Chiral Pt(Me-BPCH): Synthesis and theoretical investigation of parity violation sensitivity

Anastasia Borschevsky; Beno\^it Darqui\'e; Charles Silva; D. Scott Bohle; Eduardus; J. Wietze J. van Boven; Luk\'a\v{s} F. Pa\v{s}teka; Philip Karageorghis

arxiv: 2509.26407 · v1 · pith:WTOI36HMnew · submitted 2025-09-30 · ⚛️ physics.chem-ph

Chiral Pt(Me-BPCH): Synthesis and theoretical investigation of parity violation sensitivity

Eduardus , J. Wietze J. van Boven , Charles Silva , Philip Karageorghis , D. Scott Bohle , Beno\^it Darqui\'e , Anastasia Borschevsky , Luk\'a\v{s} F. Pa\v{s}teka This is my paper

Pith reviewed 2026-05-21 22:07 UTC · model grok-4.3

classification ⚛️ physics.chem-ph

keywords parity violationchiral moleculesplatinum complexvibrational spectroscopycomputational chemistryMe-BPCHsynthesis

0 comments

The pith

The chiral platinum complex Pt(Me-BPCH) has vibrational transitions with enhanced parity violation effects suitable for measurement.

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

The paper reports the synthesis of Pt(Me-BPCH) and uses computations to evaluate how parity violation shifts its vibrational frequencies. Comparisons with Au(Me-BPCH) and Pt(CF3-BPCH) are used to locate modes that combine sizable PV shifts with experimental accessibility. A sympathetic reader cares because a positive measurement would give a direct molecular test of fundamental symmetry breaking at accessible energies. The central task is to rank transitions by the size of their PV response while keeping practical factors such as intensity and linewidth in view.

Core claim

Pt(Me-BPCH) exhibits promising vibrational transitions with enhanced PV effects suitable for measurement, identified through computational investigation and comparison to Au(Me-BPCH) and Pt(CF3-BPCH). The most promising transitions are selected on the basis of their enhanced PV effects and practical experimental considerations, while the relationship between vibrational structure and PV sensitivity is analyzed across all three molecules.

What carries the argument

Computational evaluation of parity violation contributions to the vibrational frequencies of the chiral Pt(Me-BPCH) complex and its two derivatives.

Load-bearing premise

The computational methods accurately predict both the magnitude and sign of parity violation contributions to the vibrational frequencies without large systematic errors from basis-set incompleteness or electron-correlation approximations.

What would settle it

A high-resolution infrared or Raman measurement of the vibrational lines in Pt(Me-BPCH) that either matches the computed PV-induced frequency shifts or deviates from them by more than the estimated uncertainty.

Figures

Figures reproduced from arXiv: 2509.26407 by Anastasia Borschevsky, Beno\^it Darqui\'e, Charles Silva, D. Scott Bohle, Eduardus, J. Wietze J. van Boven, Luk\'a\v{s} F. Pa\v{s}teka, Philip Karageorghis.

**Figure 1.** Figure 1: Thermal ellipsoid plot of Pt(Me-BPCH). Note, the asymmetric unit contains two complexes. Key metric parameters (◦,˚A) include: Pt(1)-N(1) 1.971(8), Pt(1)-N(2) 1.954(7), Pt(1)-N(3) 2.064(3), Pt(1)-N(4) 2.069(7), N(1)-C(2) 1.327(12), C(2)-O(1) 1.251(11), N(2)-C(3) 1.343(11), C(3)-O(2) 1.224(11), N(1)-Pt(1)- N(2) 85.2(3), N(3)-Pt(1)-N(4) 114.0(3). Top: view perpendicular to the C2 axis; bottom: view along C2 … view at source ↗

**Figure 2.** Figure 2: Schematic representation of the left- (S) and right-handed (R) enantiomers of Pt(Me-BPCH) and response of their respective vibrational transitions to parity violation effects. 2.2. Computational Details Geometry optimizations and the harmonic frequency analysis were carried out in Gaussian16 program [43], using the ωB97X-D density functional [44] combined with the Def2-TZVPP basis set [45], which includes… view at source ↗

**Figure 3.** Figure 3: Comparison of the experimental (KBr matrix) and calculated IR spectra of Pt(Me-BPCH). Both spectra are normalized to the highest peak. The calculated stick spectrum is based on harmonic vibrational analysis with empirically scaled frequencies using a factor 0.94. The experimental spectrum is vertically shifted for increased legibility. 3.2. Sensitivity to Parity Violation The calculated frequencies and int… view at source ↗

**Figure 4.** Figure 4: Comparison of the potential energy curves V (q) (blue lines) and the PV potential curves V PV(q) (red lines) of the asymmetric (top) and symmetric (bottom) C=O strecthing modes of Pt(Me-BPCH), Au(MeBPCH) and Pt(CF3-BPCH). The displacement vectors (i.e. the q axes) are aligned and oriented in the same direction for easier visual comparison. visual representation of the differences in the PV shifts observed… view at source ↗

read the original abstract

A complex of platinum and the tetra-coordinate chelating ligand, R,R'-6,6'-dimethyl-N,N'-bis(2'-pyridine-carboxamide)-1-cyclohexane (Me-BPCH) is investigated as a potential candidate for measurement of parity violation (PV) in chiral molecules. The synthesis of Pt(Me-BPCH) is presented alongside computational investigation of PV sensitivity in its vibrational spectrum. Pt(Me-BPCH) is compared to other two derivatives of this complex, Au(Me-BPCH) and Pt(CF$_3$-BPCH) in terms of their PV response and suitability for measurement. We identify the most promising vibrational transitions based on their enhanced PV effects and practical experimental considerations and analyze the relationship between the vibrational structure and the corresponding PV sensitivity for all three molecules.

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.

Referee Report

2 major / 2 minor

Summary. The manuscript reports the synthesis of the chiral platinum complex Pt(Me-BPCH) together with a computational study of parity-violating contributions to its vibrational frequencies. The PV sensitivities are compared with those of the Au(Me-BPCH) and Pt(CF3-BPCH) analogs; specific vibrational transitions are identified as promising for future experimental PV measurements on the basis of their computed frequency shifts and practical considerations.

