Post-2000 nonlinear optical materials and measurements: data tables and best practices

Nathalie Vermeulen; Daniel Espinosa; Adam Ball; John Ballato; Philippe Boucaud; Georges Boudebs; Cecília L.A.V. Campos; Peter Dragic; Anderson S.L. Gomes; Mikko J. Huttunen; Nathaniel Kinsey; Rich Mildren; Dragomir Neshev; Lázaro A. Padilha; Minhao Pu; Ray Secondo; Eiji Tokunaga; Dmitry Turchinovich; Jingshi Yan; Kresten Yvind; Ksenia Dolgaleva; Eric W. Van Stryland

doi:10.1088/2515-7647/ac9e2f

Post-2000 nonlinear optical materials and measurements: data tables and best practices

Nathalie Vermeulen, Daniel Espinosa, Adam Ball, John Ballato, Philippe Boucaud, Georges Boudebs, Cecília L.A.V. Campos, Peter Dragic, Anderson S.L. Gomes, Mikko J. Huttunen, Nathaniel Kinsey, Rich Mildren, Dragomir Neshev, Lázaro A. Padilha, Minhao Pu, Ray Secondo, Eiji Tokunaga, Dmitry Turchinovich, Jingshi Yan, Kresten YvindKsenia Dolgaleva, Eric W. Van Stryland

Research output: Contribution to journal › Article › peer-review

Abstract

In its 60 years of existence, the field of nonlinear optics has gained momentum especially over the past two decades thanks to major breakthroughs in material science and technology. In this article, we present a new set of data tables listing nonlinear-optical properties for different material categories as reported in the literature since 2000. The papers included in the data tables are representative experimental works on bulk materials, solvents, 0D-1D-2D materials, metamaterials, fiber waveguiding materials, on-chip waveguiding materials, hybrid waveguiding systems, and materials suitable for nonlinear optics at THz frequencies. In addition to the data tables, we also provide best practices for performing and reporting nonlinear-optical experiments. These best practices underpin the selection process that was used for including papers in the tables. While the tables indeed show strong advancements in the field over the past two decades, we encourage the nonlinear-optics community to implement the identified best practices in future works. This will allow a more adequate comparison, interpretation and use of the published parameters, and as such further stimulate the overall progress in nonlinear-optical science and applications.

Original language	English (US)
Article number	035001
Journal	JPhys Photonics
Volume	5
Issue number	3
DOIs	https://doi.org/10.1088/2515-7647/ac9e2f
State	Published - Jul 2023

Keywords

THz nonlinear optics
bulk materials
fibers
low-dimensional materials
metamaterials
nonlinear optics
on-chip waveguides

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Atomic and Molecular Physics, and Optics
Electrical and Electronic Engineering

Online availability

10.1088/2515-7647/ac9e2f

Library availability

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Vermeulen, N., Espinosa, D., Ball, A., Ballato, J., Boucaud, P., Boudebs, G., Campos, C. L. A. V., Dragic, P., Gomes, A. S. L., Huttunen, M. J., Kinsey, N., Mildren, R., Neshev, D., Padilha, L. A., Pu, M., Secondo, R., Tokunaga, E., Turchinovich, D., Yan, J., ... Van Stryland, E. W. (2023). Post-2000 nonlinear optical materials and measurements: data tables and best practices. JPhys Photonics, 5(3), Article 035001. https://doi.org/10.1088/2515-7647/ac9e2f

Vermeulen, N, Espinosa, D, Ball, A, Ballato, J, Boucaud, P, Boudebs, G, Campos, CLAV, Dragic, P, Gomes, ASL, Huttunen, MJ, Kinsey, N, Mildren, R, Neshev, D, Padilha, LA, Pu, M, Secondo, R, Tokunaga, E, Turchinovich, D, Yan, J, Yvind, K, Dolgaleva, K & Van Stryland, EW 2023, 'Post-2000 nonlinear optical materials and measurements: data tables and best practices', JPhys Photonics, vol. 5, no. 3, 035001. https://doi.org/10.1088/2515-7647/ac9e2f

