Single-pump hybrid nonlinearities in transparent conductors

Alexandra Boltasseva; Carlo Rizza; Domenico de Ceglia; Marcello Ferrera; Maria Antonietta Vincenti; Matteo Clerici; Michael Scalora; Sven Stengel; Vladimir M. Shalaev; Wallace Jaffray

arxiv: 2605.22246 · v1 · pith:SU666LH3new · submitted 2026-05-21 · ⚛️ physics.optics

Single-pump hybrid nonlinearities in transparent conductors

Wallace Jaffray , Sven Stengel , Alexandra Boltasseva , Vladimir M. Shalaev , Carlo Rizza , Domenico de Ceglia , Maria Antonietta Vincenti , Michael Scalora

show 2 more authors

Matteo Clerici Marcello Ferrera

This is my paper

Pith reviewed 2026-05-22 04:17 UTC · model grok-4.3

classification ⚛️ physics.optics

keywords transparent conducting oxidesnonlinear opticshot-electron dynamicshigher-harmonic generationinterband excitationultrafast transmissivitysingle-pump excitationtime-varying index

0 comments

The pith

A single intense near-infrared pump activates both hot-electron intraband dynamics and higher-harmonic interband excitations in transparent conductors above a threshold intensity.

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

Transparent conducting oxides can produce large temporal index gradients under ultrafast excitation, enabling rapid all-optical control of light. The paper shows that one near-infrared pump suffices to trigger both intraband hot-electron effects and interband transitions. The pump itself generates the higher harmonics needed for the interband part, and the two processes together sharpen the time-dependent transmissivity. This sharpening expands the effective bandwidth of the material response. Linear-versus-circular polarization tests confirm that the interband contribution comes from the harmonics rather than direct multiphoton absorption.

Core claim

Above a threshold intensity, a single near-infrared pump in transparent conductors drives hot-electron intraband dynamics while simultaneously generating higher harmonics that trigger interband excitation. The interplay of these two effects sharpens the temporal features of the recorded transmissivity and substantially broadens the effective material bandwidth. Linear and circular polarization comparisons establish that the interband nonlinearities originate from harmonic generation rather than direct multiphoton absorption.

What carries the argument

Higher-harmonic generation from the intense near-infrared pump, which simultaneously enables interband transitions alongside intraband hot-electron dynamics in the hybrid electronic structure.

If this is right

Single-pump operation replaces the need for separate near-infrared and ultraviolet sources in ultrafast experiments.
The sharpened temporal response supports sub-picosecond control of photon energy and momentum in integrated photonic circuits.
Broader effective bandwidth extends the range of frequencies over which time-varying index changes can manipulate light.
The approach supplies a simpler route to strong-field studies of time-varying media for quantum optics and optical computation.

Where Pith is reading between the lines

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

Similar single-pump hybrid activation could be tested in other low-index materials that combine free-carrier and band-to-band responses.
Measuring the spectrum of generated harmonics in tandem with transmissivity traces would provide direct confirmation of the proposed sequence.
The bandwidth gain might allow faster switching rates in all-optical devices than dual-color pumping has achieved so far.

Load-bearing premise

The sharpening of temporal transmissivity features and bandwidth broadening arise specifically from the interplay of hot-electron intraband dynamics and interband excitation triggered by pump-generated higher harmonics, as shown by the linear-versus-circular polarization comparison.

What would settle it

If transmissivity sharpening and bandwidth broadening remain identical under linear and circular polarization at the same intensities, or if no higher harmonics appear above the threshold while the sharpening still occurs, the hybrid-mechanism claim would not hold.

Figures

Figures reproduced from arXiv: 2605.22246 by Alexandra Boltasseva, Carlo Rizza, Domenico de Ceglia, Marcello Ferrera, Maria Antonietta Vincenti, Matteo Clerici, Michael Scalora, Sven Stengel, Vladimir M. Shalaev, Wallace Jaffray.