Significance. If the computed PV shifts prove reliable, the work supplies a concrete synthetic target and a comparative analysis that could help prioritize transitions for high-resolution spectroscopy aimed at detecting molecular parity violation. The experimental synthesis itself is a tangible contribution, and the ligand-variation comparison offers qualitative insight into structure-PV relationships in heavy-element complexes.

major comments (2)

[Computational Methods] Computational Methods section: the manuscript provides no information on the relativistic Hamiltonian (ZORA, DKH, or four-component), DFT functional, basis-set family for Pt and light atoms, or the numerical implementation of the PV operator in the vibrational Hessian. For a 5d center the PV shift is dominated by the nuclear-spin-independent weak interaction near the Pt nucleus; without these details the reported ordering of enhanced modes cannot be assessed for robustness against basis-set incompleteness or functional error.
[Results] Results section (comparison of Pt(Me-BPCH) with Au and CF3 analogs): the central claim that certain modes exhibit larger PV shifts rests on unbenchmarked relativistic DFT values. No cross-validation against a smaller chiral molecule whose PV frequency shift has been computed at a higher level (e.g., Dirac-Coulomb CCSD(T)) is presented, leaving open the possibility that systematic errors reverse the relative ordering of the three complexes.

minor comments (2)

[Abstract] Abstract: the phrase 'computational investigation' should be expanded to name the level of theory and any key approximations so that readers can immediately gauge the computational rigor.
[Notation] Notation: ensure that the symbol used for the PV frequency shift is defined once and used consistently; avoid introducing new acronyms without explicit expansion.

Simulated Author's Rebuttal

2 responses · 0 unresolved

We thank the referee for their careful reading of our manuscript and for the constructive comments. We address each major comment below and indicate the changes we will make in the revised version.

read point-by-point responses

Referee: [Computational Methods] Computational Methods section: the manuscript provides no information on the relativistic Hamiltonian (ZORA, DKH, or four-component), DFT functional, basis-set family for Pt and light atoms, or the numerical implementation of the PV operator in the vibrational Hessian. For a 5d center the PV shift is dominated by the nuclear-spin-independent weak interaction near the Pt nucleus; without these details the reported ordering of enhanced modes cannot be assessed for robustness against basis-set incompleteness or functional error.

Authors: We agree that the Computational Methods section should contain these technical details to allow assessment of the results. In the revised manuscript we will expand this section to specify the relativistic Hamiltonian (ZORA), the DFT functional, the basis-set families used for Pt and the light atoms, and the numerical implementation of the PV operator within the vibrational Hessian. revision: yes
Referee: [Results] Results section (comparison of Pt(Me-BPCH) with Au and CF3 analogs): the central claim that certain modes exhibit larger PV shifts rests on unbenchmarked relativistic DFT values. No cross-validation against a smaller chiral molecule whose PV frequency shift has been computed at a higher level (e.g., Dirac-Coulomb CCSD(T)) is presented, leaving open the possibility that systematic errors reverse the relative ordering of the three complexes.

Authors: We acknowledge that absolute PV shifts from relativistic DFT carry systematic uncertainty. However, all three complexes were treated with exactly the same methodology, so the relative ordering of their PV sensitivities remains meaningful within this consistent framework. Dirac-Coulomb CCSD(T) calculations on these large 5d-containing systems are currently prohibitive. In the revision we will add an explicit discussion of these methodological limitations and the rationale for relying on relative DFT trends. revision: partial

Circularity Check

0 steps flagged

Standard relativistic DFT computations of PV shifts show no self-referential reduction

full rationale

The paper reports synthesis of Pt(Me-BPCH) followed by computational evaluation of parity-violating contributions to vibrational frequencies using established quantum-chemistry methods. These calculations are performed independently for Pt(Me-BPCH), Au(Me-BPCH), and Pt(CF3-BPCH) and compared directly; the resulting PV sensitivities are outputs of the electronic-structure treatment rather than parameters fitted to the target observables or redefined by construction. No load-bearing step reduces to a self-citation chain or ansatz smuggled from prior author work. Minor self-citations to earlier PV methodology papers exist but do not substitute for the present computations. The derivation chain therefore remains self-contained against external benchmarks.

Axiom & Free-Parameter Ledger

0 free parameters · 1 axioms · 0 invented entities

Abstract provides no explicit free parameters, invented entities, or detailed axioms; computational PV work implicitly relies on standard quantum chemistry assumptions.

axioms (1)

domain assumption Standard quantum chemistry methods (DFT or similar) accurately capture parity-violating contributions to vibrational frequencies
The theoretical investigation of PV sensitivity presupposes that the chosen electronic structure method and basis sets yield reliable PV matrix elements.

pith-pipeline@v0.9.0 · 5714 in / 1173 out tokens · 33710 ms · 2026-05-21T22:07:48.517958+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 washburn_uniqueness_aczel unclear

?

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

Geometry optimizations... using the ωB97X-D density functional combined with the Def2-TZVPP basis set... PV energy contributions... using the effective PV Hamiltonian... Numerov–Cooley (NC) procedure

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

72 extracted references · 72 canonical work pages

[1]

Pasteur, C

L. Pasteur, C. R. Hebd. s´ eances Acad. Sci.26(21), 535–539 (1848)

work page
[2]

Bloom, Y

B.P. Bloom, Y. Paltiel, R. Naaman and D.H. Waldeck, Chemical Reviews124(4), 1950– 1991 (2024)

work page 1950
[3]

Ayuso, A.F

D. Ayuso, A.F. Ordonez and O. Smirnova, Phys. Chem. Chem. Phys.24, 26962–26991 (2022)

work page 2022
[4]

Yamashita, T

Y. Yamashita, T. Yasukawa, W.J. Yoo, T. Kitanosono and S. Kobayashi, Chem. Soc. Rev.47, 4388–4480 (2018)

work page 2018
[5]

