronskowski, Journal of Computational Chemistry41, 1931–1940 (2020)

work page 1931

[37] [37]

A. P. Bartók, S. De, C. Poelking, N. Bernstein, J. R. Kermode, G. Csányi, and M. Ceriotti, Science Advances3, 10.1126/sci- adv.1701816 (2017)

work page doi:10.1126/sci- 2017

[38] [38]

K. C. Lai, S. Matera, C. Scheurer, and K. Reuter, J. Chem. Phys. 159, 024129 (2023)

work page 2023

[39] [39]

A. P. Bartók, R. Kondor, and G. Csányi, Phys. Rev. B87, 184115 (2013)

work page 2013

[40] [40]

J. M. Lombardi, F. Riccius, C. W. P. Pare, H. H. Hee- nen, K. Reuter, and C. Scheurer, ChemRxiv2026(2026), https://chemrxiv.org/doi/pdf/10.26434/chemrxiv.15000180/v1

work page doi:10.26434/chemrxiv.15000180/v1 2026

[41] [41]

A. Jain, S. P. Ong, G. Hautier, W. Chen, W. D. Richards, S. Dacek, S. Cholia, D. Gunter, D. Skinner, G. Ceder, and K. a. Persson, APL Mater.1, 011002 (2013)

work page 2013

[42] [42]

Batatia, S

I. Batatia, S. Batzner, D. P. Kovács, A. Musaelian, G. N. C. Simm, R. Drautz, C. Ortner, B. Kozinsky, and G. Csányi, Nat. Mach. Intell.7, 56 (2025)

work page 2025

[43] [43]

Musaelian, S

A. Musaelian, S. Batzner, A. Johansson, L. Sun, C. J. Owen, M. Kornbluth, and B. Kozinsky, Nat. Commun.14, 579 (2023)

work page 2023

[44] [44]

van der Heide, B

T. van der Heide, B. Aradi, B. Hourahine, T. Frauenheim, and T. A. Niehaus, Phys. Rev. Mater.7, 063802 (2023)

work page 2023

[45] [45]

Song, Data Availability to Adaptive Slater Koster Parame- ters: Crossing Oxidation States with Density Functional Tight Binding (2026)

Y . Song, Data Availability to Adaptive Slater Koster Parame- ters: Crossing Oxidation States with Density Functional Tight Binding (2026)

work page 2026

[46] [46]

Hammer and J

B. Hammer and J. Nørskov, inImpact of Surface Science on Catalysis, Advances in Catalysis, V ol. 45 (Academic Press,

work page

[47] [47]

band structure

pp. 71–129. END MA TTER Appendix A: DFTB theory, total energy, and DFTB2 SCC. In Kohn-Sham density-functional theory [25], for a multi- electron system in a field ofNnuclei at positions ⃗R, the to- tal energy can be written as a functional of the charge density n(⃗r). Within the tight binding ansatz [3], one can interpret the total energy as dependent on ...

work page