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Autori principali: Cao, Lei, Meng, Fanqi, Özdemir, Esra, Loth, Yannik, Richter, Merle, Wigger, Anna Katharina, Sosa, Maira Pérez, Jumaah, Alaa Jabbar, Al-Daffaie, Shihab, Bolívar, Peter Haring, Roskos, Hartmut G.
Natura: Preprint
Pubblicazione: 2023
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Accesso online:https://arxiv.org/abs/2311.14493
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author Cao, Lei
Meng, Fanqi
Özdemir, Esra
Loth, Yannik
Richter, Merle
Wigger, Anna Katharina
Sosa, Maira Pérez
Jumaah, Alaa Jabbar
Al-Daffaie, Shihab
Bolívar, Peter Haring
Roskos, Hartmut G.
author_facet Cao, Lei
Meng, Fanqi
Özdemir, Esra
Loth, Yannik
Richter, Merle
Wigger, Anna Katharina
Sosa, Maira Pérez
Jumaah, Alaa Jabbar
Al-Daffaie, Shihab
Bolívar, Peter Haring
Roskos, Hartmut G.
contents Designing terahertz sensors with high sensitivity to detect nanoscale thin films and single biomolecule presents a significant challenge, and addressing these obstacles is crucial for unlocking their full potential in scientific research and advanced applications. This work presents a strategy for the design optimization of metamaterial sensors employed in the detection of small amounts of dielectric materials. The sensors usually utilize the shift of the resonance frequency as an indicator of the presence of the analyte. The amount of shifting depends on intrinsic properties (electric field distribution, quality factor, and mode volume) of the bare cavity, as well as the overlap volume of its high-electric-field zone(s) and the analyte. Guided by the simplified dielectric perturbation theory, interdigitated electric split-ring resonators (ID-eSRR) are devised to significantly enhance the detection sensitivity for thin-film analytes compared to eSRRs without interdigitated fingers in the SRR gap region. The fingers of the ID-eSRR metamaterial sensor redistribute the electric field, creating strongly localized field enhancements that substantially boost the interaction with the analyte. Additionally, the periodic change of the orientation of the inherent anti-phase electric field in the interdigitated structure reduces radiation loss, leading to a higher Q-factor. Experiments with e-beam-fabricated ID-eSRR sensors operating at around 300 GHz demonstrate a remarkable frequency shift of 33.5 GHz upon deposition of a SiO2 layer with a thickness of 150 nm as an analyte simulant. The figure of merit (FOM) improves by over 50 times compared to structures without interdigitated fingers. This rational design option opens a promising avenue for highly sensitive detection of thin films and trace biomolecules.
format Preprint
id arxiv_https___arxiv_org_abs_2311_14493
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle Interdigitated Terahertz Metamaterial Sensors: Design with the Dielectric Perturbation Theory
Cao, Lei
Meng, Fanqi
Özdemir, Esra
Loth, Yannik
Richter, Merle
Wigger, Anna Katharina
Sosa, Maira Pérez
Jumaah, Alaa Jabbar
Al-Daffaie, Shihab
Bolívar, Peter Haring
Roskos, Hartmut G.
Optics
Instrumentation and Detectors
Designing terahertz sensors with high sensitivity to detect nanoscale thin films and single biomolecule presents a significant challenge, and addressing these obstacles is crucial for unlocking their full potential in scientific research and advanced applications. This work presents a strategy for the design optimization of metamaterial sensors employed in the detection of small amounts of dielectric materials. The sensors usually utilize the shift of the resonance frequency as an indicator of the presence of the analyte. The amount of shifting depends on intrinsic properties (electric field distribution, quality factor, and mode volume) of the bare cavity, as well as the overlap volume of its high-electric-field zone(s) and the analyte. Guided by the simplified dielectric perturbation theory, interdigitated electric split-ring resonators (ID-eSRR) are devised to significantly enhance the detection sensitivity for thin-film analytes compared to eSRRs without interdigitated fingers in the SRR gap region. The fingers of the ID-eSRR metamaterial sensor redistribute the electric field, creating strongly localized field enhancements that substantially boost the interaction with the analyte. Additionally, the periodic change of the orientation of the inherent anti-phase electric field in the interdigitated structure reduces radiation loss, leading to a higher Q-factor. Experiments with e-beam-fabricated ID-eSRR sensors operating at around 300 GHz demonstrate a remarkable frequency shift of 33.5 GHz upon deposition of a SiO2 layer with a thickness of 150 nm as an analyte simulant. The figure of merit (FOM) improves by over 50 times compared to structures without interdigitated fingers. This rational design option opens a promising avenue for highly sensitive detection of thin films and trace biomolecules.
title Interdigitated Terahertz Metamaterial Sensors: Design with the Dielectric Perturbation Theory
topic Optics
Instrumentation and Detectors
url https://arxiv.org/abs/2311.14493