Epsilon-Near-Zero Metamaterials

Yue Li; Ziheng Zhou; Yijing He; Hao Li

doi:10.1017/9781009128339

Series: Elements in Emerging Theories and Technologies in Metamaterials

Epsilon-Near-Zero Metamaterials

Published online by Cambridge University Press: 21 December 2021

Yue Li ,

Ziheng Zhou ,

Yijing He and

Hao Li

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Yue Li: Affiliation:
Tsinghua University, Beijing
Ziheng Zhou: Affiliation:
Tsinghua University, Beijing
Yijing He: Affiliation:
Tsinghua University, Beijing
Hao Li: Affiliation:
Tsinghua University, Beijing

Summary

This Element introduces the exotic wave phenomena arising from the extremely small optical refractive index, and sheds light on the underlying mechanisms, with a primary focus on the basic concepts and fundamental wave physics. The authors reveal the exciting applications of ENZ metamaterials, which have profound impacts over a wide range of fields of science and technology. The sections are organized as follows: in Section 2, the authors demonstrate the extraordinary wave properties in ENZ metamaterials, analyzing the unique wave dynamics and the resulting effects. Section 3 is dedicated to introducing various realization methods of the ENZ metamaterials with periodic and non-periodic styles. The applications of ENZ metamaterials are discussed in Sections 4 and 5, from the perspectives of microwave engineering, optics, and quantum physics. The authors close in Section 6 by presenting an outlook on the development of ENZ metamaterials and discussing the key challenges addressed in future works.

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Keywords

epsilon-near-zero metamaterials antennas integrated circuits plasmonics

Type: Element
Information: Series: Elements in Emerging Theories and Technologies in Metamaterials

DOI: https://doi.org/10.1017/9781009128339 [Opens in a new window]

Online ISBN: 9781009128339

Publisher: Cambridge University Press

Print publication: 03 February 2022

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References

Zouhdi, S., Sihvola, A., and Arsalane, M., Advances in Electromagnetics of Complex Media and Metamaterials. Dordrecht: Springer Netherlands, 2002.CrossRef Google Scholar

Marqués, R., Martín, F., and Sorolla, M., Metamaterials with Negative Parameters. Hoboken, NJ: John Wiley & Sons, Inc., 2007.CrossRef Google Scholar

Caloz, C. and Itoh, T., Electromagnetic Metamaterials: Transmission Line Theory and Microwave Applications. Hoboken, NJ: John Wiley & Sons, Inc., 2005.CrossRef Google Scholar

Cai, W. and Shalaev, V., Optical Metamaterials. New York: Springer, 2010.CrossRef Google Scholar

Cui, T. J., Smith, D. R., and Liu, R., Metamaterials. Boston, MA: Springer, 2010.Google Scholar

Engheta, N. and Ziolkowski, R. W., Metamaterials. Hoboken, NJ: John Wiley & Sons, 2006.Google Scholar

Zheludev, N. I. and Kivshar, Y. S., From metamaterials to metadevices, Nat. Mater., 11, 11, 917–924 (2012).Google Scholar

Shaltout, A. M., Kinsey, N., Kim, J. et al., Development of Optical Metasurfaces: Emerging Concepts and New Materials, Proc. IEEE, 104, 12, 2270–2287 (2016).CrossRef Google Scholar

Liberal, I. and Engheta, N., Near-zero refractive index photonics, Nat. Photonics, 11, 3, 149–158 (2017).CrossRef Google Scholar

Reshef, O., De Leon, I., Alam, M. Z., and Boyd, R. W., Nonlinear optical effects in epsilon-near-zero media, Nat. Rev. Mater., 4, 8, 535–551 (2019).CrossRef Google Scholar

Niu, X., Hu, X., Chu, S., and Gong, Q., Epsilon-near-zero photonics: a new platform for integrated devices, Adv. Opt. Mater., 6, 10, 1–36 (2018).Google Scholar

Cheng, Q., Jiang, W. X., and Cui, T. J., Spatial power combination for omnidirectional radiation via anisotropic metamaterials, Phys. Rev. Lett., 108, 21, 2–6 (2012).CrossRef Google Scholar PubMed

Liu, F., Huang, X., and Chan, C. T., Dirac cones at k→= 0 in acoustic crystals and zero refractive index acoustic materials, Appl. Phys. Lett., 100, 7 (2012).Google Scholar

Li, Y., Zhu, K., Peng, Y. et al., Thermal meta-device in analogue of zero-index photonics, Nat. Mater., 18, 1, 48–54 (2019).CrossRef Google Scholar PubMed

Kinsey, N., DeVault, C., Boltasseva, A., and Shalaev, V. M., Near-zero-index materials for photonics, Nat. Rev. Mater., 4, 12, 742–760 (2019).Google Scholar

Ziolkowski, R. W., Propagation in and scattering from a matched metamaterial having a zero index of refraction, Phys. Rev. E, 70, 4, 046608 (2004).CrossRef Google Scholar PubMed

Silveirinha, M. and Engheta, N., Tunneling of electromagnetic energy through subwavelength channels and bends using ε-near-zero materials, Phys. Rev. Lett., 97, 15, 157403 (2006).CrossRef Google Scholar PubMed

Edwards, B., Alù, A., Young, M. E., Silveirinha, M., and Engheta, N., Experimental verification of epsilon-near-zero metamaterial coupling and energy squeezing using a microwave waveguide, Phys. Rev. Lett., 100, 3, 033903 (2008).CrossRef Google Scholar PubMed

Liu, R., Cheng, Q.. Hand, T. et al., Experimental demonstration of electromagnetic tunneling through an epsilon-near-zero metamaterial at microwave frequencies, Phys. Rev. Lett., 100, 2, 023903 (2008).CrossRef Google Scholar PubMed

Enoch, S., Tayeb, G., Sabouroux, P., Guérin, N., and Vincent, P., A Metamaterial for Directive Emission, Phys. Rev. Lett., 89, 21, 213902 (2002).CrossRef Google Scholar PubMed

