Design and Characterisation of Terahertz Schottky Barrier Diode Mixers
Doktorsavhandling, 2024
Efficient and compact terahertz frequency converters operating at ambient temperatures are essential for long lifetime space/air-borne missions. Yet, realising mixers in the 3–5 THz range remains challenging due to the lack of stable local oscillator sources, complexities in circuit fabrication, and the need for high-precision machining of E-plane split blocks.
This dissertation addresses these challenges with a focus on developing 3.5-THz and 4.7-THz harmonic and fundamental mixers. First, the effect of idler terminations on the harmonic mixer's performance was evaluated. Based on this theoretical study, 3.5-THz, x6-harmonic mixers were designed, featuring a planar, single-ended Schottky-barrier diode with a sub-micron anode on a 2-um GaAs membrane. The mixers exhibited a conversion loss of 60 dB at 3.5 THz and 76 dB at 4.7 THz. This was followed by a successful demonstration of phase-locking of quantum-cascade lasers, representing the state-of-the-art wide-band harmonic mixers using planar diodes in the 3-5 THz range.
In addition, this research focused on the design and experimental characterisation of 3.5-THz and 4.7-THz fundamental mixers. The initial video detection and noise temperature measurements indicated significant losses and poor RF coupling. To address these issues, a scaled-down experiment was performed to analyse the impact of E-plane misalignment on diagonal horn antennas in the WM-570 frequency band. An E-plane misalignment of approximately 8% of the wavelength led to a 3-dB degradation in the optical coupling to a Gaussian beam (Gaussicity) in the middle of the waveguide band. Based on this, an optimised design for a 4.7-THz, x8-harmonic mixer with an integrated pyramidal horn, less susceptible to E-plane asymmetry, is presented. Finally, an alternate measurement technique which enables broadband characterisation of THz harmonic mixers is demonstrated. These results represent the first broadband characterisation of THz harmonic mixers from 2.2 to 3 THz.
These results present essential findings that will enable the realisation of THz heterodyne receivers for detecting atomic and molecular species such as hydroxyl radical (OH) and atomic oxygen (OI), which are crucial for atmospheric and planetary science research.
This dissertation addresses these challenges with a focus on developing 3.5-THz and 4.7-THz harmonic and fundamental mixers. First, the effect of idler terminations on the harmonic mixer's performance was evaluated. Based on this theoretical study, 3.5-THz, x6-harmonic mixers were designed, featuring a planar, single-ended Schottky-barrier diode with a sub-micron anode on a 2-um GaAs membrane. The mixers exhibited a conversion loss of 60 dB at 3.5 THz and 76 dB at 4.7 THz. This was followed by a successful demonstration of phase-locking of quantum-cascade lasers, representing the state-of-the-art wide-band harmonic mixers using planar diodes in the 3-5 THz range.
In addition, this research focused on the design and experimental characterisation of 3.5-THz and 4.7-THz fundamental mixers. The initial video detection and noise temperature measurements indicated significant losses and poor RF coupling. To address these issues, a scaled-down experiment was performed to analyse the impact of E-plane misalignment on diagonal horn antennas in the WM-570 frequency band. An E-plane misalignment of approximately 8% of the wavelength led to a 3-dB degradation in the optical coupling to a Gaussian beam (Gaussicity) in the middle of the waveguide band. Based on this, an optimised design for a 4.7-THz, x8-harmonic mixer with an integrated pyramidal horn, less susceptible to E-plane asymmetry, is presented. Finally, an alternate measurement technique which enables broadband characterisation of THz harmonic mixers is demonstrated. These results represent the first broadband characterisation of THz harmonic mixers from 2.2 to 3 THz.
These results present essential findings that will enable the realisation of THz heterodyne receivers for detecting atomic and molecular species such as hydroxyl radical (OH) and atomic oxygen (OI), which are crucial for atmospheric and planetary science research.
Terahertz electronics
Schottky-barrier diodes
Heterodyne receivers
Harmonic mixers
Phase locking
Författare
Divya Jayasankar
WiTECH
RISE AB
Chalmers, Mikroteknologi och nanovetenskap, Terahertz- och millimetervågsteknik
Effect of idler terminations on the conversion loss for THz Schottky diode harmonic mixers
International Conference on Infrared, Millimeter, and Terahertz Waves, IRMMW-THz,;Vol. 2019-September(2019)
Paper i proceeding
A 3.5-THz, x6-Harmonic, Single-Ended Schottky Diode Mixer for Frequency Stabilization of Quantum-Cascade Lasers
IEEE Transactions on Terahertz Science and Technology,;Vol. 11(2021)p. 684-694
Artikel i vetenskaplig tidskrift
A Broadband Conversion Loss Measurement Technique for Terahertz Harmonic Mixers
IEEE Transactions on Terahertz Science and Technology,;Vol. 14(2024)p. 424-427
Artikel i vetenskaplig tidskrift
Design and Characterisation of a 3.5-THz Fundamental Schottky Mixer
32nd International Symposium of Space Terahertz Technology, ISSTT 2022,;(2022)
Paper i proceeding
Impact of E-plane Misalignment on THz Diagonal Horn Antennas
IEEE Transactions on Terahertz Science and Technology,;(2024)
Artikel i vetenskaplig tidskrift
4.7-THz Schottky Diode Harmonic Mixer: Design, Fabrication, and Performance Optimization
ISSTT 2024 - 33rd International Symposium on Space Terahertz Technology,;(2024)
Paper i proceeding
Radio astronomy has witnessed unprecedented growth over the past few decades, allowing us to explore our galaxy and expand our knowledge about the origin of the universe. However, a part of the electromagnetic spectrum has remained unexplored due to technological limitations. The terahertz (THz) frequency range, referred to as the sub-millimetre or far-infrared region, is roughly defined from 300 GHz to 10 THz. It represents the area of the electromagnetic spectrum where microwave and optical techniques meet.
Studying the chemical composition of the Earth at THz frequencies will provide valuable insights into global warming and climate change. In particular, detecting gas species such as atomic oxygen (OI) at 4.7 THz and hydroxyl (OH) at 3.5 THz in the least explored atmospheric regions can improve the climate and weather prediction models.
A key component in receivers is a mixer or frequency converter. Mixers can detect and convert incoming signals to lower-frequency signals that are easier to process and analyse. This thesis focuses on developing receivers that operate at 3.5/4.7 THz based on Schottky diodes which are ideal for long lifetime space missions since they operate without cryogenics.
Studying the chemical composition of the Earth at THz frequencies will provide valuable insights into global warming and climate change. In particular, detecting gas species such as atomic oxygen (OI) at 4.7 THz and hydroxyl (OH) at 3.5 THz in the least explored atmospheric regions can improve the climate and weather prediction models.
A key component in receivers is a mixer or frequency converter. Mixers can detect and convert incoming signals to lower-frequency signals that are easier to process and analyse. This thesis focuses on developing receivers that operate at 3.5/4.7 THz based on Schottky diodes which are ideal for long lifetime space missions since they operate without cryogenics.
THz-metrologi för moderna trådlösa system
Stiftelsen för Strategisk forskning (SSF) (FID17-0040), -- .
Styrkeområden
Informations- och kommunikationsteknik
Infrastruktur
Kollberglaboratoriet
Nanotekniklaboratoriet
Ämneskategorier
Elektroteknik och elektronik
ISBN
978-91-8103-131-7
Doktorsavhandlingar vid Chalmers tekniska högskola. Ny serie: 5589
Utgivare
Chalmers
Kollektorn
Opponent: Dr. Jeanne Treuttel