Accessing the optical nonlinearity of metals with metal-dielectric photonic bandgap structures

Ryan S. Bennink; Young Kwon Yoon; Robert W. Boyd; J. E. Sipe

doi:10.1364/OL.24.001416

Accessing the optical nonlinearity of metals with metal-dielectric photonic bandgap structures

Ryan S. Bennink
, Young Kwon Yoon
, Robert W. Boyd
, J. E. Sipe

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

142 Scopus citations

Abstract

Metals typically have very large nonlinear susceptibilities (∼10⁶ times larger than those of typical dielectrics), but because they are nearly opaque their nonlinear properties are effectively inaccessible. We demonstrate numerically that a multilayer metal-dielectric structure in which the metal is the dominant nonlinear [X(3)] material can have much larger intensity-dependent changes in the complex amplitude of the transmitted beam than a bulk sample containing the same thickness of metal. For 80 nm of copper the magnitude of the nonlinear phase shift is predicted to be as much as 40 times larger for the layered copper-silica sample, and the transmission is also greatly increased. The effective nonlinear refractive-index coefficient n₂ of this composite material can be as large as (3 + 6i) × 10^-9 cm²/W, which is among the largest values for known, reasonably transmissive materials.

Original language	English
Pages (from-to)	1416-1418
Number of pages	3
Journal	Optics Letters
Volume	24
Issue number	20
DOIs	https://doi.org/10.1364/OL.24.001416
State	Published - Oct 15 1999
Externally published	Yes

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title = "Accessing the optical nonlinearity of metals with metal-dielectric photonic bandgap structures",

abstract = "Metals typically have very large nonlinear susceptibilities (∼106 times larger than those of typical dielectrics), but because they are nearly opaque their nonlinear properties are effectively inaccessible. We demonstrate numerically that a multilayer metal-dielectric structure in which the metal is the dominant nonlinear [X(3)] material can have much larger intensity-dependent changes in the complex amplitude of the transmitted beam than a bulk sample containing the same thickness of metal. For 80 nm of copper the magnitude of the nonlinear phase shift is predicted to be as much as 40 times larger for the layered copper-silica sample, and the transmission is also greatly increased. The effective nonlinear refractive-index coefficient n2 of this composite material can be as large as (3 + 6i) × 10-9 cm2/W, which is among the largest values for known, reasonably transmissive materials.",

author = "Bennink, \{Ryan S.\} and Yoon, \{Young Kwon\} and Boyd, \{Robert W.\} and Sipe, \{J. E.\}",

year = "1999",

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TY - JOUR

T1 - Accessing the optical nonlinearity of metals with metal-dielectric photonic bandgap structures

AU - Bennink, Ryan S.

AU - Yoon, Young Kwon

AU - Boyd, Robert W.

AU - Sipe, J. E.

PY - 1999/10/15

Y1 - 1999/10/15

N2 - Metals typically have very large nonlinear susceptibilities (∼106 times larger than those of typical dielectrics), but because they are nearly opaque their nonlinear properties are effectively inaccessible. We demonstrate numerically that a multilayer metal-dielectric structure in which the metal is the dominant nonlinear [X(3)] material can have much larger intensity-dependent changes in the complex amplitude of the transmitted beam than a bulk sample containing the same thickness of metal. For 80 nm of copper the magnitude of the nonlinear phase shift is predicted to be as much as 40 times larger for the layered copper-silica sample, and the transmission is also greatly increased. The effective nonlinear refractive-index coefficient n2 of this composite material can be as large as (3 + 6i) × 10-9 cm2/W, which is among the largest values for known, reasonably transmissive materials.

AB - Metals typically have very large nonlinear susceptibilities (∼106 times larger than those of typical dielectrics), but because they are nearly opaque their nonlinear properties are effectively inaccessible. We demonstrate numerically that a multilayer metal-dielectric structure in which the metal is the dominant nonlinear [X(3)] material can have much larger intensity-dependent changes in the complex amplitude of the transmitted beam than a bulk sample containing the same thickness of metal. For 80 nm of copper the magnitude of the nonlinear phase shift is predicted to be as much as 40 times larger for the layered copper-silica sample, and the transmission is also greatly increased. The effective nonlinear refractive-index coefficient n2 of this composite material can be as large as (3 + 6i) × 10-9 cm2/W, which is among the largest values for known, reasonably transmissive materials.

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DO - 10.1364/OL.24.001416

M3 - Article

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SP - 1416

EP - 1418

JO - Optics Letters

JF - Optics Letters

IS - 20

ER -

Accessing the optical nonlinearity of metals with metal-dielectric photonic bandgap structures

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