Ciattoni, A., Rizza, C., and Palange, E., Extreme nonlinear electrodynamics in metamaterials with very small linear dielectric permittivity, Phys. Rev. A, 81, 4, 043839 (2010).CrossRef Google Scholar

Suchowski, H., O’Brien, K., Wong, Z. J. et al., Phase mismatch-free nonlinear propagation in optical zero-index materials, Science, 342, 6163, 1223–1226 (2013).Google Scholar

Pollard, R. J., Murphy, A., Hendren, W. R. et al., nonlocalities, Optical and additional waves in epsilon-near-zero metamaterials, Phys. Rev. Lett., 102, 12, 127405 (2009).CrossRef Google Scholar PubMed

Davoyan, A. R., Mahmoud, A. M., and Engheta, N., Optical isolation with epsilon-near-zero metamaterials, Opt. Express, 21, 3, 3279 (2013).Google Scholar

Fleury, R. and Alù, A., Enhanced superradiance in epsilon-near-zero plasmonic channels, Phys. Rev. B, 87, 20, 201101 (2013).CrossRef Google Scholar

Rotman, W., Plasma simulation by artificial dielectrics and parallel-plate media, IRE Trans. Antennas Propag., 10, 1, 82–95 (1962).Google Scholar

Sanada, A., Kimura, M., Awai, I., Caloz, C., and Itoh, T., A planar zeroth-order resonator antenna using a left-handed transmission line, Conf. Proceedings- Eur. Microw. Conf., 3, 1341–1344 (2004).Google Scholar

Moitra, P., Yang, Y., Anderson, Z. et al., Realization of an all-dielectric zero-index optical metamaterial, Nat. Photonics, 7, 10, 791–795 (2013).CrossRef Google Scholar

Huang, X., Lai, Y., Hang, Z. H., Zheng, H., and Chan, C. T., Dirac cones induced by accidental degeneracy in photonic crystals and zero-refractive-index materials, Nat. Mater., 10, 8, 582–586 (2011).Google Scholar

Li, Y., Kita, S., Muñoz, P. et et al., On-chip zero-index metamaterials, Nat. Photonics, 9, 11, 738–742 (2015).Google Scholar

Liberal, I., Mahmoud, A. M., Li, Y., Edwards, B., and Engheta, N., Photonic doping of epsilon-near-zero media, Science, 355, 6329, 1058–1062 (2017).Google Scholar

Zhou, Z., Li, Y., Li, H. et al., Substrate-integrated photonic doping for near-zero-index devices, Nat. Commun., 10, 1, 4132 (2019).Google Scholar

Engheta, N., Salandrino, A., and Alù, A., Circuit elements at optical frequencies: nanoinductors, nanocapacitors, and nanoresistors, Phys. Rev. Lett., 95, 9, 095504 (2005).Google Scholar

Engheta, N., Circuits with light at nanoscales: optical nanocircuits inspired by metamaterials, Science, 317, 5845, 1698–1702 (2007).Google Scholar

Alù, A. and Engheta, N., All optical metamaterial circuit board at the nanoscale, Phys. Rev. Lett., 103, 14, 143902 (2009).Google Scholar

Abbasi, F. and Engheta, N., Roles of epsilon-near-zero (ENZ) and mu-near-zero (MNZ) materials in optical metatronic circuit networks, Opt. Express, 22, 21, 25109 (2014).CrossRef Google Scholar PubMed

Li, Y., Liberal, I., Della Giovampaola, C., and Engheta, N., Waveguide metatronics: lumped circuitry based on structural dispersion, Sci. Adv., 2, 6, e1501790 (2016).CrossRef Google Scholar PubMed

Khurgin, J. B. and Boltasseva, A., Reflecting upon the losses in plasmonics and metamaterials, MRS Bull., 37, 8, 768–779 (2012).Google Scholar

Khurgin, J. B., How to deal with the loss in plasmonics and metamaterials, Nat. Nanotechnol., 10, 1, 2–6 (2015).Google Scholar

Johnson, P. B. and Christy, R. W., Optical constants of the noble metals, Phys. Rev. B, 6, 12, 4370–4379 (1972).Google Scholar

Silveirinha, M. and Engheta, N., Design of matched zero-index metamaterials using nonmagnetic inclusions in epsilon-near-zero media, Phys. Rev. B, 75, 7, 075119 (2007).CrossRef Google Scholar

Mahmoud, A. M. and Engheta, N., Wave–matter interactions in epsilon-and-mu-near-zero structures, Nat. Commun., 5, 1, 5638 (2014).Google Scholar

Liberal, I., Mahmoud, A. M., and Engheta, N., Geometry-invariant resonant cavities, Nat. Commun., 7, 1, 10989 (2016).CrossRef Google Scholar PubMed

Garcia-Vidal, F. J., Martin-Moreno, L., Ebbesen, T. W., and Kuipers, L., Light passing through subwavelength apertures, Rev. Mod. Phys., 82, 1, 729–787 (2010).Google Scholar

Castaldi, G., Gallina, I., Galdi, V., Alù, A., and Engheta, N., Electromagnetic tunneling through a single-negative slab paired with a double-positive bilayer, Phys. Rev. B, 83, 8, 081105 (2011).Google Scholar

Silveirinha, M. G. and Engheta, N., Theory of supercoupling, squeezing wave energy, and field confinement in narrow channels and tight bends using ε near-zero metamaterials, Phys. Rev. B, 76, 24, 245109 (2007).Google Scholar

Alù, A., Silveirinha, M. G., and Engheta, N., Transmission-line analysis of ε-Near-Zero-filled narrow channels, Phys. Rev. E, 78, 1, 016604 (2008).CrossRef Google Scholar PubMed

Marcos, J. S., Silveirinha, M. G., and Engheta, N., µ -near-zero supercoupling, Phys. Rev. B, 91, 19, 195112 (2015).CrossRef Google Scholar