Fiechter, P.A.B

M.R. Fiechter, P.A.B. Haase, N. Saleh, P. Soulard, B. Tremblay, R.W.A. Havenith, R.G.E. Timmermans, P. Schwerdtfeger, J. Crassous, B. Darqui´ e, L.F. Paˇ steka and A. Borschevsky, The Journal of Physical Chemistry Letters13(42), 10011–10017 (2022)

work page 2022
[6]

Saleh, R

N. Saleh, R. Bast, N. Vanthuyne, C. Roussel, T. Saue, B. Darqui´ e and J. Crassous, Chirality30(2), 147–156 (2018)

work page 2018
[7]

Saleh, S

N. Saleh, S. Zrig, T. Roisnel, L. Guy, R. Bast, T. Saue, B. Darqui´ e and J. Crassous, Phys. Chem. Chem. Phys.15, 10952–10959 (2013)

work page 2013
[8]

Shagam, A

Eduardus, Y. Shagam, A. Landau, S. Faraji, P. Schwerdtfeger, A. Borschevsky and L.F. Paˇ steka, Chem. Commun.59, 14579–14582 (2023)

work page 2023
[9]

Landau, Eduardus, D

A. Landau, Eduardus, D. Behar, E.R. Wallach, L.F. Paˇ steka, S. Faraji, A. Borschevsky and Y. Shagam, The Journal of Chemical Physics159(11), 114307 (2023)

work page 2023
[10]

Schwerdtfeger, inComputational Spectroscopy: Methods, Experiments and Applications, edited by J¨ org Grunenberg (, , 2010), Chap

P. Schwerdtfeger, inComputational Spectroscopy: Methods, Experiments and Applications, edited by J¨ org Grunenberg (, , 2010), Chap. 7, pp. 201–221

work page 2010
[11]

Berger and J

R. Berger and J. Stohner, WIREs Computational Molecular Science9(3), e1396 (2019)

work page 2019
[12]

C.S. Wu, E. Ambler, R.W. Hayward, D.D. Hoppes and R.P. Hudson, Physical Review 105, 1413–1415 (1957)

work page 1957
[13]

Bouchiat, J

M. Bouchiat, J. Guena, L. Pottier and L. Hunter, Physics Letters B134(6), 463–468 (1984)

work page 1984
[14]

Wood, S.C

C.S. Wood, S.C. Bennett, D. Cho, B.P. Masterson, J.L. Roberts, C.E. Tanner and C.E. Wieman, Science275(5307), 1759–1763 (1997)

work page 1997
[15]

Crassous, C

J. Crassous, C. Chardonnet, T. Saue and P. Schwerdtfeger, Organic and Biomolecular Chemistry3, 2218–2224 (2005)

work page 2005
[16]

Darqui´ e, C

B. Darqui´ e, C. Stoeffler, S. Zrig, J. Crassous, P. Soulard, P. Asselin, T.R. Huet, L. Guy, R. Bast, T. Saue, P. Schwerdtfeger, A. Shelkovnikov, C. Daussy, A. Amy-Klein and C. Chardonnet, Chirality22, 870–884 (2010)

work page 2010
[17]

Quack, G

M. Quack, G. Seyfang and G. Wichmann, Chemical Science13, 10598–10643 (2022)

work page 2022
[18]

Daussy, T

C. Daussy, T. Marrel, A. Amy-Klein, C.T. Nguyen, C.J. Bord´ e and C. Chardonnet, Phys- ical Review Letters83, 1554–1557 (1999)

work page 1999
[19]

Crassous, J.P

J. Crassous, J.P. Monier, F. Dutasta, M. Ziskind, C. Daussy, C. Grain and C. Chardonnet, ChemPhysChem4, 541 (2003)

work page 2003
[20]

Safronova, D

M.S. Safronova, D. Budker, D. DeMille, D.F.J. Kimball, A. Derevianko and C.W. Clark, Rev. Mod. Phys.90, 025008 (2018)

work page 2018
[21]

Gaul, M.G

K. Gaul, M.G. Kozlov, T.A. Isaev and R. Berger, Phys. Rev. Lett.125, 123004 (2020)

work page 2020
[22]

Cournol, M

A. Cournol, M. Manceau, M. Pierens, L. Lecordier, D. Tran, R. Santagata, B. Argence, A. Goncharov, O. Lopez, M. Abgrall, Y. Le Coq, R. Le Targat, H. ´Alvarez Martinez, W. Lee, D. Xu, P.E. Pottie, R. Hendricks, T. Wall, J. Bieniewska, B. Sauer, M. Tarbutt, A. Amy-Klein, S. Tokunaga and B. Darqui´ e, Quantum Electronics49(3), 288 (2019)

work page 2019
[23]

Zel’Dovich, D.B

B.Y. Zel’Dovich, D.B. Saakyan and I.I. Sobel’Man, Soviet Journal of Experimental and Theoretical Physics Letters25, 94 (1977)

work page 1977
[24]

R. Bast, A. Koers, A.S.P. Gomes, M. Iliaˇ s, L. Visscher, P. Schwerdtfeger and T. Saue, Phys. Chem. Chem. Phys.13, 864–876 (2011)

work page 2011
[25]

Bouchiat and C

M. Bouchiat and C. Bouchiat, Physics Letters B48(2), 111–114 (1974)

work page 1974
[26]

Harris and L

R. Harris and L. Stodolsky, Physics Letters B78(2–3), 313–317 (1978)

work page 1978
[27]

Hegstrom, D.W

R.A. Hegstrom, D.W. Rein and P.G.H. Sandars, The Journal of Chemical Physics73(5), 2329–2341 (1980). 13

work page 1980
[28]

Laerdahl and P.A

J.K. Laerdahl and P.A. Schwerdtfeger, Physical Review A - Atomic, Molecular, and Op- tical Physics60(6), 4439 – 4453 (1999)

work page 1999
[29]