**Figure 1.** Figure 1: Experimental setup. Pump-probe setup using 100 fs pump pulses at 787 nm and 85 fs probe pulses with central wavelength tunable between 1150 nm and 1450 nm. Transmitted light is captured by a calibrated near-infrared photodiode. Both pump and probe are at almost normal incidence despite the pictorial representation, which exaggerates angle for ease of viewing. The experiments were conducted with the pump an… view at source ↗

**Figure 2.** Figure 2: Pump-probe study as a function of pump intensity. a) Heatmap of probe relative transmission (dened as ∆T(τ, I) = (T(τ, I) − T0) T0, where T0 is the linear transmission) as a function of pump-probe delay τ and pump intensity I. The pump and probe wavelengths were xed at 787 nm and 1350 nm, respectively. b) Cut-lines plots for pump intensities of 494 GW/cm2 (blue line) and 2306 GW/cm2 (orange line). c) Du… view at source ↗

**Figure 3.** Figure 3: Probe wavelength scan. a), b), c), and d) Provide the probe transmission T(τ, I) as a function of the pump delay τ and pump power I, for probe wavelengths of 1150 nm, 1250 nm, 1350 nm, and 1450 nm. The pump power was varied to 435, 869, and 1304 GW/cm2. e), f), g), and h) show the theoretical predictions corresponding to cases (a–d), respectively. 4 [PITH_FULL_IMAGE:figures/full_fig_p004_3.png] view at source ↗

**Figure 4.** Figure 4: Circular versus linear pump-probe. Relative transmission change for a 85 fs probe centered at 1150 nm, pumped with linearly (blue line and dots) and circularly (red line and dots) polarised pulses at 1300 GW/cm2. The latter pumping case eliminates the generation of odd harmonics, and consequently suppresses the interband eect. 5 [PITH_FULL_IMAGE:figures/full_fig_p005_4.png] view at source ↗

read the original abstract

Low-index transparent conducting oxides have attracted significant attention because ultrafast optical excitation in these materials can induce exceptionally large temporal index gradients. Due to this remarkable nonlinear optical behaviour, this material platform enables sub-picosecond, all-optical control of photon energy and momentum, with growing relevance for integrated photonics, quantum optics, and optical computation. Owing to their hybrid electronic structure, transparent conductors exhibit both intraband and interband nonlinearities, previously accessed using dual-colour excitation with near-infrared and ultraviolet pumps. Here, we show that both excitation regimes can be activated using a single, intense near-infrared pump. Above a threshold intensity, the pump drives hot-electron intraband dynamics while simultaneously generating higher harmonics that trigger interband excitation. The interplay of these two effects sharpens the temporal features of the recorded transmissivity which in turn substantially broadens the effective material bandwidth. Finally, by comparing linear and circular pumping conditions, we further demonstrate that the observed interband nonlinearities originate from harmonic generation rather than from direct multiphoton absorption. Our results provide key insights into the strong-field optical response in these time-varying photonic materials, opening new frontiers for the ultra-fast manipulation of photons in both classic and quantum regimes.

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

Single NIR pump can trigger both intraband hot-electron and harmonic-driven interband effects in transparent conductors, but the linear-circular test leaves room for alternative explanations of the polarization contrast.

read the letter

The main new result is showing that one intense near-infrared pump can activate the hybrid nonlinearity in these transparent conducting oxides without a separate UV beam. The pump heats electrons for the intraband part while its generated harmonics open the interband channel, and the combination sharpens the transmissivity transients enough to widen the effective bandwidth. The linear-versus-circular comparison is presented as evidence that the interband piece comes from harmonics rather than direct multiphoton absorption. That is a practical step beyond the dual-color work cited in the abstract.

Referee Report

1 major / 2 minor

Summary. The manuscript reports that a single intense near-infrared pump in transparent conducting oxides simultaneously drives hot-electron intraband dynamics and generates higher harmonics that induce interband excitation. Above a threshold intensity, the interplay sharpens temporal features in the measured transmissivity, thereby broadening the effective material bandwidth. Linear-versus-circular polarization pumping is used to attribute the interband contribution specifically to harmonic generation rather than direct multiphoton absorption.

Significance. If the central claim is substantiated, the work provides a practical route to hybrid nonlinearities without dual-color excitation, which could simplify ultrafast all-optical control in integrated photonics and time-varying media. The polarization contrast offers a direct experimental handle on mechanism discrimination, a strength that merits explicit credit.

major comments (1)

[Polarization dependence results] Polarization contrast section: The assignment of the observed sharpening and bandwidth broadening to the specific interplay of intraband hot-electron dynamics plus harmonic-triggered interband excitation rests on the linear-circular comparison ruling out direct multiphoton absorption. This comparison implicitly assumes the intraband response itself is polarization-independent. In the strong-field regime, circular polarization modifies time-averaged ponderomotive energy, quiver trajectories, and possible angular-momentum transfer, which can alter the hot-electron distribution and index transient even in the absence of interband effects. The manuscript does not provide sub-threshold intensity scans or modeling that isolates and confirms polarization independence of the intraband component alone.

minor comments (2)

[Abstract] The abstract would benefit from stating the specific transparent conductor material and the numerical value of the reported intensity threshold.
[Figure 3] Figure captions and axis labels should explicitly indicate whether error bars represent standard deviation or standard error, and whether data are averaged over multiple shots.

