Perovskites for ultrafast active terahertz photonics
In the electromagnetic spectrum terahertz (THz) frequency that lies between conventional electronics and photonics is vital due to its uniqueness and high potential for many disruptive applications such as security, high-resolution imaging, ultrasensitive sensors, and high-speed wireless communic...
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| Format: | Thesis-Doctor of Philosophy |
| Language: | English |
| Published: |
Nanyang Technological University
2020
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| Online Access: | https://hdl.handle.net/10356/145567 |
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| Institution: | Nanyang Technological University |
| Language: | English |
| Summary: | In the electromagnetic spectrum terahertz (THz) frequency that lies between
conventional electronics and photonics is vital due to its uniqueness and high
potential for many disruptive applications such as security, high-resolution
imaging, ultrasensitive sensors, and high-speed wireless communication for the
sixth generation (6G). THz waves hold the potential to boost the key performance
of many existing technologies thus, the emergence of THz photonics is inevitable.
Hence, it is of paramount importance to develop the technology that provides
unprecedented control on terahertz waves. The difficulties to control the
properties of THz waves using natural existing materials led to the development
of artificial composite materials known as metamaterial (MM).
Metamaterial (MM) offers a simple and effective platform to develop the terahertz
technologies owing to its scalable and on demand optical property that could be
tuned. Active control of metamaterial response enables realization of THz
functional devices. More importantly, the ability to control THz waves at ultrafast
time scale is extremely crucial for developing next generation high-speed wireless
communication. Integrating dynamic materials such as semiconductors with MM
offers a possible solution. However, for commercial large-scale deployment a
cost-effective high performing functional solution is desired for advance
manipulation of THz waves in emerging THz technologies.
This thesis aims to address these questions and provides a possible route to
develop cost effective, easily integrable and high performing ultrafast THz
photonic devices by integrating solution processed perovskite with metallic THz8
metamaterial (MM) structures. In the development of ultrafast active THz devices,
the natural progression is to introduce multi functionalities in active metamaterial
for advance manipulation of THz waves. In this context, the strong interaction of
perovskite thin film with confined THz electric field offers a viable route to tune
the carrier dynamics which is key to the foundation for next generation
multifunctional active metamaterials.
In this thesis, solution-processed perovskite has been explored to develop ultrafast
THz photonics device. Fano resonant metamaterial structures owing to strong THz
electric field confinement were employed to integrate with perovskites. The high
photoconductivity and ultrafast free carrier dynamics in perovskite thin film
enabled near unity modulation of THz electric field at ultrafast timescale. The
existence of self-assembled quantum well (QW) in 2D perovskite provides an
additional channel for the photoexcited free carrier to relax at ultrafast time scales
(~ 20 ps) which is fastest in the family of solution processed semiconductors. We
demonstrated 2D perovskite integrated hybrid metadevice at rigid as well as
flexible platform that showed modulation of THz waves at ~ 50 GHz modulation
speed.
In the future prospect of the thesis we provide an outlook to achieve wavelength
dependent response of active THz metadevice through integration of perovskites
with silicon. The large bandgap tunability, ease of integration and ultrafast carrier
dynamics of perovskite opens a new paradigm to develop multifunctional ultrafast
active THz photonic devices for advance manipulation of THz waves. |
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