Feng, H. Ma, J. Hui Shi, Q. Cheng, and T. Jun Cui, Experimental verification of supercoupling and cloaking using mu-near-zero materials based on a waveguide, Appl. Phys. Lett., 103, 2, 021908 (2013).Google Scholar

Alù, A. and Engheta, N., Light squeezing through arbitrarily shaped plasmonic channels and sharp bends, Phys. Rev. B, 78, 3, 035440 (2008).Google Scholar

Edwards, B., Alù, A., Silveirinha, M. G., and Engheta, N., Reflectionless sharp bends and corners in waveguides using epsilon-near-zero effects, J. Appl. Phys., 105, 4, 044905 (2009).CrossRef Google Scholar

Liu, L., Hu, C., Zhao, Z., and Luo, X., Multi-passband tunneling effect in multilayered Epsilon-Near-Zero Metamaterials, Opt. Express, 17, 14, 12183 (2009).Google Scholar

Vojnovic, N., Jokanovic, B., Radovanovic, M., and Mesa, F., Tunable second-order bandpass filter based on dual ENZ waveguide, 2015 9th Int. Congr. Adv. Electromagn. Mater. Microwaves Opt. METAMATERIALS 2015, September, 316–318 (2015).Google Scholar

Mitrovic, M., Jokanovic, B., and Vojnovic, N., Wideband tuning of the tunneling frequency in a narrowed epsilon-near-zero channel, IEEE Antennas Wirel. Propag. Lett., 12, 631–634 (2013).Google Scholar

Vojnovic, N., Jokanovic, B., Radovanovic, M., Medina, F., and Mesa, F., Modeling of nonresonant longitudinal and inclined slots for resonance tuning in ENZ waveguide structures, IEEE Trans. Antennas Propag., 63, 11, 5107–5113 (2015).CrossRef Google Scholar

Liu, Y., Sun, F., Yang, Y. et al., Broadband electromagnetic wave tunneling with transmuted material singularity, Phys. Rev. Lett., 125, 20, 207401 (2020).Google Scholar

Adams, D. C., Inampudi, S., Ribaudo, T. et al., Funneling light through a subwavelength aperture with epsilon-near-zero materials, Phys. Rev. Lett., 107, 13, 133901 (2011).CrossRef Google Scholar PubMed

Li, Y. and Engheta, N., Supercoupling of surface waves with ε-near-zero metastructures, Phys. Rev. B – Condens. Matter Mater. Phys., 90, 20, 201107 (2014).CrossRef Google Scholar

Li, Z., Sun, Y., Sun, H. et al., J. Phys. D. Appl. Phys., 50, 37 (2017).Google Scholar

Alu, A. and Engheta, N., Coaxial-to-waveguide matching with ε-near-zero ultranarrow channels and bends, IEEE Trans. Antennas Propag., 58, 2, 328–339 (2010).CrossRef Google Scholar

Li, Y., Plasmonic Optics: Theory and Applications (SPIE Press, 2017).CrossRef Google Scholar PubMed

West, P., Ishii, S., Naik, G. et al., Searching for better plasmonic materials. Las. Photon. Rev. 4, 6, 795–808 (2010).Google Scholar

Ordal, M., Bell, R., Alexander, R. Jr, Long, L. and Querry, M., Optical properties of fourteen metals in the infrared and far infrared: Al, Co, Cu, Au, Fe, Pb, Mo, Ni, Pd, Pt, Ag, Ti, V, and W., Appl. Opt., 24, 4493 (1985).Google Scholar

Boltasseva, A., and Atwater, H., Low-loss plasmonic metamaterials, Science, 331, 290–291 (2011).Google Scholar PubMed

Naik, G., Kim, J., and Boltasseva, A., Oxides and nitrides as alternative plasmonic materials in the optical range, Opt. Mater. Express, 1, 6, 1090–1099 (2011).Google Scholar

Vassant, S., Archambault, A., Marquier, F. et al., Epsilon-near-zero mode for active optoelectronic devices. Phys. Rev. Lett., 109, 237401 (2012).Google Scholar

Campione, S., Brener, I., and Marquier, F., Theory of epsilon-near-zero modes in ultrathin films. Phys. Rev. B, 91, 12, 121408 (2015).CrossRef Google Scholar

de Ceglia, D., Campione, S., Vincenti, M. A., Capolino, F., Scalora, M., Low-damping epsilon-near-zero slabs: nonlinear and nonlocal optical properties. Phys. Rev. B, 87, 15, 155140 (2013).CrossRef Google Scholar

Ou, J., So, J.-K., Adamo, G. et al., Ultraviolet and visible range plasmonics of a topological insulator Bi_1.5Sb_0.5Te_1.8Se_1.2, Nat. Commun., 5, 5139 (2014).Google Scholar

Giovampaola, C. and Engheta, N., Plasmonics without negative dielectrics. Phys. Rev. B, 93, 19, 195152 (2016).Google Scholar

Li, Y., Liberal, I., and Engheta, N., Structural dispersion–based reduction of loss in epsilon-near-zero and surface plasmon polariton waves, Sci. Adv., 5, eaav3764 (2019).Google Scholar

Javani, M. and Stockman, M., Real and imaginary properties of epsilon-near-zero materials. Phys. Rev. Lett., 117, 10, 107404 (2016).Google Scholar

Sun, L. and Yu, K., Strategy for designing broadband epsilon-near-zero metamaterials. J. Opt. Soc. Am., B 29, 5, 984–989 (2012).Google Scholar

Li, Z., Liu, Z., and Aydin, K., Wideband zero-index metacrystal with high transmission at visible frequencies, J. Opt. Soc. Am. B., 34, 7, D13–D17 (2017).Google Scholar

Maas, R., Parsons, J., Engheta, N., and Polman, A., Experimental realization of an epsilon-near-zero metamaterial at visible wavelengths, Nat. Photon., 7, 11, 907–912 (2013).Google Scholar