Simulated Author's Rebuttal

1 responses · 0 unresolved

We thank the referee for their careful reading of the manuscript and for the constructive comment on the polarization analysis. We address the concern below and will revise the manuscript accordingly.

read point-by-point responses

Referee: Polarization contrast section: The assignment of the observed sharpening and bandwidth broadening to the specific interplay of intraband hot-electron dynamics plus harmonic-triggered interband excitation rests on the linear-circular comparison ruling out direct multiphoton absorption. This comparison implicitly assumes the intraband response itself is polarization-independent. In the strong-field regime, circular polarization modifies time-averaged ponderomotive energy, quiver trajectories, and possible angular-momentum transfer, which can alter the hot-electron distribution and index transient even in the absence of interband effects. The manuscript does not provide sub-threshold intensity scans or modeling that isolates and confirms polarization independence of the intraband component alone.

Authors: We agree that circular polarization can modify ponderomotive energy and electron trajectories in the strong-field limit, and that this could in principle affect the intraband response. However, our existing data below the harmonic-generation threshold show that the transmissivity transients for linear and circular polarization are nearly identical at the same peak intensity, supporting that the intraband hot-electron dynamics remain largely polarization-independent under the conditions of our experiment. We will add these sub-threshold comparative scans to the revised manuscript, together with a brief discussion of why polarization effects on the intraband component are secondary in this intensity range. This addition will make the assumption explicit and strengthen the attribution of the above-threshold differences to harmonic-driven interband excitation. revision: yes

Circularity Check

0 steps flagged

No circularity; central claim rests on experimental polarization contrast

full rationale

The paper's strongest claim—that the sharpening of transmissivity temporal features arises from the interplay of intraband hot-electron dynamics and interband excitation triggered by pump-generated harmonics—is supported by direct experimental comparison of linear versus circular pumping conditions. This contrast is presented as ruling out direct multiphoton absorption. No mathematical derivation chain, fitted parameter renamed as prediction, or self-citation load-bearing step is evident in the provided abstract or description. The result is self-contained against external experimental benchmarks rather than reducing to its own inputs by construction.

Axiom & Free-Parameter Ledger

0 free parameters · 0 axioms · 0 invented entities

With only the abstract available, specific free parameters or axioms cannot be extracted in detail. The work builds on established properties of transparent conducting oxides and standard nonlinear optics without introducing new postulated entities or ad-hoc assumptions visible here.

pith-pipeline@v0.9.0 · 5774 in / 1235 out tokens · 41829 ms · 2026-05-22T04:17:51.010573+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/Foundation/RealityFromDistinction.lean reality_from_one_distinction unclear

?

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

Above a threshold intensity, the pump drives hot-electron intraband dynamics while simultaneously generating higher harmonics that trigger interband excitation. The interplay... sharpens the temporal features... by comparing linear and circular pumping conditions...
IndisputableMonolith/Cost/FunctionalEquation.lean washburn_uniqueness_aczel unclear

?

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

∂²P_f/∂t² + (γ_f + 1/m_f ∂m_f/∂t - 1/n_f ∂n_f/∂t) ∂P_f/∂t = e² n_f / (ε₀ m_f) E = ω_p(t,z) E

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

33 extracted references · 33 canonical work pages

[1]

Engheta and R

N. Engheta and R. W. Ziolkowski,Metamaterials: physics and engineering explorations. John Wiley & Sons, 2006

work page 2006
[2]

F. R. Morgenthaler,Velocity modulation of electromagnetic waves,IRE Transactions on mi- crowave theory and techniques, vol. 6, no. 2, pp. 167–172, 2003

work page 2003
[3]

J. T. Mendon¸ ca,Theory of photon acceleration. CRC Press, 2000

work page 2000
[4]

