Pith Number

pith:ROV4DVPV

pith:2026:ROV4DVPVM7E4MWKKKIZPSXK6I6

not attested not anchored not stored refs resolved

Radioactive Molecules as Laboratories of Fundamental Physics

A. Jadbabaie, A. M. Jayich, J. T. Singh, N. R. Hutzler, R.F. Garcia Ruiz, S. Ebadi

Radioactive molecules serve as sensitive new laboratories for detecting physics beyond the Standard Model.

arxiv:2605.12767 v1 · 2026-05-12 · physics.atom-ph · hep-ex · nucl-ex

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\usepackage{pith}
\pithnumber{ROV4DVPVM7E4MWKKKIZPSXK6I6}

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Record completeness

1 Bitcoin timestamp

2 Internet Archive

3 Author claim open · sign in to claim

4 Citations open

5 Replications open

✓ Portable graph bundle live · download bundle · merged state

The bundle contains the canonical record plus signed events. A mirror can host it anywhere and recompute the same current state with the deterministic merge algorithm.

Claims

C1strongest claim

Radioactive molecules provide a powerful new platform in the search for new physics at energy scales complementary to high-energy particle colliders.

C2weakest assumption

That ongoing advances in production, control, and theoretical modeling of radioactive molecules will deliver the sensitivity needed to detect or constrain new physics effects.

C3one line summary

Radioactive molecules offer enhanced sensitivity to new physics through combined nuclear and molecular properties, providing a platform complementary to high-energy colliders.

References

150 extracted · 150 resolved · 2 Pith anchors

[1] Canetti, L., Drewes, M. & Shaposhnikov, M. Matter and antimatter in the universe.New J. Phys.14, 095012 (2012) 2012

[2] Sakharov, A. D. Violation of CP Invariance, C asymmetry, and baryon asymmetry of the universe. JETP Lett.5, 24–27 (1967). Originally published in Pisma Zh. Eksp. Teor. Fiz. 5, 32–35 (1967) 1967

[3] de Vries, J., Postma, M., van de Vis, J. & White, G. Electroweak baryogenesis and the standard model effective field theory.J. High Energy Phys.2018(2018). 15/28 2018

[4] Phys.13, 391–396, DOI: 10.1038/nphys4021 (2017) 2017 · doi:10.1038/nphys4021

[5] Bar-Shalom, S., Soni, A. & Wudka, J. Theoretical underpinnings of CP-violation at the high-energy frontier.Phys. Lett. B860, 139135, DOI: 10.1016/j.physletb.2024.139135 2024 · doi:10.1016/j.physletb.2024.139135

Receipt and verification

First computed	2026-05-18T03:09:48.217351Z
Builder	pith-number-builder-2026-05-17-v1
Signature	Pith Ed25519 (`pith-v1-2026-05`) · public key
Schema	pith-number/v1.0

Canonical hash

8babc1d5f567c9c6594a5232f95d5e479c2bed034b0e8dd9f081d30c8f081573

Aliases

arxiv: 2605.12767 · arxiv_version: 2605.12767v1 · doi: 10.48550/arxiv.2605.12767 · pith_short_12: ROV4DVPVM7E4 · pith_short_16: ROV4DVPVM7E4MWKK · pith_short_8: ROV4DVPV

Agent API

Resolver JSON Graph JSON Events JSON Schema Signing key

Verify this Pith Number yourself

curl -sH 'Accept: application/ld+json' https://pith.science/pith/ROV4DVPVM7E4MWKKKIZPSXK6I6 \
  | jq -c '.canonical_record' \
  | python3 -c "import sys,json,hashlib; b=json.dumps(json.loads(sys.stdin.read()), sort_keys=True, separators=(',',':'), ensure_ascii=False).encode(); print(hashlib.sha256(b).hexdigest())"
# expect: 8babc1d5f567c9c6594a5232f95d5e479c2bed034b0e8dd9f081d30c8f081573

Canonical record JSON

{
  "metadata": {
    "abstract_canon_sha256": "e46f149e6b98d6742ba8bf909ffc25bb54c8d578fc47f50e1a0f9e90acce9e74",
    "cross_cats_sorted": [
      "hep-ex",
      "nucl-ex"
    ],
    "license": "http://arxiv.org/licenses/nonexclusive-distrib/1.0/",
    "primary_cat": "physics.atom-ph",
    "submitted_at": "2026-05-12T21:31:29Z",
    "title_canon_sha256": "362d241fafe066dc34c8081385aacf0d92bddf337c68730603ac03395ad75522"
  },
  "schema_version": "1.0",
  "source": {
    "id": "2605.12767",
    "kind": "arxiv",
    "version": 1
  }
}