Multiphotonics (2025)

Revision as of 13:08, 20 August 2025

The second MULTIPHOTONICS meeting will take place in Madrid, on 8–9 October (2025) with the support of ICMM—CSIC and IFF—CSIC. It follows the very successful MULTIPHOTONICS (2024) first edition. The workshop will likewise discuss the physics of multiphoton correlations.

If you liked Munich, you'll love Madrid!

Topics

Multiphoton generation: Single and $N$-photon emission.
Quantum light generation with properties such as entanglement or squeezing.
Frequency filtering, statistics, coherence and correlation measurements.
Quantum optics, cavity-QED, light-matter interaction and nanophotonics.

Venue

ICMM-CSIC on the Cantoblanco Campus:

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Hotel accommodation

External attendants will be provided with a two-nights (Tue 7 & Wed 9) hotel room with breakfast at the VP Jardín De Tres Cantos in Tres Cantos. This is a quiet, modern urban-planning city at the north of Madrid, well connected to the site of the meeting and to the Spanish capital itself.

Organizers

The event is supported by a joint ICMM‒IFF effort:

Fabrice Laussy from ICMM‒CSIC.
Carlos Sánchez Muñoz from IFF‒CSIC.

Contact the organizers.

Confirmed Attendants

Tentative Program

Tuesday 7 October

Participants arrive.

Wednesday 8 October (Day 1)

Morning Session

Opening (by Fabrice Laussy)

8:50-9:00

Serge Reynaud

9:00-9:30

Kai Müller

Unlocking multiphoton emission from a single-photon source through mean-field engineering — 9:30-10:00

Multiphotons are generally regarded as accidental in the context of single photon sources. However, multiphoton emission can turn out to be even more fundamental and interesting than the single-photon emission, since in a coherently driven system, the multiphoton suppression arises from quantum interferences between virtual multiphoton fluctuations and the mean field in a Poisson superposition of all number states. Here, we demonstrate how one can control the multiphoton dynamics of a two-level system by disrupting these quantum interferences through a precise and independent homodyne control of the mean field. We show that, counterintuitively, quantum fluctuations always play a major qualitative role, even and in fact especially, when their quantitative contribution is vanishing as compared to that of the mean field.^[1]

Joaquin Guimbao Gaspar

10:00-10:30

Juan Camilo López Carreño

10:30-11:00

Coffee break

Post-coffee

Jesper Mørk

Quantum noise and squeezing in nanolasers. — 11:30-12:00

We present a recently developed method for simulating quantum noise in nanolasers.^[2]^[3] Based on a simple stochastic interpretation of rate equations, the approach accurately reproduces quantum master equation results for few-emitter lasers and aligns with Langevin equations in macroscopic regimes. Notably, it bridges the intermediate mesoscopic regime previously inaccessible to existing models. We apply this method to analyze amplitude squeezing in nanolasers using novel cavities with extreme light confinement, which strongly enhance light-matter interaction.

Elena del Valle

12:00-12:30

Ahsan Nazir

12:30-13:00

Владислав Шишков

Spectral theory and statistical properties of integrated single-photon sources. — 13:00-13:30

Lunch

Group photo

Afternoon Session

Philipp Schneeweiß

Tailoring photon statistics with an atom-based two-photon interferometer — 15:00-15:30

Based on Ref. _^[4].

Johannes Feist

15:30-16:00

Lukas Hanschke

16:00-16:30

Francesca Marchetti

16:30-17:00

Coffee break

Evening Session

Jake Iles-Smith

17:30-18:00

Antonio Isaac Fernandez Dominguez

18:00-18:30

Yajun Wang

18:30-19:00

Carlos Sánchez

19:00-19:30

20:30 Dinner

Thursday 9 October (Day 2)

Morning Session

Sven Höfling

9:00-9:30

Tim Thomay

Higher-order Fock states for sensing applications. — 9:30-10:00

See Ref. _^[5].

Jacob Ngaha

10:00-10:30

Eduardo Zubizarreta Casalengua

10:30-11:00

Coffee break

Post-Coffee Session

Zhiliang Yuan

11:30-12:00

Carlos Antón Solanas

12:00-12:30

Sang Kyu Kim

12:30-13:00

Alejandro González Tudela

13:00-13:30

Lunch

Afternoon Session

Vincenzo D'Ambrosio

14:30-15:00

Alexandros Spilioti

15:00-15:30

Natalia Armaou

15:30-16:00

Fabrice Laussy

Liquid time and time liquids — 16:00-16:30

The basic quantum-optical emitter—the two-level system—is already much more complicated than one could reasonably expect, and to this day, its thorough characterization remains to be completed.^[6] Here, I will jump to the case of the $N$-level system, and survey the amazing phenomenology that immediately shouts out from this simplest extension of the brick of quantum optics. A first surprise is that the $N$-level system, not the two-level one, is the most suitable to implement perfect single-photon sources.^[7] Furthemore, a good single-photon source acquires features that differ considerably from those usually wanted for that purpose. For instance, instead of merely suppressing two-photon coincidences at $\tau=0$, a good single-photon emitter is one that develops long-time oscillations as a result of self-organizing its photon streams to all orders in photon counting, differing from the basic case in a way similar to how a liquid differs from a gas.^[8] This calls for revisiting our understanding of single-photon sources, and raise fascinating questions on how they relate, in time, to exotic phase of matters.^[9] I will also describe how such a picture extends into multiphotonics,^[10] and how one could observe such effects experimentally.^[11]