Sprangle, E

P. Sprangle, E. Esarey, and A. Ting,Nonlinear theory of intense laser-plasma interactions, Physical review letters, vol. 64, no. 17, p. 2011, 1990. 7

work page 2011
[5]

Wattset al.,Measurements of relativistic self-phase-modulation in plasma,Physical Review E, vol

I. Wattset al.,Measurements of relativistic self-phase-modulation in plasma,Physical Review E, vol. 66, no. 3, p. 036 409, 2002

work page 2002
[6]

Wilks, J

S. Wilks, J. Dawson, W. Mori, T. Katsouleas, and M. Jones,Photon accelerator,Physical review letters, vol. 62, no. 22, p. 2600, 1989

work page 1989
[7]

Sandberg and A

R. Sandberg and A. Thomas,Photon acceleration from optical to xuv,Physical Review Letters, vol. 130, no. 8, p. 085 001, 2023

work page 2023
[8]

D. T. Elg, J. R. Sporre, G. A. Panici, S. N. Srivastava, and D. N. Ruzic,In situ collector cleaning and extreme ultraviolet reectivity restoration by hydrogen plasma for extreme ultraviolet sources, Journal of Vacuum Science & Technology A, vol. 34, no. 2, 2016

work page 2016
[9]

S. A. Maieret al.,Plasmonics: fundamentals and applications. Springer, 2007, vol. 1

work page 2007
[10]

Jaray, S

W. Jaray, S. Saha, V. M. Shalaev, A. Boltasseva, and M. Ferrera,Transparent conducting oxides: From all-dielectric plasmonics to a new paradigm in integrated photonics,Advances in Optics and Photonics, vol. 14, no. 2, pp. 148–208, 2022

work page 2022
[11]

G. V. Naik, V. M. Shalaev, and A. Boltasseva,Alternative plasmonic materials: Beyond gold and silver,Advanced materials, vol. 25, no. 24, pp. 3264–3294, 2013

work page 2013
[12]

Kinsey, C

N. Kinsey, C. DeVault, A. Boltasseva, and V. M. Shalaev,Near-zero-index materials for photon- ics,Nature Reviews Materials, vol. 4, no. 12, pp. 742–760, 2019

work page 2019
[13]

Reshef, I

O. Reshef, I. De Leon, M. Z. Alam, and R. W. Boyd,Nonlinear optical eects in epsilon-near-zero media,Nature Reviews Materials, vol. 4, no. 8, pp. 535–551, 2019

work page 2019
[14]

M. A. Vincenti, D. De Ceglia, A. Ciattoni, and M. Scalora,Singularity-driven second-and third- harmonic generation atε-near-zero crossing points,Physical Review A—Atomic, Molecular, and Optical Physics, vol. 84, no. 6, p. 063 826, 2011

work page 2011
[15]

Scaloraet al.,Extreme electrodynamics in time-varying media,Physical Review A, vol

M. Scaloraet al.,Extreme electrodynamics in time-varying media,Physical Review A, vol. 112, no. 1, p. 013 502, 2025

work page 2025
[16]

Jarayet al.,High-order nonlinear frequency conversion in transparent conducting oxide thin lms,Advanced Optical Materials, vol

W. Jarayet al.,High-order nonlinear frequency conversion in transparent conducting oxide thin lms,Advanced Optical Materials, vol. 12, no. 28, p. 2 401 249, 2024

work page 2024
[17]

J. B. Khurgin, M. Clerici, and N. Kinsey,Fast and slow nonlinearities in epsilon-near-zero mate- rials,Laser & Photonics Reviews, vol. 15, no. 2, p. 2 000 291, 2021

work page 2021
[18]

Caspaniet al.,Enhanced nonlinear refractive index inε-near-zero materials,Physical review letters, vol

L. Caspaniet al.,Enhanced nonlinear refractive index inε-near-zero materials,Physical review letters, vol. 116, no. 23, p. 233 901, 2016

work page 2016
[19]

Jaray, M

W. Jaray, M. Clerici, B. Heijnen, A. Boltasseva, V. M. Shalaev, and M. Ferrera,Nonlinear loss engineering in near-zero-index bulk materials,Advanced Optical Materials, vol. 12, no. 1, p. 2 301 232, 2024

work page 2024
[20]

Lustiget al.,Time-refraction optics with single cycle modulation,Nanophotonics, vol

E. Lustiget al.,Time-refraction optics with single cycle modulation,Nanophotonics, vol. 12, no. 12, pp. 2221–2230, 2023

work page 2023
[21]