Forati, E. and Hanson, G., On the epsilon near zero condition for spatially dispersive materials, New J. Phys., 15, 12, 123027 (2013).Google Scholar

Luo, J., Chen, H., Hou, B., Xu, P., and Lai, Y., Nonlocality-induced negative refraction and subwavelength imaging by parabolic dispersions in metal–dielectric multilayered structures with effective zero permittivity, Plasmonics, 8, 2, 1095–1099 (2013).Google Scholar

Shen, L., Yang, T., and Chau, Y., 50/50 beam splitter using a one-dimensional metal photonic crystal with parabolalike dispersion, Appl. Phys. Lett., 90, 25, 251909 (2007).Google Scholar

Silveirinha, M., and Belov, P., Spatial dispersion in lattices of split ring resonators with permeability near zero, Phys. Rev., B 77, 23, 233104 (2008).CrossRef Google Scholar

Moitra, P., Yang, Y., Anderson, Z. et al., Realization of an all-dielectric zero-index optical metamaterial, Nature Photon., 7, 10, 791–795 (2013).Google Scholar

Zhou, Y., He, X. T., Zhao, F. L., and Dong, J. W., Proposal for achieving in-plane magnetic mirrors by silicon photonic crystals, Opt. Lett., 41, 10, 2209–2212 (2016).Google Scholar

Luo, J., and Lai, Y., Epsilon-near-zero or mu-near-zero materials composed of dielectric photonic crystals, Sci. China Inf. Sci., 56, 12, 1–10 (2013).Google Scholar

Iizuka, H., and Engheta, N., Antireflection structure for an effective refractive index near-zero medium in a two-dimensional photonic crystal, Phys. Rev. B, 90, 11, 115412 (2014).Google Scholar

Wu, Y., A semi-Dirac point and an electromagnetic topological transition in a dielectric photonic crystal, Opt Express., 22, 1906–17, 2014.Google Scholar

Lin, Z., Christakis, L., Li, Y. et al., Topology-optimized dual-polarization Dirac cones, Phys. Rev. B, 97, 08, 081408 (2018).Google Scholar

Minkov, M., Williamson, I., Xiao, M., and Fan, S., Zero-index bound states in the continuum, Phys. Rev. Lett., 121, 26, 263901 (2018).Google Scholar

Tang, H., DeVault, C., Camayd-Muñoz, S. et al., Low-loss zero-index materials, Nano Lett., 21, 2, 914–920 (2021).Google Scholar

Dong, T., Liang, J., Camayd-Muñoz, S. et al., Ultra-low-loss on-chip zero-index materials, Light-Sci. Appl., 10, 1, 1–9 (2021).Google Scholar

Selvanayagam, M. and Eleftheriades, G., Negative-refractive-index transmission lines with expanded unit cells, IEEE Trans. Antennas Propag., 56, 11, 3592–3596 (2008).Google Scholar

Jiang, H., Liu, W., Yu, K. et al., Experimental verification of loss-induced field enhancement and collimation in anisotropic μ-near-zero metamaterials, Phys. Rev. B, 91, 4, 045302 (2015).CrossRef Google Scholar

Li, Y., Jiang, H. T., Liu, W. W. et al., Experimental realization of subwavelength flux manipulation in anisotropic near-zero index metamaterials, Europhys. Lett., 113, 5, 57006 (2016).Google Scholar

Silveirinha, M., Alù, A., and Engheta, N., Parallel-plate metamaterials for cloaking structures, Phys. Rev. E, 75, 3, 036603-16 (2007).Google Scholar

Pozar, D. M., Microwave Engineering, 4th ed. (John Wiley & Sons, Inc., New York, 2012).Google Scholar

Cassivi, Y., Perregrini, L., Arioni, P. et al., Dispersion characteristics of substrate integrated rectangular waveguide, IEEE Microw. Wireless Compon. Lett., 12, 9, 333–335 (2002).Google Scholar

Vesseur, E., Coenen, T., Caglayan, H., Engheta, N., and Polman, A., Experimental verification of n=0 structures for visible light, Physical Review Letters, 110, 1, 013902 (2013).Google Scholar

Reshef, O., Camayd-Muñoz, P., Vulis, D. et al., Direct observation of phase-free propagation in a silicon waveguide, ACS Photonics, 4, 10, 2385–2389 (2017).Google Scholar

Luo, J., Lu, W., Hang, Z. et al., Phys. Rev. Lett., 112, 7, 073903 (2014).Google Scholar

Ma, H. F., Shi, J. H., Cheng, Q., and Cui, T. J., Experimental verification of supercoupling and cloaking using mu-near-zero materials based on a waveguide, Appl. Phys. Lett., 103, 2, 021908 (2013).Google Scholar

Luo, J., Xu, P., Chen, H. et al., Realizing almost perfect bending waveguides with anisotropic epsilon-near-zero metamaterials, Appl. Phys. Lett., 100, 22, 221903 (2012).Google Scholar

Luo, J., and Lai, Y., Anisotropic zero-index waveguide with arbitrary shapes, Sci. Rep., 4, 1, 5875 (2014).Google Scholar

Ji, W., Luo, J., and Lai, Y., Extremely anisotropic epsilon-near-zero media in waveguide metamaterials, Opt. Express, 27, 14, 19463–19473 (2019).CrossRef Google Scholar PubMed

Shalin, A. S., Ginzburg, P., Orlov, A. A. et al., Scattering suppression from arbitrary objects in spatially dispersive layered metamaterials, Phys. Rev. B, 91, 12, 125426 (2015).Google Scholar

Luo, J., Xu, P., Gao, L., Lai, Y., and Chen, H., Manipulate the transmissions using index-near-zero or epsilon-near-zero metamaterials with coated defects, Plasmonics, 7, 2, 353–358 (2012).Google Scholar

