Metamaterials, Surface Waves, and Their Applications
Thesis advisor: Willie J. Padilla === The field of metamaterials (MMs) has garnered a great deal of attention ever since the experimental demonstration of negative refractive indexes. Such an exotic response stemmed from the engineering capability of MMs, as they can obtain almost any optical respon...
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ndltd-BOSTON-oai-dlib.bc.edu-bc-ir_1037482019-05-10T07:37:47Z Metamaterials, Surface Waves, and Their Applications Chen, Wenchen Thesis advisor: Willie J. Padilla Text thesis 2014 Boston College English electronic application/pdf The field of metamaterials (MMs) has garnered a great deal of attention ever since the experimental demonstration of negative refractive indexes. Such an exotic response stemmed from the engineering capability of MMs, as they can obtain almost any optical responses at any given frequency by carefully structuring the geometries. There are countless examples where MMs have posed promising results in tailoring free space radiation. However, their usage beyond this common platform is far less explored. For examples, surface electromagnetic waves, which offer great potentials for future device applications, could be an intriguing place for the further development of metamateirals. In this dissertation, we study various MM configurations where the interplay between surface waves and metamaterials has a significant impact on the device performance. Firstly, Chapter 1 introduces some fundamental concepts of metamaterials and surface electromagnetic waves, and outline the fabrication, experiments, and characterization details. In Chapter 2, we investigate whether the effective optical parameters of MMs have the exact physical meaning as those of natural substances. Two types of MM resonators are studied, and we found the thickness of the host matrix plays a crucial role in such a homogenization process. Next, we present a computational and experimental study of MMs in conjunction with a novel gigahertz/terahertz transmission line, in Chapter 3. By optimizing the coupling between the MMs and the signal, information can be encoded. Chapter 4 presents a study of designing an extremely subwavelength magnetic MM. By maximizing the effective inductance and capacitance of the structure, the final geometry obtains a strong magnetic resonance with the size of merely λₒ/2000, where λₒ is the resonant wavelength. A novel time-domain spectroscopic method is also proposed to determine the frequency-dependent permeability of the samples. In Chapter 5, we characterize two hidden channels of MM perfect absorbers : scattering and generation of surface electromagnetic waves. In particular, we unveil lossy surface waves are generated during the process resulting in an enhancement of angular absorbance. The study provides a new insight to the working principle of MMAs. In Chapter 6, we investigate complementary MM structures that exhibit strong extraordinary optical transmission with higher transmission efficiency. We discover the origin of the fundamental mode is irrelevant to the Bloch modes. Lastly, we summarize all achievements and give an outlook in Chapter 7. Metamaterials Plasmonics Surface Waves Copyright is held by the author, with all rights reserved, unless otherwise noted. Thesis (PhD) — Boston College, 2014. Submitted to: Boston College. Graduate School of Arts and Sciences. Discipline: Physics. http://hdl.handle.net/2345/bc-ir:103748 |
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Metamaterials Plasmonics Surface Waves Chen, Wenchen Metamaterials, Surface Waves, and Their Applications |
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Thesis advisor: Willie J. Padilla === The field of metamaterials (MMs) has garnered a great deal of attention ever since the experimental demonstration of negative refractive indexes. Such an exotic response stemmed from the engineering capability of MMs, as they can obtain almost any optical responses at any given frequency by carefully structuring the geometries. There are countless examples where MMs have posed promising results in tailoring free space radiation. However, their usage beyond this common platform is far less explored. For examples, surface electromagnetic waves, which offer great potentials for future device applications, could be an intriguing place for the further development of metamateirals. In this dissertation, we study various MM configurations where the interplay between surface waves and metamaterials has a significant impact on the device performance. Firstly, Chapter 1 introduces some fundamental concepts of metamaterials and surface electromagnetic waves, and outline the fabrication, experiments, and characterization details. In Chapter 2, we investigate whether the effective optical parameters of MMs have the exact physical meaning as those of natural substances. Two types of MM resonators are studied, and we found the thickness of the host matrix plays a crucial role in such a homogenization process. Next, we present a computational and experimental study of MMs in conjunction with a novel gigahertz/terahertz transmission line, in Chapter 3. By optimizing the coupling between the MMs and the signal, information can be encoded. Chapter 4 presents a study of designing an extremely subwavelength magnetic MM. By maximizing the effective inductance and capacitance of the structure, the final geometry obtains a strong magnetic resonance with the size of merely λₒ/2000, where λₒ is the resonant wavelength. A novel time-domain spectroscopic method is also proposed to determine the frequency-dependent permeability of the samples. In Chapter 5, we characterize two hidden channels of MM perfect absorbers : scattering and generation of surface electromagnetic waves. In particular, we unveil lossy surface waves are generated during the process resulting in an enhancement of angular absorbance. The study provides a new insight to the working principle of MMAs. In Chapter 6, we investigate complementary MM structures that exhibit strong extraordinary optical transmission with higher transmission efficiency. We discover the origin of the fundamental mode is irrelevant to the Bloch modes. Lastly, we summarize all achievements and give an outlook in Chapter 7. === Thesis (PhD) — Boston College, 2014. === Submitted to: Boston College. Graduate School of Arts and Sciences. === Discipline: Physics. |
author |
Chen, Wenchen |
author_facet |
Chen, Wenchen |
author_sort |
Chen, Wenchen |
title |
Metamaterials, Surface Waves, and Their Applications |
title_short |
Metamaterials, Surface Waves, and Their Applications |
title_full |
Metamaterials, Surface Waves, and Their Applications |
title_fullStr |
Metamaterials, Surface Waves, and Their Applications |
title_full_unstemmed |
Metamaterials, Surface Waves, and Their Applications |
title_sort |
metamaterials, surface waves, and their applications |
publisher |
Boston College |
publishDate |
2014 |
url |
http://hdl.handle.net/2345/bc-ir:103748 |
work_keys_str_mv |
AT chenwenchen metamaterialssurfacewavesandtheirapplications |
_version_ |
1719079467044831232 |