Laerdahl, P.A

J.K. Laerdahl, P.A. Schwerdtfeger and H.M. Quiney, Physical Review Letters84(17), 3811 – 3814 (2000)

work page 2000
[30]

Bast and P.A

R. Bast and P.A. Schwerdtfeger, Physical Review Letters91(2) (2003)

work page 2003
[31]

Schwerdtfeger, J

P.A. Schwerdtfeger, J. Gierlich and T. Bollwein, Angewandte Chemie - International Edition42(11), 1293 – 1296 (2003)

work page 2003
[32]

Schwerdtfeger and R

P.A. Schwerdtfeger and R. Bast, Journal of the American Chemical Society126(6), 1652 – 1653 (2004)

work page 2004
[33]

Figgen, T

D. Figgen, T. Saue and P.A. Schwerdtfeger, Journal of Chemical Physics132(23) (2010)

work page 2010
[34]

Figgen, A.H

D. Figgen, A.H. Koers and P.A. Schwerdtfeger, Angewandte Chemie - International Edi- tion49(16), 2941 – 2943 (2010)

work page 2010
[35]

de Montigny, R

F. de Montigny, R. Bast, A.S.P. Gomes, G. Pilet, N. Vanthuyne, C.M. Roussel, L. Guy, P.A. Schwerdtfeger, T. Saue and J. Crassous, Physical Chemistry Chemical Physics12 (31), 8792 – 8803 (2010)

work page 2010
[36]

Nahrwold, R.J.F

S. Nahrwold, R.J.F. Berger and P.A. Schwerdtfeger, Journal of Chemical Physics140(2) (2014)

work page 2014
[37]

Wormit, M

M. Wormit, M. Olejniczak, A.L. Deppenmeier, A. Borschevsky, T. Saue and P. Schwerdt- feger, Physical Chemistry Chemical Physics16(32), 17043–17051 (2014)

work page 2014
[38]

Lemal, The Journal of Organic Chemistry69(1), 1–11 (2004)

D.M. Lemal, The Journal of Organic Chemistry69(1), 1–11 (2004)

work page 2004
[39]

Pfaltz and W.J

A. Pfaltz and W.J. Drury, Proc. Nat. Acad. Sci.(USA)101(16), 5723–5726 (2004)

work page 2004
[40]

Belda and C

O. Belda and C. Moberg, Coord. Chem. Rev.249(5), 727–740 (2005)

work page 2005
[41]

Bateman, S.W

L. Bateman, S.W. Breeden and P.O. Leary, Tetrahed.: Asym19(3), 391–396 (2008)

work page 2008
[42]

Macrae, I

C.F. Macrae, I. Sovago, S.J. Cottrell, P.T.A. Galek, P. McCabe, E. Pidcock, M. Platings, G.P. Shields, J.S. Stevens, M. Towler and P.A. Wood, Journal of Applied Crystallography 53(1), 226–235 (2020)

work page 2020
[43]

Frisch, G.W

M.J. Frisch, G.W. Trucks, H.B. Schlegel, G.E. Scuseria, M.A. Robb, J.R. Cheeseman, G. Scalmani, V. Barone, G.A. Petersson, H. Nakatsuji, X. Li, M. Caricato, A.V. Marenich, J. Bloino, B.G. Janesko, R. Gomperts, B. Mennucci, H.P. Hratchian, J.V. Ortiz, A.F. Izmaylov, J.L. Sonnenberg, D. Williams-Young, F. Ding, F. Lipparini, F. Egidi, J. Goings, B. Peng, A....

work page 2016
[44]

Chai and M

J.D. Chai and M. Head-Gordon, Phys. Chem. Chem. Phys.10, 6615–6620 (2008)

work page 2008
[45]

Weigend and R

F. Weigend and R. Ahlrichs, Phys. Chem. Chem. Phys.7, 3297–3305 (2005)

work page 2005
[46]

Andrae, U

D. Andrae, U. H¨ außermann, M. Dolg, H. Stoll and H. Preuß, Theoretica chimica acta77 (2), 123–141 (1990)

work page 1990
[47]

DIRAC, a relativistic ab initio electronic structure program, Release DIRAC23 (2023), written by R. Bast, A. S. P. Gomes, T. Saue and L. Visscher and H. J. Aa. Jensen, with contributions from I. A. Aucar, V. Bakken, C. Chibueze, J. Creutzberg, K. G. Dyall, S. Dubillard, U. Ekstr¨ om, E. Eliav, T. Enevoldsen, E. Faßhauer, T. Fleig, O. Fos- sgaard, L. Halbe...

work page doi:10.5281/zenodo.7670749 2023
[48]

Berger, inRelativistic Electronic Structure Theory, edited by Peter Schwerdtfeger, Theoretical and Computational Chemistry, Vol

R. Berger, inRelativistic Electronic Structure Theory, edited by Peter Schwerdtfeger, Theoretical and Computational Chemistry, Vol. 14 (, , 2004), pp. 188–288

work page 2004
[49]

Heß, C.M

B.A. Heß, C.M. Marian, U. Wahlgren and O. Gropen, Chemical Physics Letters251(5-6), 365–371 (1996)

work page 1996
[50]

Schimmelpfennig, AMFI, an atomic mean-field spin-orbit integral program 1996 and 1999, University of Stockholm

B. Schimmelpfennig, AMFI, an atomic mean-field spin-orbit integral program 1996 and 1999, University of Stockholm

work page 1996
[51]

Thierfelder, G

C. Thierfelder, G. Rauhut and P. Schwerdtfeger, Physical Review A81, 032513 (2010)

work page 2010
[52]

Dyall, Theoretical Chemistry Accounts112(5-6), 403–409 (2004), revision K.G

K.G. Dyall, Theoretical Chemistry Accounts112(5-6), 403–409 (2004), revision K.G. Dyall and A.S.P. Gomes, Theor. Chem. Acc. (2009) 125:97

work page 2004
[53]

Dyall, Theoretical Chemistry Accounts135(5), 128 (2016)