Closing (by Carlos Sánchez)

Goodbye coffee & Merienda

Participants depart

Q&A(bstracts)

At this occasion, we shall try to revive an old format of archiving Scientific debates: instead of publishing proceedings, we will publish the abstract and the (edited) Questions & Answers sessions, which contains information nowhere else to be found.

References

↑ Unlocking multiphoton emission from a single-photon source through mean-field engineering., Sang Kyu Kim et al. arXiv:2411.10441 (2024).
↑ Stochastic Approach to the Quantum Noise of a Single-Emitter Nanolaser. M. Bundgaard-Nielsen, E. V. Denning, M. Saldutti and J. Mork in Phys. Rev. Lett. 130:253801 (2023).
↑ Simple yet Accurate Stochastic Approach to the Quantum Phase Noise of Nanolasers. M. Bundgaard-Nielsen, M. Saldutti, B. F. Gotzsche, E. Grovn and J. Mork in Phys. Rev. Lett. 134:213804 (2025).
↑ Tailoring Photon Statistics with an Atom-Based Two-Photon Interferometer. M. Cordier, M. Schemmer, P. Schneeweiss, J. Volz and A. Rauschenbeutel in Phys. Rev. Lett. 131:183601 (2023).
↑ Statistical model for quantum spin and photon number states. S. Powers, G. Xu, H. Fotso, T. Thomay and D. Stojkovic in Phys. Rev. A 111:012217 (2025).
↑ Two photons everywhere. E. Zubizarreta Casalengua, F. P. Laussy and E. del Valle in Phil. Trans. R. Soc. A 382:20230315 (2024).
↑ Perfect single-photon sources. S. Khalid and F. P. Laussy in Sci. Rep. 14:2684 (2024).
↑ Photon liquefaction in time. E. Zubizarreta Casalengua, E. del Valle and F. P. Laussy in APL Quant. 1:026117 (2024).
↑ Crystals in Time. F. Wilczek in Sci. Am. 32:28 (2019).
↑ Correlations in circular quantum cascades. M. A. Palomo Marcos, E. Zubizarreta Casalengua, E. del Valle and F. P. Laussy in Phys. Rev. A 111:023704 (2025).
↑ Correlations in a three-level system, A. Barreto Padrón, E. del Valle and F. P. Laussy, unpublished.

[1] Unlocking multiphoton emission from a single-photon source through mean-field engineering., Sang Kyu Kim et al. arXiv:2411.10441 (2024).

[cite-bundgaardnielsen23a-2] Stochastic Approach to the Quantum Noise of a Single-Emitter Nanolaser. M. Bundgaard-Nielsen, E. V. Denning, M. Saldutti and J. Mork in Phys. Rev. Lett. 130:253801 (2023).

[cite-bundgaardnielsen25a-3] Simple yet Accurate Stochastic Approach to the Quantum Phase Noise of Nanolasers. M. Bundgaard-Nielsen, M. Saldutti, B. F. Gotzsche, E. Grovn and J. Mork in Phys. Rev. Lett. 134:213804 (2025).

[cite-cordier23a-4] Tailoring Photon Statistics with an Atom-Based Two-Photon Interferometer. M. Cordier, M. Schemmer, P. Schneeweiss, J. Volz and A. Rauschenbeutel in Phys. Rev. Lett. 131:183601 (2023).

[cite-powers25a-5] Statistical model for quantum spin and photon number states. S. Powers, G. Xu, H. Fotso, T. Thomay and D. Stojkovic in Phys. Rev. A 111:012217 (2025).

[cite-zubizarretacasalengua24b-6] Two photons everywhere. E. Zubizarreta Casalengua, F. P. Laussy and E. del Valle in Phil. Trans. R. Soc. A 382:20230315 (2024).

[cite-khalid24a-7] Perfect single-photon sources. S. Khalid and F. P. Laussy in Sci. Rep. 14:2684 (2024).

[cite-zubizarretacasalengua24a-8] Photon liquefaction in time. E. Zubizarreta Casalengua, E. del Valle and F. P. Laussy in APL Quant. 1:026117 (2024).

