Pith Number

pith:DMTRWZJP

pith:2026:DMTRWZJPUM2X5F7AIEZS4OUK4F

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Floquet engineering of nonreciprocal light-induced dipolar interactions

Benjamin A. Stickler, Iurie Coroli, Livia Egyed, Manuel Reisenbauer, Murad Abuzarli, Uro\v{s} Deli\'c

Floquet driving of nonreciprocal dipolar forces produces beamsplitter, squeezing, and tunable complex frequencies between trapped particles.

arxiv:2605.13694 v1 · 2026-05-13 · quant-ph · physics.atom-ph · physics.optics

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\usepackage{pith}
\pithnumber{DMTRWZJPUM2X5F7AIEZS4OUK4F}

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2 Internet Archive

3 Author claim open · sign in to claim

4 Citations open

5 Replications open

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Claims

C1strongest claim

We demonstrate beamsplitter, single-, and two-mode squeezing operations, as well as signatures of a negative-mass-like oscillator arising from the nonreciprocity. Moreover, we show that a programmable combination of these operations enables continuous tuning of complex eigenfrequencies.

C2weakest assumption

That the idealized Floquet-driven nonreciprocal dipolar interactions can be realized in actual tweezer arrays without dominant experimental imperfections such as heating, decoherence, or scattering losses that would wash out the predicted operations.

C3one line summary

Floquet engineering of nonreciprocal light-induced dipolar interactions in tweezer arrays realizes beamsplitter, squeezing operations, negative-mass-like signatures, and tunable complex eigenfrequencies.

References

65 extracted · 65 resolved · 0 Pith anchors

[1] Progress in quantum metrology and applications for optical atomic clocks 2025

[2] J. Ye and P. Zoller, Phys. Rev. Lett.132, 190001 (2024) 2024

[3] S. Colombo, E. Pedrozo-Pe˜ nafiel, and V. Vuleti´ c, Ap- plied Physics Letters121, 210502 (2022) 2022

[4] I. Bloch, J. Dalibard, and W. Zwerger, Rev. Mod. Phys. 80, 885 (2008) 2008

[5] N. Defenu, T. Donner, T. Macrı, G. Pagano, S. Ruffo, and A. Trombettoni, Reviews of Modern Physics95, 035002 (2023) 2023

Receipt and verification

First computed	2026-05-18T02:44:16.920477Z
Builder	pith-number-builder-2026-05-17-v1
Signature	Pith Ed25519 (`pith-v1-2026-05`) · public key
Schema	pith-number/v1.0

Canonical hash

1b271b652fa3357e97e041332e3a8ae16de4a9adf75c10b33c70b5d0269acb98

Aliases

arxiv: 2605.13694 · arxiv_version: 2605.13694v1 · doi: 10.48550/arxiv.2605.13694 · pith_short_12: DMTRWZJPUM2X · pith_short_16: DMTRWZJPUM2X5F7A · pith_short_8: DMTRWZJP

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/DMTRWZJPUM2X5F7AIEZS4OUK4F \
  | 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: 1b271b652fa3357e97e041332e3a8ae16de4a9adf75c10b33c70b5d0269acb98

Canonical record JSON

{
  "metadata": {
    "abstract_canon_sha256": "67e7361236e2e5e8e6afbd29d4a48bfc14541449fc7cfbfec417f30a983b7dca",
    "cross_cats_sorted": [
      "physics.atom-ph",
      "physics.optics"
    ],
    "license": "http://creativecommons.org/licenses/by/4.0/",
    "primary_cat": "quant-ph",
    "submitted_at": "2026-05-13T15:46:28Z",
    "title_canon_sha256": "19b40256f4ccb3637134f9e1fe21cdcee1e1571c71301738d024fa9e9a34d9b5"
  },
  "schema_version": "1.0",
  "source": {
    "id": "2605.13694",
    "kind": "arxiv",
    "version": 1
  }
}