Wafer-level processing of ultralow-loss Si3N4
Doktorsavhandling, 2023
Photonic integrated circuits (PICs) are devices fabricated on a planar wafer that allow light generation, processing, and detection. Photonic integration brings important advantages for scaling up the complexity and functionality of photonic systems and facilitates their mass deployment in areas where large volumes and compact solutions are needed, e.g., optical interconnects. Among the material platforms available, silicon nitride (Si3N4) displays excellent optical properties such as broadband transparency, moderately high refractive index, and relatively strong nonlinearities. Indeed, Si3N4 integrated waveguides display ultralow-loss (few decibels per meter), which enables efficient light processing and nonlinear optics. Moreover, Si3N4 is compatible with standard complementary metal oxide semiconductor (CMOS) processing techniques,
which facilitates the manufacture scalability required by mass deployment of PICs. However, the selection of a single photonic platform sets limitations to the device functionalities due to the intrinsic properties of the material and the fundamental limitation of optical waveguiding. Multilayer integration of different platforms can overcome the limitations encountered in a singleplatform PIC.
This thesis presents the development of advanced techniques for the waferlevel manufacturing of ultralow-loss Si3N4 devices and approaches to enable their interface with active components like modulators and chip-scale comb sources (microcombs). The investigation covers the tailoring of a waveguide to the functionality required, the wafer-scale manufacturing of Si3N4, and how to overcome the limitations of a single platform on a wafer. These studies enable high-yield fabrication of microcombs, the integration of two Si3N4 platforms on the same wafer, and a strategy to efficiently couple to an integrated LiNbO3 layer to expand the chip functionality and scale up the complexity of the PIC.
which facilitates the manufacture scalability required by mass deployment of PICs. However, the selection of a single photonic platform sets limitations to the device functionalities due to the intrinsic properties of the material and the fundamental limitation of optical waveguiding. Multilayer integration of different platforms can overcome the limitations encountered in a singleplatform PIC.
This thesis presents the development of advanced techniques for the waferlevel manufacturing of ultralow-loss Si3N4 devices and approaches to enable their interface with active components like modulators and chip-scale comb sources (microcombs). The investigation covers the tailoring of a waveguide to the functionality required, the wafer-scale manufacturing of Si3N4, and how to overcome the limitations of a single platform on a wafer. These studies enable high-yield fabrication of microcombs, the integration of two Si3N4 platforms on the same wafer, and a strategy to efficiently couple to an integrated LiNbO3 layer to expand the chip functionality and scale up the complexity of the PIC.
waveguide
photonic integrated circuit
multilayer integration
ultralow loss
microcombs i
silicon nitride
Room A423 (Kollektorn), Department of Microtechnology and Nanoscience (MC2), Kemivägen 9, Göteborg,
Opponent: Prof. Joyce Poon, Max Plank Institute of Microstructure Physics, Germany
Författare
Marcello Girardi
Chalmers, Mikroteknologi och nanovetenskap, Fotonik
Passive Si3N4 photonic integrated platform at 1μm for short-range optical interconnects
2019 Conference on Lasers and Electro-Optics Europe and European Quantum Electronics Conference, CLEO/Europe-EQEC 2019,; (2019)
Paper i proceeding
LiNbO3/Si3N4-Bilayer Vertical Coupler for Integrated Photonics
Conference Proceedings - Lasers and Electro-Optics Society Annual Meeting-LEOS,; Vol. 2020-May(2020)
Paper i proceeding
Óskar B. Helgason, Marcello Girardi, Zhichao Ye, Fuchuan Lei, Jochen Schröder and Victor Torres-Company, Surpassing the nonlinear conversion efficiency of soliton microcombs
Marcello Girardi, Óskar B. Helgason, Alexander Caut, Magnus Karlsson, Anders Larsson, Victor Torres-Company, Multilayer integration in silicon nitride: decoupling linear and nonlinear functionalities for ultralow loss photonic integrated systems
Marcello Girardi, Óskar B. Helgason, Carmen H. López Ortega, Israel Rebolledo-Salgado, Victor Torres-Company, Superefficient microcombs at the wafer level
Photonic integrated circuits are the result of applying cutting-edge nanoscale manufacturing techniques to the field of optics. Photonic integrated circuits are chips, usually smaller than a coin, capable of transmitting, generating, and manipulating light. These chips have the potential to replace bulky optical systems, improve their functionalities, and decrease power consumption. For this reason, they are already used in the communication sector, inside data centers to form the fast communication network that enables the Internet as we know it. To sustain the steady growth in Internet utilization, research focuses on developing best-in-class optical materials and combining them in the same chip to achieve fast and power-efficient optical communication links. Moreover, other fields such as timekeeping, range measurement, spectroscopy, and biosensing can exploit these advancements to miniaturize complex light processing systems.
This thesis focuses on fabrication techniques to improve the functionalities of photonic integrated circuits, by integrating multiple layers of optical materials. This provides more freedom in the design, enabling more advanced optical systems. The publications in this thesis present multiple ultralow loss silicon nitride photonic platforms, the integration of two platforms on the same chip, and the possibility of integrating other materials for specific functions, e.g., light modulation (on-off switching). Moreover, the fabrication techniques are developed at the wafer level with high yield, which guarantees the possibility of scaling up the manufacturing to produce best-in-class devices for large-scale applications, such as optical communication systems.
This thesis focuses on fabrication techniques to improve the functionalities of photonic integrated circuits, by integrating multiple layers of optical materials. This provides more freedom in the design, enabling more advanced optical systems. The publications in this thesis present multiple ultralow loss silicon nitride photonic platforms, the integration of two platforms on the same chip, and the possibility of integrating other materials for specific functions, e.g., light modulation (on-off switching). Moreover, the fabrication techniques are developed at the wafer level with high yield, which guarantees the possibility of scaling up the manufacturing to produce best-in-class devices for large-scale applications, such as optical communication systems.
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Integrerade optiska sändare för våglängdsmultiplexering i datacenternätverk
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Dark-Soliton Engineering in Microresonator Frequency Combs (DarkComb)
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Flerdimensionell koherentkommunikation med mikrofrekvenskammar
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Styrkeområden
Informations- och kommunikationsteknik
Nanovetenskap och nanoteknik
Materialvetenskap
Ämneskategorier
Telekommunikation
Annan fysik
Nanoteknik
Annan elektroteknik och elektronik
Infrastruktur
Nanotekniklaboratoriet
ISBN
978-91-7905-920-0
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5386
Utgivare
Chalmers
Room A423 (Kollektorn), Department of Microtechnology and Nanoscience (MC2), Kemivägen 9, Göteborg,
Opponent: Prof. Joyce Poon, Max Plank Institute of Microstructure Physics, Germany