K.G. Dyall, Theoretical Chemistry Accounts135(5), 128 (2016)

work page 2016
[54]

Noumerov, Monthly Notices of the Royal Astronomical Society84(8), 592–602 (1924)

B.V. Noumerov, Monthly Notices of the Royal Astronomical Society84(8), 592–602 (1924)

work page 1924
[55]

Cooley, Mathematics of Computation (1961)

J.W. Cooley, Mathematics of Computation (1961)

work page 1961
[56]

Bast, Numerov v0.5.0 Zenodo,https://doi.org/10.5281/zenodo.10004062017, Oct

R. Bast, Numerov v0.5.0 Zenodo,https://doi.org/10.5281/zenodo.10004062017, Oct

work page doi:10.5281/zenodo.10004062017
[57]

Tokunaga, C

S.K. Tokunaga, C. Stoeffler, F. Auguste, A. Shelkovnikov, C. Daussy, A. Amy-Klein, C. Chardonnet and B. Darqui´ e, Molecular Physics111(14–15), 2363–2373 (2013)

work page 2013
[58]

Cournol and other, Quantum Electronics49(3), 288–292 (2019)

A. Cournol and other, Quantum Electronics49(3), 288–292 (2019)

work page 2019
[59]

Tokunaga, R.J

S.K. Tokunaga, R.J. Hendricks, M.R. Tarbutt and B. Darqui´ e, New Journal of Physics 19(5), 053006 (2017)

work page 2017
[60]

Asselin, Y

P. Asselin, Y. Berger, T.R. Huet, L. Margul` es, R. Motiyenko, R.J. Hendricks, M.R. Tarbutt, S.K. Tokunaga and B. Darqui´ e, Physical Chemistry Chemical Physics19(6), 4576–4587 (2017)

work page 2017
[61]

Darqui´ e, N

B. Darqui´ e, N. Saleh, S.K. Tokunaga, M. Srebro-Hooper, A. Ponzi, J. Autschbach, P. Decleva, G.A. Garcia, J. Crassous and L. Nahon, Physical Chemistry Chemical Physics 23(42), 24140–24153 (2021)

work page 2021
[62]

Shelkovnikov, R.J

A. Shelkovnikov, R.J. Butcher, C. Chardonnet and A. Amy-Klein, Physical Review Letters 100(15) (2008)

work page 2008
[63]

Argence, B

B. Argence, B. Chanteau, O. Lopez, D. Nicolodi, M. Abgrall, C. Chardonnet, C. Daussy, B. Darqui´ e, Y. Le Coq and A. Amy-Klein, Nature Photonics9(7), 456–460 (2015)

work page 2015
[64]

Santagata, D.B.A

R. Santagata, D.B.A. Tran, B. Argence, O. Lopez, S.K. Tokunaga, F. Wiotte, H. Mouhamad, A. Goncharov, M. Abgrall, Y. Le Coq, H. Alvarez-Martinez, R. Le Targat, W.K. Lee, D. Xu, P.E. Pottie, B. Darqui´ e and A. Amy-Klein, Optica6(4), 411 (2019)

work page 2019
[65]

D.B.A. Tran, O. Lopez, M. Manceau, A. Goncharov, M. Abgrall, H. Alvarez-Martinez, R. Le Targat, E. Cantin, P.E. Pottie, A. Amy-Klein and B. Darqui´ e, APL Photonics9 (3) (2024)

work page 2024
[66]

D.B.A. Tran, M. Manceau, O. Lopez, A. Goncharov, A. Amy-Klein and B. Darqui´ e, Ex- tending frequency metrology to increasingly complex molecules: SI-traceable sub-Doppler mid-IR spectroscopy of trioxane 2025, arXiv:2502.08201

work page arXiv 2025
[67]

Chanteau, O

B. Chanteau, O. Lopez, W. Zhang, D. Nicolodi, B. Argence, F. Auguste, M. Abgrall, C. Chardonnet, G. Santarelli, B. Darqui´ e, Y. Le Coq and A. Amy-Klein, New Journal of Physics15(7), 073003 (2013)

work page 2013
[68]

Cantin, M

E. Cantin, M. Tønnes, R. Le Targat, A. Amy-Klein, O. Lopez and P.E. Pottie, New Journal of Physics23(5), 053027 (2021)

work page 2021
[69]

Paˇ steka, A

Eduardus, L.F. Paˇ steka, A. Bonifacio, M. Manceau, S. Faraji, N. Kuroda, M. Senami, J.J. Aucar, I.A. Aucar, M.R. Fiechter, J. Crassous, T. Saue, B. Darqui´ e and A. Borschevsky, Parity violation effects in helical osmocene: theoretical analysis and ex- perimental prospects,in preparation

work page
[70]

Y. Wang, J. Rodewald, O. Lopez, M. Manceau, B. Darqui´ e, B.E. Sauer and M.R. Tarbutt, New Journal of Physics27(2), 023038 (2025)

work page 2025
[71]

Manceau, T.E

M. Manceau, T.E. Wall, H. Philip, A. Baranov, O. Lopez, M.R. Tarbutt, R. Teissier and B. Darqui´ e, Laser & Photonics Reviews (2025)

work page 2025
[72]

Schwerdtfeger, T

P. Schwerdtfeger, T. Saue, J. van Stralen and L. Visscher, Physical Review A71(1), 15 012103 (2005). 16

work page 2005

[1] [1]

Pasteur, C

L. Pasteur, C. R. Hebd. s´ eances Acad. Sci.26(21), 535–539 (1848)

work page

[2] [2]

Bloom, Y

B.P. Bloom, Y. Paltiel, R. Naaman and D.H. Waldeck, Chemical Reviews124(4), 1950– 1991 (2024)

work page 1950

[3] [3]

Ayuso, A.F

D. Ayuso, A.F. Ordonez and O. Smirnova, Phys. Chem. Chem. Phys.24, 26962–26991 (2022)

work page 2022

[4] [4]