[cite-wilczek19a-9] Crystals in Time. F. Wilczek in Sci. Am. 32:28 (2019).

[cite-palomo25a-10] Correlations in circular quantum cascades. M. A. Palomo Marcos, E. Zubizarreta Casalengua, E. del Valle and F. P. Laussy in Phys. Rev. A 111:023704 (2025).

[cite-barretopadron25a-11] Correlations in a three-level system, A. Barreto Padrón, E. del Valle and F. P. Laussy, unpublished.

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[3]

[4]

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[6]

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@@ Line 28: / Line 28: @@
 {{#display_map:
 .54371620681268, -3.6895857339526277~Multiphotonics 2025;
+.601729668839276, -3.7140155088021896~Hotel;
+.41540847521611, -3.7073765955284195~Plaza Mayor de Madrid;
 }}
-Hotel accommodation for foreign attendants is currently being arranged.
+== Hotel accommodation ==
+External attendants will be provided with a two-nights (Tue&nbsp;7 & Wed&nbsp;9) hotel room with breakfast at the [https://www.trescantos-hotel.com/ VP Jardín De Tres Cantos] in [[Tres Cantos]]. This is a quiet, modern urban-planning city at the north of [[Madrid]], well connected to the site of the meeting and to the Spanish capital itself.
 == Organizers ==
@@ Line 52: / Line 56: @@
 # [[Vincenzo D'Ambrosio]] - [[Università di Napoli Federico II]], [[Napoli]]
 # [[Vladislav Shishkov|Владислав Шишков (Vladislav Shishkov)]] - [[Aalto University]], [[Espoo]]
+# [[Yajun Wang]] - [[Shanxi University]], [[China]]
 # [[Alexandros Spiliotis]] - [[IESL-FORTH]], [[Heraklion]]
+# [[Natalia Armaou]] - [[Westlake University]], [[China]]
 # [[Juan Camilo López Carreño]] - [[University of Warsaw]], [[Warsaw]]
 # [[Carlos Antón Solanas]] - {{uam}}
 # [[Johannes Feist]] - {{uam}}
 # [[Antonio Isaac Fernandez Dominguez]] - {{uam}}
+# [[Alejandro González Tudela]] - [[IFF]]-[[CSIC]], [[Madrid]]
 # [[Francesca Marchetti]] - {{uam}}
 # [[Eduardo Zubizarreta Casalengua]] - [[Technische Universität München]], [[München]]
@@ Line 62: / Line 69: @@
 # [[Joaquin Guimbao Gaspar]] - [[ICMM]]-[[CSIC]], [[Madrid]]
 # [[Jacob Ngaha]] - [[ICMM]]-[[CSIC]], [[Madrid]]
-# [[Alejandro González Tudela]] - [[IFF]]-[[CSIC]], [[Madrid]]
+# [[Lukas Hanschke]] - [[Technische Universität München]], [[München]]
-<!--# [[Arianna Barreto Padrón]] - {{uam}}-->
 # [[Elena del Valle]] - {{uam}}
 # [[Carlos Sánchez]] - [[IFF]]-[[CSIC]], [[Madrid]]
@@ Line 79: / Line 85: @@
 ===== Opening (by Fabrice Laussy) =====
+:50-9:00
 ===== Serge Reynaud =====
+:00-9:30
 ===== Kai Müller =====
+''Unlocking multiphoton emission from a single-photon source through mean-field engineering'' — 9:30-10:00
+:Multiphotons are generally regarded as accidental in the context of single photon sources. However, multiphoton emission can turn out to be even more fundamental and interesting than the single-photon emission, since in a coherently driven system, the multiphoton suppression arises from quantum interferences between virtual multiphoton fluctuations and the mean field in a Poisson superposition of all number states. Here, we demonstrate how one can control the multiphoton dynamics of a two-level system by disrupting these quantum interferences through a precise and independent homodyne control of the mean field. We show that, counterintuitively, quantum fluctuations always play a major qualitative role, even and in fact especially, when their quantitative contribution is vanishing as compared to that of the mean field.<ref><u>Unlocking multiphoton emission from a single-photon source through mean-field engineering</u>., [[Sang Kyu Kim]]{{etal}} {{arXiv|2411.10441}} (2024).</ref>
+===== Joaquin Guimbao Gaspar =====
+:00-10:30
 ===== Juan Camilo López Carreño =====
+:30-11:00
 '''''Coffee break'''''
@@ Line 87: / Line 105: @@
 ===== Jesper Mørk  =====
-''Quantum noise and squeezing in nanolasers.''
+''Quantum noise and squeezing in nanolasers.'' — 11:30-12:00
 :We present a recently developed method for simulating quantum noise in nanolasers.{{cite|bundgaardnielsen23a}}{{cite|bundgaardnielsen25a}} Based on a simple stochastic interpretation of rate equations, the approach accurately reproduces quantum master equation results for few-emitter lasers and aligns with Langevin equations in macroscopic regimes. Notably, it bridges the intermediate mesoscopic regime previously inaccessible to existing models. We apply this method to analyze amplitude squeezing in nanolasers using novel cavities with extreme light confinement, which strongly enhance light-matter interaction.
