Please use this identifier to cite or link to this item: https://doi.org/10.1002/adfm.202005977
Title: Light–Matter Interaction in Quantum Confined 2D Polar Metals
Authors: Nisi, K
Subramanian, S
He, W
Ulman, KA 
El-Sherif, H
Sigger, F
Lassaunière, M
Wetherington, MT
Briggs, N
Gray, J
Holleitner, AW
Bassim, N
Quek, SY 
Robinson, JA
Wurstbauer, U
Keywords: Two-dimensional Metals
Optical Properties
Dielectric Properties
Epsilon Near-zero 39 Behavior
Half van der Waals structures
Quantum Plasmonics
Ellipsometry
First Principles 40 Calculations
2D Polar Metals
Issue Date: 1-Jan-2021
Publisher: Wiley
Citation: Nisi, K, Subramanian, S, He, W, Ulman, KA, El-Sherif, H, Sigger, F, Lassaunière, M, Wetherington, MT, Briggs, N, Gray, J, Holleitner, AW, Bassim, N, Quek, SY, Robinson, JA, Wurstbauer, U (2021-01-01). Light–Matter Interaction in Quantum Confined 2D Polar Metals. Advanced Functional Materials 31 (4) : 2005977-2005977. ScholarBank@NUS Repository. https://doi.org/10.1002/adfm.202005977
Abstract: This work is a systematic experimental and theoretical study of the in-plane dielectric functions of 2D gallium and indium films consisting of two or three atomic metal layers confined between silicon carbide and graphene with a corresponding bonding gradient from covalent to metallic to van der Waals type. k-space resolved free electron and bound electron contributions to the optical response are identified, with the latter pointing towards the existence of thickness dependent quantum confinement phenomena. The resonance energies in the dielectric functions and the observed epsilon near-zero behavior in the near infrared to visible spectral range, are dependent on the number of atomic metal layers and properties of the metal involved. A model-based spectroscopic ellipsometry approach is used to estimate the number of atomic metal layers, providing a convenient route over expensive invasive characterization techniques. A strong thickness and metal choice dependence of the light–matter interaction makes these half van der Waals 2D polar metals attractive for quantum engineered metal films, tunable (quantum-)plasmonics and nano-photonics.
Source Title: Advanced Functional Materials
URI: https://scholarbank.nus.edu.sg/handle/10635/194633
ISSN: 1616301X
16163028
DOI: 10.1002/adfm.202005977
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