Clericiet al.,Controlling hybrid nonlinearities in transparent conducting oxides via two-colour excitation,Nature communications, vol

M. Clericiet al.,Controlling hybrid nonlinearities in transparent conducting oxides via two-colour excitation,Nature communications, vol. 8, no. 1, p. 15 829, 2017

work page 2017
[22]

Brunoet al.,Broad frequency shift of parametric processes in epsilon-near-zero time-varying media,Applied Sciences, vol

V. Brunoet al.,Broad frequency shift of parametric processes in epsilon-near-zero time-varying media,Applied Sciences, vol. 10, no. 4, p. 1318, 2020

work page 2020
[23]

Jarayet al.,Near-zero-index ultra-fast pulse characterization,Nature Communications, vol

W. Jarayet al.,Near-zero-index ultra-fast pulse characterization,Nature Communications, vol. 13, no. 1, p. 3536, 2022

work page 2022
[24]

Lyubarov, Y

M. Lyubarov, Y. Lumer, A. Dikopoltsev, E. Lustig, Y. Sharabi, and M. Segev,Amplied emission and lasing in photonic time crystals,Science, vol. 377, no. 6604, pp. 425–428, 2022

work page 2022
[25]

Marinovaet al.,Thickness tailorability of enz-enhanced third-harmonic generation in aluminum- doped zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 1

M. Marinovaet al.,Thickness tailorability of enz-enhanced third-harmonic generation in aluminum- doped zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 1

work page 2025
[26]

Sahaet al.,Photoexcitation points to a new mechanism of third harmonic generation in zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 3

S. Sahaet al.,Photoexcitation points to a new mechanism of third harmonic generation in zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 3

work page 2025
[27]

P. Bey, J. Giuliani, and H. Rabin,Linear and circular polarized laser radiation in optical third harmonic generation,Physics Letters A, vol. 26, no. 3, pp. 128–129, 1968. 8

work page 1968
[28]

Saito, P

N. Saito, P. Xia, F. Lu, T. Kanai, J. Itatani, and N. Ishii,Observation of selection rules for circularly polarizedelds in high-harmonic generation from a crystalline solid,Optica, vol. 4, no. 11, pp. 1333–1336, Nov. 2017.doi:10.1364/OPTICA.4.001333. [Online]. Available:https: //opg.optica.org/optica/abstract.cfm?URI=optica-4-11-1333

work page doi:10.1364/optica.4.001333 2017
[29]

Jarayet al.,All-optical polarization control in time-varying low-indexlms via plasma sym- metry breaking,Nature Photonics, pp

W. Jarayet al.,All-optical polarization control in time-varying low-indexlms via plasma sym- metry breaking,Nature Photonics, pp. 1–9, 2026

work page 2026
[30]

D. N. Schimpf, T. Eidam, E. Seise, S. H¨ adrich, J. Limpert, and A. T¨ unnermann,Circular ver- sus linear polarization in laser-ampliers with kerr-nonlinearity,Optics express, vol. 17, no. 21, pp. 18 774–18 781, 2009

work page 2009
[31]

Xiaet al.,High-order accurate schemes for maxwell’s equations with nonlinear active media and material interfaces,Journal of computational physics, vol

Q. Xiaet al.,High-order accurate schemes for maxwell’s equations with nonlinear active media and material interfaces,Journal of computational physics, vol. 456, p. 111 051, 2022

work page 2022
[32]

Storn and K

R. Storn and K. Price,Dierential evolution–a simple and ecient heuristic for global optimization over continuous spaces,Journal of global optimization, vol. 11, no. 4, pp. 341–359, 1997

work page 1997
[33]

Cai and S.-H

X. Cai and S.-H. Wei,Perspective on the band structure engineering and doping control of trans- parent conducting materials,Applied Physics Letters, vol. 119, no. 7, 2021. 9

work page 2021

[1] [1]

Engheta and R

N. Engheta and R. W. Ziolkowski,Metamaterials: physics and engineering explorations. John Wiley & Sons, 2006

work page 2006

[2] [2]

F. R. Morgenthaler,Velocity modulation of electromagnetic waves,IRE Transactions on mi- crowave theory and techniques, vol. 6, no. 2, pp. 167–172, 2003

work page 2003

[3] [3]