 ===== Elena del Valle =====
+:00-12:30
 ===== Ahsan Nazir  =====
+:30-13:00
 ===== Владислав Шишков =====
-''Spectral theory and statistical properties of integrated single-photon sources.''
+''Spectral theory and statistical properties of integrated single-photon sources.'' — 13:00-13:30
 '''''Lunch'''''
@@ Line 101: / Line 123: @@
 ==== Afternoon Session <!-- Carlos AS-->====
 ===== Philipp Schneeweiß =====
-===== Antonio Isaac Fernandez Dominguez =====
+''Tailoring photon statistics with an atom-based two-photon interferometer'' — 15:00-15:30
+Based on Ref.&nbsp;{{onlinecite|cordier23a}}.
+===== Johannes Feist =====
+:30-16:00
+===== Lukas Hanschke =====
+:00-16:30
 ===== Francesca Marchetti =====
+:30-17:00
-''''' Coffee break'''''
+'''''Coffee break'''''
 ==== Evening Session <!-- Kai/Eduardo-->====
 ===== Jake Iles-Smith =====
-===== Joaquin Guimbao Gaspar =====
+:30-18:00
-===== Johannes Feist  =====
+===== Antonio Isaac Fernandez Dominguez =====
+:00-18:30
+===== Yajun Wang =====
+:30-19:00
 ===== Carlos Sánchez =====
+:00-19:30
+:30 ''''' Dinner '''''
 === Thursday 9 October (Day 2) ===
@@ Line 117: / Line 158: @@
 ===== Sven Höfling =====
+:00-9:30
 ===== Tim Thomay =====
-''Higher-order Fock states for sensing applications.''
+''Higher-order Fock states for sensing applications.'' — 9:30-10:00
 See Ref.&nbsp;{{onlinecite|powers25a}}.
 ===== Jacob Ngaha =====
+:00-10:30
 ===== Eduardo Zubizarreta Casalengua =====
+:30-11:00
 '''''Coffee break'''''
@@ Line 130: / Line 176: @@
 ===== Zhiliang Yuan =====
+:30-12:00
 ===== Carlos Antón Solanas =====
+:00-12:30
 ===== Sang Kyu Kim =====
+:30-13:00
 ===== Alejandro González Tudela =====
+:00-13:30
 '''''Lunch'''''
@@ Line 139: / Line 192: @@
 ===== Vincenzo D'Ambrosio =====
+:30-15:00
 ===== Alexandros Spilioti =====
+:00-15:30
+===== Natalia Armaou =====
+:30-16:00
 ===== Fabrice Laussy =====
+''Liquid time and time liquids'' — 16:00-16:30
+:The basic quantum-optical emitter—the two-level system—is already much more complicated than one could reasonably expect, and to this day, its thorough characterization remains to be completed.{{cite|zubizarretacasalengua24b}} Here, I will jump to the case of the $N$-level system, and survey the amazing phenomenology that immediately shouts out from this simplest extension of the brick of quantum optics. A first surprise is that the $N$-level system, not the two-level one, is the most suitable to implement perfect single-photon sources.{{cite|khalid24a}} Furthemore, a good single-photon source acquires features that differ considerably from those usually wanted for that purpose. For instance, instead of merely suppressing two-photon coincidences at&nbsp;$\tau=0$, a good single-photon emitter is one that develops long-time oscillations as a result of self-organizing its photon streams to all orders in photon counting, differing from the basic case in a way similar to how a liquid differs from a gas.{{cite|zubizarretacasalengua24a}} This calls for revisiting our understanding of single-photon sources, and raise fascinating questions on how they relate, in time, to exotic phase of matters.{{cite|wilczek19a}} I will also describe how such a picture extends into multiphotonics,{{cite|palomo25a}} and how one could observe such effects experimentally.{{cite|barretopadron25a}}
 ==== Closing (by Carlos Sánchez) ====
-'''''Goodbye coffee'''''
+'''''Goodbye coffee & Merienda'''''
 Participants depart
@@ Line 149: / Line 213: @@
 == Q&A(bstracts) ==
-At this occasion, we shall try to revive an old format of archiving Scientific debates: instead of publishing proceedings, we will publish the abstract and the (edited) Question & Answer sessions, which contains information nowhere else to be found.
+At this occasion, we shall try to revive an old format of archiving Scientific debates: instead of publishing proceedings, we will publish the abstract and the (edited) [[Q&A(bstracts)|Questions & Answers sessions]], which contains information nowhere else to be found.
 == References ==
 <references />