Yamashita, T

Y. Yamashita, T. Yasukawa, W.J. Yoo, T. Kitanosono and S. Kobayashi, Chem. Soc. Rev.47, 4388–4480 (2018)

work page 2018

[5] [5]

Fiechter, P.A.B

M.R. Fiechter, P.A.B. Haase, N. Saleh, P. Soulard, B. Tremblay, R.W.A. Havenith, R.G.E. Timmermans, P. Schwerdtfeger, J. Crassous, B. Darqui´ e, L.F. Paˇ steka and A. Borschevsky, The Journal of Physical Chemistry Letters13(42), 10011–10017 (2022)

work page 2022

[6] [6]

Saleh, R

N. Saleh, R. Bast, N. Vanthuyne, C. Roussel, T. Saue, B. Darqui´ e and J. Crassous, Chirality30(2), 147–156 (2018)

work page 2018

[7] [7]

Saleh, S

N. Saleh, S. Zrig, T. Roisnel, L. Guy, R. Bast, T. Saue, B. Darqui´ e and J. Crassous, Phys. Chem. Chem. Phys.15, 10952–10959 (2013)

work page 2013

[8] [8]

Shagam, A

Eduardus, Y. Shagam, A. Landau, S. Faraji, P. Schwerdtfeger, A. Borschevsky and L.F. Paˇ steka, Chem. Commun.59, 14579–14582 (2023)

work page 2023

[9] [9]

Landau, Eduardus, D

A. Landau, Eduardus, D. Behar, E.R. Wallach, L.F. Paˇ steka, S. Faraji, A. Borschevsky and Y. Shagam, The Journal of Chemical Physics159(11), 114307 (2023)

work page 2023

[10] [10]

Schwerdtfeger, inComputational Spectroscopy: Methods, Experiments and Applications, edited by J¨ org Grunenberg (, , 2010), Chap

P. Schwerdtfeger, inComputational Spectroscopy: Methods, Experiments and Applications, edited by J¨ org Grunenberg (, , 2010), Chap. 7, pp. 201–221

work page 2010

[11] [11]

Berger and J

R. Berger and J. Stohner, WIREs Computational Molecular Science9(3), e1396 (2019)

work page 2019

[12] [12]

C.S. Wu, E. Ambler, R.W. Hayward, D.D. Hoppes and R.P. Hudson, Physical Review 105, 1413–1415 (1957)

work page 1957

[13] [13]

Bouchiat, J

M. Bouchiat, J. Guena, L. Pottier and L. Hunter, Physics Letters B134(6), 463–468 (1984)

work page 1984

[14] [14]

Wood, S.C

C.S. Wood, S.C. Bennett, D. Cho, B.P. Masterson, J.L. Roberts, C.E. Tanner and C.E. Wieman, Science275(5307), 1759–1763 (1997)

work page 1997

[15] [15]

Crassous, C

J. Crassous, C. Chardonnet, T. Saue and P. Schwerdtfeger, Organic and Biomolecular Chemistry3, 2218–2224 (2005)

work page 2005

[16] [16]

Darqui´ e, C

B. Darqui´ e, C. Stoeffler, S. Zrig, J. Crassous, P. Soulard, P. Asselin, T.R. Huet, L. Guy, R. Bast, T. Saue, P. Schwerdtfeger, A. Shelkovnikov, C. Daussy, A. Amy-Klein and C. Chardonnet, Chirality22, 870–884 (2010)

work page 2010

[17] [17]

Quack, G

M. Quack, G. Seyfang and G. Wichmann, Chemical Science13, 10598–10643 (2022)

work page 2022

[18] [18]

Daussy, T

C. Daussy, T. Marrel, A. Amy-Klein, C.T. Nguyen, C.J. Bord´ e and C. Chardonnet, Phys- ical Review Letters83, 1554–1557 (1999)

work page 1999

[19] [19]

Crassous, J.P

J. Crassous, J.P. Monier, F. Dutasta, M. Ziskind, C. Daussy, C. Grain and C. Chardonnet, ChemPhysChem4, 541 (2003)

work page 2003

[20] [20]

Safronova, D

M.S. Safronova, D. Budker, D. DeMille, D.F.J. Kimball, A. Derevianko and C.W. Clark, Rev. Mod. Phys.90, 025008 (2018)

work page 2018

[21] [21]

Gaul, M.G

K. Gaul, M.G. Kozlov, T.A. Isaev and R. Berger, Phys. Rev. Lett.125, 123004 (2020)

work page 2020

[22] [22]

Cournol, M

A. Cournol, M. Manceau, M. Pierens, L. Lecordier, D. Tran, R. Santagata, B. Argence, A. Goncharov, O. Lopez, M. Abgrall, Y. Le Coq, R. Le Targat, H. ´Alvarez Martinez, W. Lee, D. Xu, P.E. Pottie, R. Hendricks, T. Wall, J. Bieniewska, B. Sauer, M. Tarbutt, A. Amy-Klein, S. Tokunaga and B. Darqui´ e, Quantum Electronics49(3), 288 (2019)

work page 2019

[23] [23]

Zel’Dovich, D.B

B.Y. Zel’Dovich, D.B. Saakyan and I.I. Sobel’Man, Soviet Journal of Experimental and Theoretical Physics Letters25, 94 (1977)

work page 1977

[24] [24]

R. Bast, A. Koers, A.S.P. Gomes, M. Iliaˇ s, L. Visscher, P. Schwerdtfeger and T. Saue, Phys. Chem. Chem. Phys.13, 864–876 (2011)

work page 2011

[25] [25]

Bouchiat and C

M. Bouchiat and C. Bouchiat, Physics Letters B48(2), 111–114 (1974)

work page 1974

[26] [26]

Harris and L

R. Harris and L. Stodolsky, Physics Letters B78(2–3), 313–317 (1978)

work page 1978

[27] [27]

Hegstrom, D.W

R.A. Hegstrom, D.W. Rein and P.G.H. Sandars, The Journal of Chemical Physics73(5), 2329–2341 (1980). 13

work page 1980

[28] [28]

