Strategies to enhance THz harmonic generation combining multilayered, gated, and metamaterial-based architectures
Graphene has unique properties paving the way for groundbreaking future applications. Its large optical nonlinearity and ease of integration in devices notably makes it an ideal candidate to become a key component for all-optical switching and frequency conversion applications. In the terahertz (THz...
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| creator | Maleki, Ali Heindl, Moritz B Xin, Yongbao Boyd, Robert W Herink, Georg Ménard, Jean-Michel |
| description | Graphene has unique properties paving the way for groundbreaking future
applications. Its large optical nonlinearity and ease of integration in devices
notably makes it an ideal candidate to become a key component for all-optical
switching and frequency conversion applications. In the terahertz (THz) region,
various approaches have been independently demonstrated to optimize the
nonlinear effects in graphene, addressing a critical limitation arising from
the atomically thin interaction length. Here, we demonstrate sample
architectures that combine strategies to enhance THz nonlinearities in
graphene-based structures. We achieve this by increasing the interaction length
through a multilayered design, controlling carrier density with an electrical
gate, and modulating the THz field spatial distribution with a metallic
metasurface substrate. Our study specifically investigates third harmonic
generation (THG) using a table-top high-field THz source. We measure THG
enhancement factors exceeding thirty and propose architectures capable of
achieving a two-order-of-magnitude increase. These findings highlight the
potential of engineered graphene-based samples in advancing THz frequency
conversion technologies for signal processing and wireless communication
applications. |
| doi_str_mv | 10.48550/arxiv.2405.17125 |
| format | Article |
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applications. Its large optical nonlinearity and ease of integration in devices
notably makes it an ideal candidate to become a key component for all-optical
switching and frequency conversion applications. In the terahertz (THz) region,
various approaches have been independently demonstrated to optimize the
nonlinear effects in graphene, addressing a critical limitation arising from
the atomically thin interaction length. Here, we demonstrate sample
architectures that combine strategies to enhance THz nonlinearities in
graphene-based structures. We achieve this by increasing the interaction length
through a multilayered design, controlling carrier density with an electrical
gate, and modulating the THz field spatial distribution with a metallic
metasurface substrate. Our study specifically investigates third harmonic
generation (THG) using a table-top high-field THz source. We measure THG
enhancement factors exceeding thirty and propose architectures capable of
achieving a two-order-of-magnitude increase. These findings highlight the
potential of engineered graphene-based samples in advancing THz frequency
conversion technologies for signal processing and wireless communication
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applications. Its large optical nonlinearity and ease of integration in devices
notably makes it an ideal candidate to become a key component for all-optical
switching and frequency conversion applications. In the terahertz (THz) region,
various approaches have been independently demonstrated to optimize the
nonlinear effects in graphene, addressing a critical limitation arising from
the atomically thin interaction length. Here, we demonstrate sample
architectures that combine strategies to enhance THz nonlinearities in
graphene-based structures. We achieve this by increasing the interaction length
through a multilayered design, controlling carrier density with an electrical
gate, and modulating the THz field spatial distribution with a metallic
metasurface substrate. Our study specifically investigates third harmonic
generation (THG) using a table-top high-field THz source. We measure THG
enhancement factors exceeding thirty and propose architectures capable of
achieving a two-order-of-magnitude increase. These findings highlight the
potential of engineered graphene-based samples in advancing THz frequency
conversion technologies for signal processing and wireless communication
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applications. Its large optical nonlinearity and ease of integration in devices
notably makes it an ideal candidate to become a key component for all-optical
switching and frequency conversion applications. In the terahertz (THz) region,
various approaches have been independently demonstrated to optimize the
nonlinear effects in graphene, addressing a critical limitation arising from
the atomically thin interaction length. Here, we demonstrate sample
architectures that combine strategies to enhance THz nonlinearities in
graphene-based structures. We achieve this by increasing the interaction length
through a multilayered design, controlling carrier density with an electrical
gate, and modulating the THz field spatial distribution with a metallic
metasurface substrate. Our study specifically investigates third harmonic
generation (THG) using a table-top high-field THz source. We measure THG
enhancement factors exceeding thirty and propose architectures capable of
achieving a two-order-of-magnitude increase. These findings highlight the
potential of engineered graphene-based samples in advancing THz frequency
conversion technologies for signal processing and wireless communication
applications.</abstract><doi>10.48550/arxiv.2405.17125</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Physics - Applied Physics Physics - Optics |
| title | Strategies to enhance THz harmonic generation combining multilayered, gated, and metamaterial-based architectures |
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