Wang, T., Luo, J., Gao, L., Xu, P., and Lai, Y., Equivalent perfect magnetic conductor based on epsilon-near-zero media, Appl. Phys. Lett., 104, 21, 211904 (2014).Google Scholar

Jin, Y., and He, S. L., Enhancing and suppressing radiation with some permeability-near-zero structures, Opt. Express, 18, 16, 16587–16593 (2010).Google Scholar

Hao, J., Yan, W., and Qiu, M., Super-reflection and cloaking based on zero index metamaterial, Appl. Phys. Lett., 96, 10, 101109 (2010).Google Scholar

Nguyen, V. C., Chen, L., and Halterman, K., Total transmission and total reflection by zero index metamaterials with defects, Phys. Rev. Lett., 105, 23, 233908 (2010).Google Scholar

Xu, Y., and Chen, H., Total reflection and transmission by epsilon-near-zero metamaterials with defects, Appl. Phys. Lett., 98, 11, 113501 (2011).CrossRef Google Scholar

Wang, T., Luo, J., Gao, L., Xu, P., and Lai, Y., Hiding objects and obtaining Fano resonances in index-near-zero and epsilon-near-zero metamaterials with Bragg-fiber-like defects, J. Opt. Soc. Am. B, 30, 7, 1878–1884 (2013).Google Scholar

Luo, J., Hang, Z., Chan, C., and Lai, Y., Unusual percolation threshold of electromagnetic waves in double-zero medium embedded with random inclusions, Laser Photonics Rev., 9, 5, 523–529 (2015).Google Scholar

Luo, J., Liu, B., Hang, Z., and Lai, Y., Coherent Perfect Absorption via Photonic Doping of Zero-Index Media, Laser Photonics Rev., 12, 8, 1800001 (2018).Google Scholar

Luo, J., Li, J., and Lai, Y., Electromagnetic impurity-immunity induced by parity-time symmetry, Phys. Rev. X, 8, 3, 031035 (2018).Google Scholar

Liberal, I., Li, Y., and Engheta, N., Reconfigurable epsilon-near-zero metasurfaces via photonic doping, Nanophotonics, 7, 6, 1117–1127 (2018).Google Scholar

Coppolaro, M., Moccia, M., Castaldi, G., Engheta, N., and Galdi, V., Non-Hermitian doping of epsilon-near-zero media, Proceedings of the National Academy of Sciences, 117, 25, 13921 (2020).Google Scholar

Malléjac, M., Merkel, A., Tournat, V., Groby, J.-P., and Romero-García, V., Doping of a plate-type acoustic metamaterial, Phys. Rev. B, 102, 6, 060302 (2020).Google Scholar

Sanada, A., Kimura, M., Awai, I., Caloz, C., and Itoh, T., A planar zeroth-order resonator antenna using a left-handed transmission line, 34th European Microwave Conference, 1341–1344 (2004).Google Scholar

Kim, J., Kim, G., Seong, W., and Choi, J., A tunable internal antenna with an epsilon negative zeroth order resonator for DVB-H Service, IEEE Trans. Antennas Propag., 57, 12, 4014–4017 (2009).Google Scholar

Mitra, D., Ghosh, B., Sarkhel, A., and Bhadra Chaudhuri, S. R., A miniaturized ring slot antenna design with enhanced radiation characteristics, IEEE Trans. Antennas Propag., 64, 1, 300–305 (2016).Google Scholar

Jahani, S., Rashed-Mohassel, J., and Shahabadi, M., Miniaturization of circular patch antennas using MNG metamaterials, , IEEE Antennas Wireless Propag. Lett., 9, 1194–1196 (2010).Google Scholar

Li, J., Salandrino, A., and Engheta, N., Shaping light beams in the nanometer scale: a Yagi-Uda nanoantenna in the optical domain. Phys. Rev. B., 76, 24, 245403 (2007).Google Scholar

Xiong, J., Lin, X., Yu, Y. et al., Novel flexible dual-frequency broadside radiating rectangular patch antennas based on complementary planar ENZ or MNZ metamaterials, IEEE Trans. Antennas Propag., 60, 8, 3958–3961 (2012).CrossRef Google Scholar

Soric, J. C., Engheta, N., Maci, S., and Alu, A., Omnidirectional metamaterial antennas based on ε-near-zero channel matching, IEEE Trans. Antennas Propag., 61, 1, 33–44 (2013).Google Scholar

Park, J., Ryu, Y., Lee, J., and Lee, J., Epsilon negative zeroth-order resonator antenna, IEEE Trans. Antennas Propag., 55, 12, 3710–3712 (2007).Google Scholar

Zhou, Z. and Li, Y., Effective epsilon-near-zero (ENZ) antenna based on transverse cutoff mode, IEEE Trans. Antennas Propag., 67, 4, 2289–2297, (2019).Google Scholar

Zhou, Z. and Li, Y., A photonic-doping-inspired SIW antenna with length-invariant operating frequency, IEEE Trans. Antennas Propag., 68, 7, 5151–5158 (2020).Google Scholar

Hu, Z., Chen, C., Zhou, Z., and Li, Y., An epsilon-near-zero-inspired PDMS substrate antenna with deformation-insensitive operating frequency, IEEE Antennas Wireless Propag. Lett., 19, 9, 1591–1595 (2020).Google Scholar

Lovat, G., Burghignoli, P., Capolino, F., Jackson, D. R., and Wilton, D. R., Analysis of directive radiation from a line source in a metamaterial slab with low permittivity, IEEE Trans. Antennas Propag., 54, 3, 1017–1030 (2006).Google Scholar

Enoch, S., Tayeb, G., Sabouroux, P., Guérin, N., and Vincent, P., A metamaterial for directive emission, Phys. Rev. Lett., 89, 21, 213902 (2002).Google Scholar

Forati, E., Hanson, G. W., and Sievenpiper, D. F., an epsilon-near-zero total-internal-reflection metamaterial antenna, IEEE Trans. Antennas Propag., 63, 5, 1909–1916 (2015).Google Scholar