Laerdahl and P.A

J.K. Laerdahl and P.A. Schwerdtfeger, Physical Review A - Atomic, Molecular, and Op- tical Physics60(6), 4439 – 4453 (1999)

work page 1999

[29] [29]

Laerdahl, P.A

J.K. Laerdahl, P.A. Schwerdtfeger and H.M. Quiney, Physical Review Letters84(17), 3811 – 3814 (2000)

work page 2000

[30] [30]

Bast and P.A

R. Bast and P.A. Schwerdtfeger, Physical Review Letters91(2) (2003)

work page 2003

[31] [31]

Schwerdtfeger, J

P.A. Schwerdtfeger, J. Gierlich and T. Bollwein, Angewandte Chemie - International Edition42(11), 1293 – 1296 (2003)

work page 2003

[32] [32]

Schwerdtfeger and R

P.A. Schwerdtfeger and R. Bast, Journal of the American Chemical Society126(6), 1652 – 1653 (2004)

work page 2004

[33] [33]

Figgen, T

D. Figgen, T. Saue and P.A. Schwerdtfeger, Journal of Chemical Physics132(23) (2010)

work page 2010

[34] [34]

Figgen, A.H

D. Figgen, A.H. Koers and P.A. Schwerdtfeger, Angewandte Chemie - International Edi- tion49(16), 2941 – 2943 (2010)

work page 2010

[35] [35]

de Montigny, R

F. de Montigny, R. Bast, A.S.P. Gomes, G. Pilet, N. Vanthuyne, C.M. Roussel, L. Guy, P.A. Schwerdtfeger, T. Saue and J. Crassous, Physical Chemistry Chemical Physics12 (31), 8792 – 8803 (2010)

work page 2010

[36] [36]

Nahrwold, R.J.F

S. Nahrwold, R.J.F. Berger and P.A. Schwerdtfeger, Journal of Chemical Physics140(2) (2014)

work page 2014

[37] [37]

Wormit, M

M. Wormit, M. Olejniczak, A.L. Deppenmeier, A. Borschevsky, T. Saue and P. Schwerdt- feger, Physical Chemistry Chemical Physics16(32), 17043–17051 (2014)

work page 2014

[38] [38]

Lemal, The Journal of Organic Chemistry69(1), 1–11 (2004)

D.M. Lemal, The Journal of Organic Chemistry69(1), 1–11 (2004)

work page 2004

[39] [39]

Pfaltz and W.J

A. Pfaltz and W.J. Drury, Proc. Nat. Acad. Sci.(USA)101(16), 5723–5726 (2004)

work page 2004

[40] [40]

Belda and C

O. Belda and C. Moberg, Coord. Chem. Rev.249(5), 727–740 (2005)

work page 2005

[41] [41]

Bateman, S.W

L. Bateman, S.W. Breeden and P.O. Leary, Tetrahed.: Asym19(3), 391–396 (2008)

work page 2008

[42] [42]

Macrae, I

C.F. Macrae, I. Sovago, S.J. Cottrell, P.T.A. Galek, P. McCabe, E. Pidcock, M. Platings, G.P. Shields, J.S. Stevens, M. Towler and P.A. Wood, Journal of Applied Crystallography 53(1), 226–235 (2020)

work page 2020

[43] [43]

Frisch, G.W

M.J. Frisch, G.W. Trucks, H.B. Schlegel, G.E. Scuseria, M.A. Robb, J.R. Cheeseman, G. Scalmani, V. Barone, G.A. Petersson, H. Nakatsuji, X. Li, M. Caricato, A.V. Marenich, J. Bloino, B.G. Janesko, R. Gomperts, B. Mennucci, H.P. Hratchian, J.V. Ortiz, A.F. Izmaylov, J.L. Sonnenberg, D. Williams-Young, F. Ding, F. Lipparini, F. Egidi, J. Goings, B. Peng, A....

work page 2016

[44] [44]

Chai and M

J.D. Chai and M. Head-Gordon, Phys. Chem. Chem. Phys.10, 6615–6620 (2008)

work page 2008

[45] [45]

Weigend and R

F. Weigend and R. Ahlrichs, Phys. Chem. Chem. Phys.7, 3297–3305 (2005)

work page 2005

[46] [46]

Andrae, U

D. Andrae, U. H¨ außermann, M. Dolg, H. Stoll and H. Preuß, Theoretica chimica acta77 (2), 123–141 (1990)

work page 1990

[47] [47]

DIRAC, a relativistic ab initio electronic structure program, Release DIRAC23 (2023), written by R. Bast, A. S. P. Gomes, T. Saue and L. Visscher and H. J. Aa. Jensen, with contributions from I. A. Aucar, V. Bakken, C. Chibueze, J. Creutzberg, K. G. Dyall, S. Dubillard, U. Ekstr¨ om, E. Eliav, T. Enevoldsen, E. Faßhauer, T. Fleig, O. Fos- sgaard, L. Halbe...

work page doi:10.5281/zenodo.7670749 2023

[48] [48]

Berger, inRelativistic Electronic Structure Theory, edited by Peter Schwerdtfeger, Theoretical and Computational Chemistry, Vol

R. Berger, inRelativistic Electronic Structure Theory, edited by Peter Schwerdtfeger, Theoretical and Computational Chemistry, Vol. 14 (, , 2004), pp. 188–288

work page 2004

[49] [49]

Heß, C.M

B.A. Heß, C.M. Marian, U. Wahlgren and O. Gropen, Chemical Physics Letters251(5-6), 365–371 (1996)

work page 1996

[50] [50]

Schimmelpfennig, AMFI, an atomic mean-field spin-orbit integral program 1996 and 1999, University of Stockholm

B. Schimmelpfennig, AMFI, an atomic mean-field spin-orbit integral program 1996 and 1999, University of Stockholm

work page 1996

[51] [51]

Thierfelder, G

C. Thierfelder, G. Rauhut and P. Schwerdtfeger, Physical Review A81, 032513 (2010)

work page 2010

[52] [52]