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title = "Post-2000 nonlinear optical materials and measurements: data tables and best practices",

abstract = "In its 60 years of existence, the field of nonlinear optics has gained momentum especially over the past two decades thanks to major breakthroughs in material science and technology. In this article, we present a new set of data tables listing nonlinear-optical properties for different material categories as reported in the literature since 2000. The papers included in the data tables are representative experimental works on bulk materials, solvents, 0D-1D-2D materials, metamaterials, fiber waveguiding materials, on-chip waveguiding materials, hybrid waveguiding systems, and materials suitable for nonlinear optics at THz frequencies. In addition to the data tables, we also provide best practices for performing and reporting nonlinear-optical experiments. These best practices underpin the selection process that was used for including papers in the tables. While the tables indeed show strong advancements in the field over the past two decades, we encourage the nonlinear-optics community to implement the identified best practices in future works. This will allow a more adequate comparison, interpretation and use of the published parameters, and as such further stimulate the overall progress in nonlinear-optical science and applications.",

keywords = "THz nonlinear optics, bulk materials, fibers, low-dimensional materials, metamaterials, nonlinear optics, on-chip waveguides",

author = "Nathalie Vermeulen and Daniel Espinosa and Adam Ball and John Ballato and Philippe Boucaud and Georges Boudebs and Campos, {Cec{\'i}lia L.A.V.} and Peter Dragic and Gomes, {Anderson S.L.} and Huttunen, {Mikko J.} and Nathaniel Kinsey and Rich Mildren and Dragomir Neshev and Padilha, {L{\'a}zaro A.} and Minhao Pu and Ray Secondo and Eiji Tokunaga and Dmitry Turchinovich and Jingshi Yan and Kresten Yvind and Ksenia Dolgaleva and {Van Stryland}, {Eric W.}",

note = "K D and D E are grateful to Roberto Morandotti and Sisira Suresh for suggesting relevant references for the tables. K D and D E acknowledge the financial support from Canada Research Chairs program and Natural Science and Engineering Council{\textquoteright}s Discovery program RGPIN-2020-03989. D T acknowledges the financial support from European Union{\textquoteright}s Horizon 2020 research and innovation programme (Grant Agreement No. 964735 EXTREME-IR), and from Deutsche Forschungsgemeinschaft (DFG) within the project 468501411–SPP2314 INTEGRATECH under the framework of the priority programme SPP2314—INTEREST. N K, A B, R S acknowledge support from Air Force Office of Scientific Research (FA9550-18-1-0151) and the National Science Foundation (1808928). A S L G and C L A V C acknowledge support from Brazilian INCT of Photonics (CNPq, CAPES, FACEPE), and Air Force Office of Scientific Research (AFOSR) under Grant FA9550-20-1-0381. R P M acknowledges funding from AFOSR FA2386-21-1-4030 and Australian Research Council LP200301594. M J H acknowledges the support of the Flagship of Photonics Research and Innovation (PREIN) funded by the Academy of Finland (Grant No. 320165). J B acknowledges support from the J. E. Sirrine Foundation. N V acknowledges the financial support from Fonds Wetenschappelijk Onderzoek (FWO) under Grants G005420N and G0F6218N (EOS-convention 30467715). P D acknowledges the U.S. Department of Defense Directed Energy Joint Transition Office (DE JTO) (N00014-17-1-2546) and the Air Force Office of Scientific Research (FA9550-16-1-0383). D N and J Y acknowledge the support by the Australian Research Council through the Centres of Excellence program (CE20010001) and NATO SPS program (OPTIMIST). M P and K Y acknowledge the financial support from Danish National Research Foundation through the Research Centre of Excellence, Silicon Photonics for Optical Communications (SPOC) (ref. DNRF123). M P also acknowledges the financial support from the European Union{\textquoteright}s Horizon 2020 research and innovation programme (Grant Agreement No. 853522 REFOCUS). P B acknowledges the French National Research Agency (Agence Nationale de la Recherche, ANR)—OPOINt project (ANR-19-CE24-0015). G B acknowledges the support from the University of Angers and from the NNN-TELECOM Program, region des Pays de la Loire, Contract No. 2015 09036.",

year = "2023",

month = jul,

doi = "10.1088/2515-7647/ac9e2f",

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T2 - data tables and best practices

AU - Vermeulen, Nathalie

AU - Espinosa, Daniel

AU - Ball, Adam

AU - Ballato, John

AU - Boucaud, Philippe

AU - Boudebs, Georges

AU - Campos, Cecília L.A.V.

AU - Dragic, Peter

AU - Gomes, Anderson S.L.

AU - Huttunen, Mikko J.

AU - Kinsey, Nathaniel

AU - Mildren, Rich

AU - Neshev, Dragomir

AU - Padilha, Lázaro A.

AU - Pu, Minhao

AU - Secondo, Ray

AU - Tokunaga, Eiji

AU - Turchinovich, Dmitry

AU - Yan, Jingshi

AU - Yvind, Kresten

AU - Dolgaleva, Ksenia

AU - Van Stryland, Eric W.