Memarian, M. and Eleftheriades, G., Dirac leaky-wave antennas for continuous beam scanning from photonic crystals. Nat. Commun., 6, 5855 (2015).CrossRef Google Scholar PubMed

Dorrah, A. H. and Eleftheriades, G. V., Pencil-beam single-point-fed Dirac leaky-wave antenna on a transmission-line grid, IEEE Antennas Wireless Propag. Lett., 16, 545–548 (2017).CrossRef Google Scholar

Yang, J., Francescato, Y., Maier, S., Mao, F., and Huang, M., Mu and epsilon near zero metamaterials for perfect coherence and new antenna designs, Opt. Express, 22, 8, 9107–9114 (2014).Google Scholar

Engheta, N., Papas, C., and Elachi, C., Radiation patterns of interfacial dipole antennas, Radio Sci., 17, 6, 1557–1566 (1982).Google Scholar

Mitra, D., Sarkhel, A., Kundu, O., and Chaudhuri, S. R. B., Design of compact and high directive slot antennas using grounded metamaterial slab, IEEE Antennas Wireless Propag. Lett., 14, 811–814 (2015).Google Scholar

Dadgarpour, A., Sharifi Sorkherizi, M., and Kishk, A. A., High-efficient circularly polarized magnetoelectric dipole antenna for 5G applications using dual-polarized split-ring resonator lens, IEEE Trans. Antennas Propag., 65, 8, 4263–4267 (2017).Google Scholar

Kim, J. et al. Role of epsilon-near-zero substrates in the optical response of plasmonic antennas, Optica, 3, 3, 339–346 (2016).Google Scholar

A. Alù, M. G. Silveirinha, A. Salandrino, and Engheta, N., Epsilon-near-zero metamaterials and electromagnetic sources: tailoring the radiation phase pattern, Phys. Rev. B, 75, 15, 155410 (2007).Google Scholar

Sun, L., Feng, S., and Yang, X., Loss enhanced transmission and collimation in anisotropic epsilon-near-zero metamaterials, Appl. Phys. Lett., 101, 24, 241101 (2012).Google Scholar

Feng, S., Loss-induced omnidirectional bending to the normal in ε-near-zero metamaterials, Phys. Rev. Lett., 108, 19, 193904 (2012).Google Scholar

Wang, B. and Huang, K., Shaping the radiation pattern with MU and epsilon-near-zero metamaterials, Progress in Electromagnetics Research, 106, 107–119 (2010).Google Scholar

Navarro-Cía, M., Beruete, M., Campillo, I., and Sorolla, M., Enhanced lens by ε and μ near-zero metamaterial boosted by extraordinary optical transmission, Phys. Rev. B, 83, 11, 115112 (2011).Google Scholar

Li, D., Szabo, Z., Qing, X., Li, E., and Chen, Z. N., A high gain antenna with an optimized metamaterial inspired superstrate, IEEE Trans. Antennas Propag., 60, 12, 6018–6023 (2012).Google Scholar

Ramaccia, D., Scattone, F., Bilotti, F., and Toscano, A., Broadband compact horn antennas by using EPS-ENZ metamaterial lens, IEEE Trans. Antennas Propag., 61, 6, 2929–2937 (2013).Google Scholar

Navarro-Cía, M., Beruete, M., Sorolla, M., and Engheta, N., Lensing system and Fourier transformation using epsilon-near-zero metamaterials, Phys. Rev. B, 86, 16, 165130 (2012).Google Scholar

Pacheco-Peña, V., Torres, V., Orazbayev, B. et al., Mechanical 144 GHz beam steering with all-metallic epsilon-near-zero lens antenna, Appl. Phys. Lett., 105, 24, 243503 (2014).Google Scholar

Soric, J. C. and Alù, A., Longitudinally independent matching and arbitrary wave patterning using ε-near-zero channels, IEEE Trans. Microw. Theory Techn., 63, 11, 3558–3567 (2015).Google Scholar

Soric, J. C. and Alù, A., Radiation patterning enabled by ε-near-zero reconfigurable metamaterial lenses, 2014 IEEE Antennas and Propagation Society International Symposium (APSURSI), 175–176 (2014).Google Scholar

Cheng, Q., Jiang, W., and Cui, T. J. , Radiation of planar electromagnetic waves by a line source in anisotropic metamaterials, J. Phys. D: Appl. Phys., 43, 33, 335406 (2010).Google Scholar

Dadgarpour, A., Sorkherizi, M. S., Denidni, T. A., and Kishk, A. A., Passive beam switching and dual-beam radiation slot antenna loaded with ENZ medium and excited through ridge gap waveguide at millimeter-waves, IEEE Trans. Antennas Propag., 65, 1, 92–102 (2017).Google Scholar

Castaldi, G., Savoia, S., Galdi, V., Alù, A., and Engheta, N., Analytical study of subwavelength imaging by uniaxial epsilon-near-zero metamaterial slabs, Phys. Rev. B, 86, 11, 115123 (2012).Google Scholar

Pacheco-Peña, V., Engheta, N., Kuznetsov, S., Gentselev, A., and Beruete, M., Experimental realization of an epsilon-near-zero graded-index metalens at terahertz frequencies, Phys. Rev. Applied, 8, 3, 034036 (2017).CrossRef Google Scholar

Jin, Y., Xiao, S., Asger Mortensen, N., and He, S., Arbitrarily thin metamaterial structure for perfect absorption and giant magnification, Opt. Express, 19, 12, 11114–11119 (2011).Google Scholar

Zhong, S., Ma, Y., and He, S., Perfect absorption in ultrathin anisotropic ε-near-zero metamaterials, Appl. Phys. Lett., 105, 2, 023504 (2014).Google Scholar

Park, J., Kang, J. H., Liu, X., and Brongersma, M. L., Electrically tunable Epsilon-Near-Zero (ENZ) metafilm absorbers, Sci Rep., 5, 15754 (2015).Google Scholar