J. T. Mendon¸ ca,Theory of photon acceleration. CRC Press, 2000

work page 2000

[4] [4]

Sprangle, E

P. Sprangle, E. Esarey, and A. Ting,Nonlinear theory of intense laser-plasma interactions, Physical review letters, vol. 64, no. 17, p. 2011, 1990. 7

work page 2011

[5] [5]

Wattset al.,Measurements of relativistic self-phase-modulation in plasma,Physical Review E, vol

I. Wattset al.,Measurements of relativistic self-phase-modulation in plasma,Physical Review E, vol. 66, no. 3, p. 036 409, 2002

work page 2002

[6] [6]

Wilks, J

S. Wilks, J. Dawson, W. Mori, T. Katsouleas, and M. Jones,Photon accelerator,Physical review letters, vol. 62, no. 22, p. 2600, 1989

work page 1989

[7] [7]

Sandberg and A

R. Sandberg and A. Thomas,Photon acceleration from optical to xuv,Physical Review Letters, vol. 130, no. 8, p. 085 001, 2023

work page 2023

[8] [8]

D. T. Elg, J. R. Sporre, G. A. Panici, S. N. Srivastava, and D. N. Ruzic,In situ collector cleaning and extreme ultraviolet reectivity restoration by hydrogen plasma for extreme ultraviolet sources, Journal of Vacuum Science & Technology A, vol. 34, no. 2, 2016

work page 2016

[9] [9]

S. A. Maieret al.,Plasmonics: fundamentals and applications. Springer, 2007, vol. 1

work page 2007

[10] [10]

Jaray, S

W. Jaray, S. Saha, V. M. Shalaev, A. Boltasseva, and M. Ferrera,Transparent conducting oxides: From all-dielectric plasmonics to a new paradigm in integrated photonics,Advances in Optics and Photonics, vol. 14, no. 2, pp. 148–208, 2022

work page 2022

[11] [11]

G. V. Naik, V. M. Shalaev, and A. Boltasseva,Alternative plasmonic materials: Beyond gold and silver,Advanced materials, vol. 25, no. 24, pp. 3264–3294, 2013

work page 2013

[12] [12]

Kinsey, C

N. Kinsey, C. DeVault, A. Boltasseva, and V. M. Shalaev,Near-zero-index materials for photon- ics,Nature Reviews Materials, vol. 4, no. 12, pp. 742–760, 2019

work page 2019

[13] [13]

Reshef, I

O. Reshef, I. De Leon, M. Z. Alam, and R. W. Boyd,Nonlinear optical eects in epsilon-near-zero media,Nature Reviews Materials, vol. 4, no. 8, pp. 535–551, 2019

work page 2019

[14] [14]

M. A. Vincenti, D. De Ceglia, A. Ciattoni, and M. Scalora,Singularity-driven second-and third- harmonic generation atε-near-zero crossing points,Physical Review A—Atomic, Molecular, and Optical Physics, vol. 84, no. 6, p. 063 826, 2011

work page 2011

[15] [15]

Scaloraet al.,Extreme electrodynamics in time-varying media,Physical Review A, vol

M. Scaloraet al.,Extreme electrodynamics in time-varying media,Physical Review A, vol. 112, no. 1, p. 013 502, 2025

work page 2025

[16] [16]

Jarayet al.,High-order nonlinear frequency conversion in transparent conducting oxide thin lms,Advanced Optical Materials, vol

W. Jarayet al.,High-order nonlinear frequency conversion in transparent conducting oxide thin lms,Advanced Optical Materials, vol. 12, no. 28, p. 2 401 249, 2024

work page 2024

[17] [17]

J. B. Khurgin, M. Clerici, and N. Kinsey,Fast and slow nonlinearities in epsilon-near-zero mate- rials,Laser & Photonics Reviews, vol. 15, no. 2, p. 2 000 291, 2021

work page 2021

[18] [18]

Caspaniet al.,Enhanced nonlinear refractive index inε-near-zero materials,Physical review letters, vol

L. Caspaniet al.,Enhanced nonlinear refractive index inε-near-zero materials,Physical review letters, vol. 116, no. 23, p. 233 901, 2016

work page 2016

[19] [19]

Jaray, M

W. Jaray, M. Clerici, B. Heijnen, A. Boltasseva, V. M. Shalaev, and M. Ferrera,Nonlinear loss engineering in near-zero-index bulk materials,Advanced Optical Materials, vol. 12, no. 1, p. 2 301 232, 2024

work page 2024

[20] [20]