Dyall, Theoretical Chemistry Accounts112(5-6), 403–409 (2004), revision K.G

K.G. Dyall, Theoretical Chemistry Accounts112(5-6), 403–409 (2004), revision K.G. Dyall and A.S.P. Gomes, Theor. Chem. Acc. (2009) 125:97

work page 2004

[53] [53]

Dyall, Theoretical Chemistry Accounts135(5), 128 (2016)

K.G. Dyall, Theoretical Chemistry Accounts135(5), 128 (2016)

work page 2016

[54] [54]

Noumerov, Monthly Notices of the Royal Astronomical Society84(8), 592–602 (1924)

B.V. Noumerov, Monthly Notices of the Royal Astronomical Society84(8), 592–602 (1924)

work page 1924

[55] [55]

Cooley, Mathematics of Computation (1961)

J.W. Cooley, Mathematics of Computation (1961)

work page 1961

[56] [56]

Bast, Numerov v0.5.0 Zenodo,https://doi.org/10.5281/zenodo.10004062017, Oct

R. Bast, Numerov v0.5.0 Zenodo,https://doi.org/10.5281/zenodo.10004062017, Oct

work page doi:10.5281/zenodo.10004062017

[57] [57]

Tokunaga, C

S.K. Tokunaga, C. Stoeffler, F. Auguste, A. Shelkovnikov, C. Daussy, A. Amy-Klein, C. Chardonnet and B. Darqui´ e, Molecular Physics111(14–15), 2363–2373 (2013)

work page 2013

[58] [58]

Cournol and other, Quantum Electronics49(3), 288–292 (2019)

A. Cournol and other, Quantum Electronics49(3), 288–292 (2019)

work page 2019

[59] [59]

Tokunaga, R.J

S.K. Tokunaga, R.J. Hendricks, M.R. Tarbutt and B. Darqui´ e, New Journal of Physics 19(5), 053006 (2017)

work page 2017

[60] [60]

Asselin, Y

P. Asselin, Y. Berger, T.R. Huet, L. Margul` es, R. Motiyenko, R.J. Hendricks, M.R. Tarbutt, S.K. Tokunaga and B. Darqui´ e, Physical Chemistry Chemical Physics19(6), 4576–4587 (2017)

work page 2017

[61] [61]

Darqui´ e, N

B. Darqui´ e, N. Saleh, S.K. Tokunaga, M. Srebro-Hooper, A. Ponzi, J. Autschbach, P. Decleva, G.A. Garcia, J. Crassous and L. Nahon, Physical Chemistry Chemical Physics 23(42), 24140–24153 (2021)

work page 2021

[62] [62]

Shelkovnikov, R.J

A. Shelkovnikov, R.J. Butcher, C. Chardonnet and A. Amy-Klein, Physical Review Letters 100(15) (2008)

work page 2008

[63] [63]

Argence, B

B. Argence, B. Chanteau, O. Lopez, D. Nicolodi, M. Abgrall, C. Chardonnet, C. Daussy, B. Darqui´ e, Y. Le Coq and A. Amy-Klein, Nature Photonics9(7), 456–460 (2015)

work page 2015

[64] [64]

Santagata, D.B.A

R. Santagata, D.B.A. Tran, B. Argence, O. Lopez, S.K. Tokunaga, F. Wiotte, H. Mouhamad, A. Goncharov, M. Abgrall, Y. Le Coq, H. Alvarez-Martinez, R. Le Targat, W.K. Lee, D. Xu, P.E. Pottie, B. Darqui´ e and A. Amy-Klein, Optica6(4), 411 (2019)

work page 2019

[65] [65]

D.B.A. Tran, O. Lopez, M. Manceau, A. Goncharov, M. Abgrall, H. Alvarez-Martinez, R. Le Targat, E. Cantin, P.E. Pottie, A. Amy-Klein and B. Darqui´ e, APL Photonics9 (3) (2024)

work page 2024

[66] [66]

D.B.A. Tran, M. Manceau, O. Lopez, A. Goncharov, A. Amy-Klein and B. Darqui´ e, Ex- tending frequency metrology to increasingly complex molecules: SI-traceable sub-Doppler mid-IR spectroscopy of trioxane 2025, arXiv:2502.08201

work page arXiv 2025

[67] [67]

Chanteau, O

B. Chanteau, O. Lopez, W. Zhang, D. Nicolodi, B. Argence, F. Auguste, M. Abgrall, C. Chardonnet, G. Santarelli, B. Darqui´ e, Y. Le Coq and A. Amy-Klein, New Journal of Physics15(7), 073003 (2013)

work page 2013

[68] [68]

Cantin, M

E. Cantin, M. Tønnes, R. Le Targat, A. Amy-Klein, O. Lopez and P.E. Pottie, New Journal of Physics23(5), 053027 (2021)

work page 2021

[69] [69]

Paˇ steka, A

Eduardus, L.F. Paˇ steka, A. Bonifacio, M. Manceau, S. Faraji, N. Kuroda, M. Senami, J.J. Aucar, I.A. Aucar, M.R. Fiechter, J. Crassous, T. Saue, B. Darqui´ e and A. Borschevsky, Parity violation effects in helical osmocene: theoretical analysis and ex- perimental prospects,in preparation

work page

[70] [70]

Y. Wang, J. Rodewald, O. Lopez, M. Manceau, B. Darqui´ e, B.E. Sauer and M.R. Tarbutt, New Journal of Physics27(2), 023038 (2025)

work page 2025

[71] [71]

Manceau, T.E

M. Manceau, T.E. Wall, H. Philip, A. Baranov, O. Lopez, M.R. Tarbutt, R. Teissier and B. Darqui´ e, Laser & Photonics Reviews (2025)

work page 2025

[72] [72]

Schwerdtfeger, T

P. Schwerdtfeger, T. Saue, J. van Stralen and L. Visscher, Physical Review A71(1), 15 012103 (2005). 16

work page 2005