Kato, Y., Morita, S., Shiomi, H., and Sanada, A., Ultrathin perfect absorbers for normal incident waves using Dirac cone metasurfaces with critical external coupling, IEEE Microw. Wireless Compon. Lett., 30, 4, 383–386 (2020).Google Scholar

Anopchenko, A., Tao, L., Arndt, C., and Lee, H. W. H., Field-effect tunable and broadband epsilon-near-zero perfect absorbers with deep subwavelength thickness, ACS Photonic., 5, 7, 2631 (2018).Google Scholar

Powell, D. A., Alù, A., Edwards, B. et al., Nonlinear control of tunneling through an epsilon-near-zero channel, Phys. Rev. B, 79, 24, 245135(2009).Google Scholar

Vojnović, N., Jokanović, B., Mitrović, M., Mesa, F., and Medina, F., Tuning ZOR in ENZ waveguide using a single longitudinal slot and equivalent circuit parameter extraction, 2014 8th International Congress on Advanced Electromagnetic Materials in Microwaves and Optics, 283–285 (2014).Google Scholar

He, Y., Li, Y., Zhu, L. et al., Waveguide dispersion tailoring by using embedded impedance surfaces, Phys. Rev. Applied, 10, 6, 064024 (2018).Google Scholar

He, Y., Li, Y., Zhou, Z. et al., Wideband epsilon-near-zero supercoupling control through substrate-integrated impedance surface, Adv. Theory Simul., 2, 8, 1900059 (2019).Google Scholar

string-name>Alù, A. and Engheta, N., Dielectric sensing in ε-near-zero narrow waveguide channels, Phys. Rev. B, 78, 4, 045102 (2008).CrossRef Google Scholar

Lobato-Morales, H., Murthy, D. V. B., Corona-Chavez, A. et al., Permittivity measurements at microwave frequencies using Epsilon-Near-Zero (ENZ) tunnel structure, IEEE Trans. Microw. Theory Techn., 59, 7, 1863–1868 (2011).Google Scholar

Corona-Chavez, A., Murthy, D. V. B., and Olvera-Cervantes, J. L., Novel microwave filters based on epsilon near zero waveguide tunnels, Microw. Optical Technol. Lett., 53, 8, 1706–1710 (2011).Google Scholar

Radovanovic, M. and Jokanovic, B., Dual-band filter inspired by ENZ waveguide, IEEE Microw. Wireless Compon. Lett., 27, 6, 554–556 (2017).Google Scholar

Zhou, Z., Li, Y., Nahvi, E. et al., Phys. Rev. Applied, 13, 3, 034005 (2020).Google Scholar

Wang, Y., Xu, P., and Qin, Y., Optical-phase demodulation using zero-index metamaterials, Opt. Lett., 40, 13, 3157–3160 (2015).Google Scholar

Liberal, I., and Engheta, N., Multiqubit subradiant states in N-port waveguide devices: ε-and-μ-near-zero hubs and nonreciprocal circulators, Phys. Rev. A, 97, 2, 022309 (2018).Google Scholar

Zhou, Z. and Li, Y., N-port equal/unequal-split power dividers using epsilon-near-zero metamaterials, IEEE Trans. Microw. Theory Techn., 69, 3, 1529–1537 (2021).Google Scholar

Silveirinha, M., Trapping light in open plasmonic nanostructures, Phys. Rev. A, 89, 2, 023813(2014).Google Scholar

Liberal, I., and Engheta, N., Nonradiating and radiating modes excited by quantum emitters in open epsilon-near-zero cavities, Sci. Adv., 2, 10, e1600987 (2016).Google Scholar

Li, L., Zhang, J., Wang, C., Zheng, N., and H. Yin, Optical bound states in the continuum in a single slab with zero refractive index, Phys. Rev. A, 96, 1, 013801 (2017).Google Scholar

Lannebère, S., and Silveirinha, M., Optical meta-atom for localization of light with quantized energy, Nat Commun., 6, 8766 (2015).Google Scholar

Huang, J., Zhang, X., Zhang, L., and Zhang, J., General model of optical frequency conversion in homogeneous media: application to second-harmonic generation in an ε-near-zero waveguide, Phys. Rev. A, 96, 1, 013836 (2017).Google Scholar

Ciattoni, A., Rizza, C., and Palange, E., Extreme nonlinear electrodynamics in metamaterials with very small linear dielectric permittivity, Phys. Rev. A, 81, 4, 043839 (2010).Google Scholar

Argyropoulos, C., Chen, P. Y., D’Aguanno, G., Engheta, N., and Alù, A., Boosting optical nonlinearities in ε-near-zero plasmonic channels, Phys. Rev. B, 85, 4, 045129 (2012).Google Scholar

Yang, Y., Lu, J., Manjavacas, A., et al. High-harmonic generation from an epsilon-near-zero material, Nat. Phys., 15, 1022–1026 (2019).Google Scholar

Capretti, A., Wang, Y., Engheta, N., and Negro, L., Enhanced third-harmonic generation in Si-compatible epsilon-near-zero indium tin oxide nanolayers, Opt. Lett., 40, 7, 1500–1503 (2015).Google Scholar

Vincenti, M. A., Kamandi, M., de Ceglia, D. et al., Second-harmonic generation in longitudinal epsilon-near-zero materials, Phys. Rev. B, 96, 4, 045438 (2017).Google Scholar

Alam, M. Z., De Leon, I., and Boyd, R. W., Large optical nonlinearity of indium tin oxide in its epsilon-near-zero region, Science, 352, 6287, 795–797 (2016).Google Scholar

Kinsey, N., DeVault, C., Kim, J. et al., Epsilon-near-zero Al-doped ZnO for ultrafast switching at telecom wavelengths, Optica, 2, 7, 616–622 (2015).Google Scholar

Guo, Q., Cui, Y., Yao, Y. et al., A solution-processed ultrafast optical switch based on a nanostructured epsilon-near-zero medium, Adv. Mater., 29, 27, 1700754 (2017).Google Scholar