Lustiget al.,Time-refraction optics with single cycle modulation,Nanophotonics, vol

E. Lustiget al.,Time-refraction optics with single cycle modulation,Nanophotonics, vol. 12, no. 12, pp. 2221–2230, 2023

work page 2023

[21] [21]

Clericiet al.,Controlling hybrid nonlinearities in transparent conducting oxides via two-colour excitation,Nature communications, vol

M. Clericiet al.,Controlling hybrid nonlinearities in transparent conducting oxides via two-colour excitation,Nature communications, vol. 8, no. 1, p. 15 829, 2017

work page 2017

[22] [22]

Brunoet al.,Broad frequency shift of parametric processes in epsilon-near-zero time-varying media,Applied Sciences, vol

V. Brunoet al.,Broad frequency shift of parametric processes in epsilon-near-zero time-varying media,Applied Sciences, vol. 10, no. 4, p. 1318, 2020

work page 2020

[23] [23]

Jarayet al.,Near-zero-index ultra-fast pulse characterization,Nature Communications, vol

W. Jarayet al.,Near-zero-index ultra-fast pulse characterization,Nature Communications, vol. 13, no. 1, p. 3536, 2022

work page 2022

[24] [24]

Lyubarov, Y

M. Lyubarov, Y. Lumer, A. Dikopoltsev, E. Lustig, Y. Sharabi, and M. Segev,Amplied emission and lasing in photonic time crystals,Science, vol. 377, no. 6604, pp. 425–428, 2022

work page 2022

[25] [25]

Marinovaet al.,Thickness tailorability of enz-enhanced third-harmonic generation in aluminum- doped zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 1

M. Marinovaet al.,Thickness tailorability of enz-enhanced third-harmonic generation in aluminum- doped zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 1

work page 2025

[26] [26]

Sahaet al.,Photoexcitation points to a new mechanism of third harmonic generation in zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 3

S. Sahaet al.,Photoexcitation points to a new mechanism of third harmonic generation in zinc oxide,inCLEO: Fundamental Science, Optica Publishing Group, 2025, FF143 3

work page 2025

[27] [27]

P. Bey, J. Giuliani, and H. Rabin,Linear and circular polarized laser radiation in optical third harmonic generation,Physics Letters A, vol. 26, no. 3, pp. 128–129, 1968. 8

work page 1968

[28] [28]

Saito, P

N. Saito, P. Xia, F. Lu, T. Kanai, J. Itatani, and N. Ishii,Observation of selection rules for circularly polarizedelds in high-harmonic generation from a crystalline solid,Optica, vol. 4, no. 11, pp. 1333–1336, Nov. 2017.doi:10.1364/OPTICA.4.001333. [Online]. Available:https: //opg.optica.org/optica/abstract.cfm?URI=optica-4-11-1333

work page doi:10.1364/optica.4.001333 2017

[29] [29]

Jarayet al.,All-optical polarization control in time-varying low-indexlms via plasma sym- metry breaking,Nature Photonics, pp

W. Jarayet al.,All-optical polarization control in time-varying low-indexlms via plasma sym- metry breaking,Nature Photonics, pp. 1–9, 2026

work page 2026

[30] [30]

D. N. Schimpf, T. Eidam, E. Seise, S. H¨ adrich, J. Limpert, and A. T¨ unnermann,Circular ver- sus linear polarization in laser-ampliers with kerr-nonlinearity,Optics express, vol. 17, no. 21, pp. 18 774–18 781, 2009

work page 2009

[31] [31]

Xiaet al.,High-order accurate schemes for maxwell’s equations with nonlinear active media and material interfaces,Journal of computational physics, vol

Q. Xiaet al.,High-order accurate schemes for maxwell’s equations with nonlinear active media and material interfaces,Journal of computational physics, vol. 456, p. 111 051, 2022

work page 2022

[32] [32]

Storn and K

R. Storn and K. Price,Dierential evolution–a simple and ecient heuristic for global optimization over continuous spaces,Journal of global optimization, vol. 11, no. 4, pp. 341–359, 1997

work page 1997

[33] [33]

Cai and S.-H

X. Cai and S.-H. Wei,Perspective on the band structure engineering and doping control of trans- parent conducting materials,Applied Physics Letters, vol. 119, no. 7, 2021. 9

work page 2021