N1 - K D and D E are grateful to Roberto Morandotti and Sisira Suresh for suggesting relevant references for the tables. K D and D E acknowledge the financial support from Canada Research Chairs program and Natural Science and Engineering Council’s Discovery program RGPIN-2020-03989. D T acknowledges the financial support from European Union’s Horizon 2020 research and innovation programme (Grant Agreement No. 964735 EXTREME-IR), and from Deutsche Forschungsgemeinschaft (DFG) within the project 468501411–SPP2314 INTEGRATECH under the framework of the priority programme SPP2314—INTEREST. N K, A B, R S acknowledge support from Air Force Office of Scientific Research (FA9550-18-1-0151) and the National Science Foundation (1808928). A S L G and C L A V C acknowledge support from Brazilian INCT of Photonics (CNPq, CAPES, FACEPE), and Air Force Office of Scientific Research (AFOSR) under Grant FA9550-20-1-0381. R P M acknowledges funding from AFOSR FA2386-21-1-4030 and Australian Research Council LP200301594. M J H acknowledges the support of the Flagship of Photonics Research and Innovation (PREIN) funded by the Academy of Finland (Grant No. 320165). J B acknowledges support from the J. E. Sirrine Foundation. N V acknowledges the financial support from Fonds Wetenschappelijk Onderzoek (FWO) under Grants G005420N and G0F6218N (EOS-convention 30467715). P D acknowledges the U.S. Department of Defense Directed Energy Joint Transition Office (DE JTO) (N00014-17-1-2546) and the Air Force Office of Scientific Research (FA9550-16-1-0383). D N and J Y acknowledge the support by the Australian Research Council through the Centres of Excellence program (CE20010001) and NATO SPS program (OPTIMIST). M P and K Y acknowledge the financial support from Danish National Research Foundation through the Research Centre of Excellence, Silicon Photonics for Optical Communications (SPOC) (ref. DNRF123). M P also acknowledges the financial support from the European Union’s Horizon 2020 research and innovation programme (Grant Agreement No. 853522 REFOCUS). P B acknowledges the French National Research Agency (Agence Nationale de la Recherche, ANR)—OPOINt project (ANR-19-CE24-0015). G B acknowledges the support from the University of Angers and from the NNN-TELECOM Program, region des Pays de la Loire, Contract No. 2015 09036.

PY - 2023/7

Y1 - 2023/7

N2 - In its 60 years of existence, the field of nonlinear optics has gained momentum especially over the past two decades thanks to major breakthroughs in material science and technology. In this article, we present a new set of data tables listing nonlinear-optical properties for different material categories as reported in the literature since 2000. The papers included in the data tables are representative experimental works on bulk materials, solvents, 0D-1D-2D materials, metamaterials, fiber waveguiding materials, on-chip waveguiding materials, hybrid waveguiding systems, and materials suitable for nonlinear optics at THz frequencies. In addition to the data tables, we also provide best practices for performing and reporting nonlinear-optical experiments. These best practices underpin the selection process that was used for including papers in the tables. While the tables indeed show strong advancements in the field over the past two decades, we encourage the nonlinear-optics community to implement the identified best practices in future works. This will allow a more adequate comparison, interpretation and use of the published parameters, and as such further stimulate the overall progress in nonlinear-optical science and applications.

AB - In its 60 years of existence, the field of nonlinear optics has gained momentum especially over the past two decades thanks to major breakthroughs in material science and technology. In this article, we present a new set of data tables listing nonlinear-optical properties for different material categories as reported in the literature since 2000. The papers included in the data tables are representative experimental works on bulk materials, solvents, 0D-1D-2D materials, metamaterials, fiber waveguiding materials, on-chip waveguiding materials, hybrid waveguiding systems, and materials suitable for nonlinear optics at THz frequencies. In addition to the data tables, we also provide best practices for performing and reporting nonlinear-optical experiments. These best practices underpin the selection process that was used for including papers in the tables. While the tables indeed show strong advancements in the field over the past two decades, we encourage the nonlinear-optics community to implement the identified best practices in future works. This will allow a more adequate comparison, interpretation and use of the published parameters, and as such further stimulate the overall progress in nonlinear-optical science and applications.

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KW - bulk materials

KW - fibers

KW - low-dimensional materials

KW - metamaterials

KW - nonlinear optics

KW - on-chip waveguides

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ER -

Post-2000 nonlinear optical materials and measurements: data tables and best practices

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