Tanabe, T., Notomi, M., Mitsugi, S., Shinya, A., and Kuramochi, E., Fast bistable all-optical switch and memory on a silicon photonic crystal on-chip, Opt. Lett., 30, 19, 2575–2577 (2005).Google Scholar

Belov, P. A., Marqués, R., Maslovski, S. I. et al., Strong spatial dispersion in wire media in the very large wavelength limit, Phys. Rev. B, 67, 11, 113103 (2003).Google Scholar

Engheta, N., From RF circuits to optical nanocircuits, IEEE Microw. Mag., 13, 4, 100–113, May–June (2012).Google Scholar

Engheta, N., Taming light at the nanoscale, Phys. World, 13, 9, 31–34 (2010).Google Scholar

Edwards, B. and Engheta, N., Experimental verification of displacement-current conduits in metamaterials-inspired optical circuitry, Phys. Rev. Lett., 108, 19, 193902 (2012).Google Scholar

Alù, A., Young, M. E., and Engheta, N., Design of nanofilters for optical nanocircuits, Phys. Rev. B, 77, 14, 144107 (2008).Google Scholar

Li, Y., Liberal, I., and Engheta, N., Dispersion synthesis with multi-ordered metatronic filters, Opt. Express, 25, 3, 1937–1948 (2017).Google Scholar

Li, Y. and Zhang, Z., Experimental verification of guided-wave lumped circuits using waveguide metamaterials, Phy. Rev. Appl., 9, 4, 044024 (2018).Google Scholar

Dominguez, O., Nordin, L., Lu, J. et al., Monochromatic multimode antennas on epsilon‐near‐zero materials, Adv. Opt. Mater., 7, 10, 1800826 (2019).Google Scholar

Chai, Z., Hu, X., Wang, F. et al., Ultrafast on-chip remotely-triggered all-optical switching based on epsilon-near-zero nanocomposites, Laser Photonics Rev., 11, 5, 1700042 (2017).Google Scholar

Wu, Y., Hu, X., Wang, F. et al., Ultracompact and unidirectional on-chip light source based on epsilon-near-zero materials in an optical communication range, Phys. Rev. Applied, 12, 5, 054021 (2019).Google Scholar

Feng, S., and Halterman, K., Coherent perfect absorption in epsilon-near-zero metamaterials, Phys. Rev. B, 86, 16, 165103 (2012).Google Scholar

Luo, J., Li, S., Hou, B., and Lai, Y., Unified theory for perfect absorption in ultrathin absorptive films with constant tangential electric or magnetic fields, Phys. Rev. B, 90, 16, 165128 (2014).Google Scholar

Wang, D., Luo, J., Sun, Z., and Lai, Y., Transforming zero-index media into geometry-invariant coherent perfect absorbers via embedded conductive films, Opt. Express, 29, 4, 5247 (2021).Google Scholar

Feng, S., Loss-induced omnidirectional bending to the normal in ϵ-near-zero metamaterials, Phys. Rev. Lett., 108, 19, 193904 (2012).Google Scholar

Fedorov, V. Y., and Nakajima, T., All-angle collimation of incident light in mu-near-zero metamaterials, Opt. Express, 21, 23, 27789–27795 (2013).Google Scholar

Alù, A. and Engheta, N., Boosting molecular fluorescence with a plasmonic nanolauncher. Phys. Rev. Lett., 103, 4, 043902 (2009).Google Scholar

Sokhoyan, R. and Atwater, H. A., Quantum optical properties of a dipole emitter coupled to an ɛ-near-zero nanoscale waveguide, Opt. Express, 21, 26, 32279–32290 (2013).Google Scholar

Liberal, I. and Engheta, N., Zero-index structures as an alternative platform for quantum optics, PNAS, 114, 5, 822–827 (2017).Google Scholar

Biehs, S.-A. and Agarwal, G. S., Qubit entanglement across ɛ-near-zero media, Phys. Rev. A, 96, 2, 022308 (2017)Google Scholar

Vertchenko, L., N. Akopian, and Lavrinenko, A. V., Epsilon-near-zero grids for on-chip quantum networks. Sci. Rep., 9, 6053 (2019)Google Scholar

Rodriguez-Fortuo, F. J., Vakil, A., and Engheta, N., Electric levitation using ɛ -near-zero metamaterials. Phys. Rev. Lett., 112, 3, 033902 (2014).Google Scholar

Liberal, I. and Engheta, N., Manipulating thermal emission with spatially static fluctuating fields in arbitrarily shaped epsilon-near-zero bodies, PNAS, 115, 12, 2878–2883 (2018).Google Scholar

Liberal, I., Lobet, M., Li, Y., and Engheta, N., Near-zero-index media as electromagnetic ideal fluids, PNAS, 117, 39, 24050–24054 (2020).Google Scholar

Chu, H. C., Li, Q., Liu, B. et al., A hybrid invisibility cloak based on integration of transparent metasurfaces and zero-index materials, Light: Science & Applications, 7, 50 (2018).Google Scholar

Sun, L., Gao, J., and Yang, X., Broadband epsilon-near-zero metamaterials with steplike metal–dielectric multilayer structures, Phys. Rev. B, 87, 16, 165134 (2013).Google Scholar

Sun, L., Yu, K. W., and Wang, G. P., Design anisotropic broadband ε-near-zero metamaterials: rigorous use of Bergman and Milton spectral representations, Phys. Rev. Applied, 9, 6, 064020 (2018).Google Scholar

Lucarini, V., Saarinen, J. J., Peiponen, K.-E., and Vartiainen, E. M., Kramers–Kronig relations in optical materials research (Springer, 2005).Google Scholar

Zangeneh-Nejad, F., Sounas, D. L., Alù, A. et al. Analogue computing with metamaterials. Nat. Rev. Mater., 6, 207–225 (2021).Google Scholar

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