Liu K.Y.Tan B.K.Wang M.J.Kittara P.Singwong D.Janphuang P.Ho P.Chen M.T.Rujopakarn W.Pen U.L.Fuller G.A.Liu J.Jiang X.J.Boussaha F.Chaumont C.Chen T.J.Chang Y.P.Lu W.C.Chiu C.P.Larkaew C.Kriettisak N.Jiang L.Wang Y.Wang Y.J.Bell G.Peña-Herazo H.A.Mizuno I.Li S.Oliveira R.N.Cookson J.Bintley D.Mahidol University2024-09-302024-09-302024-01-01Proceedings of SPIE - The International Society for Optical Engineering Vol.13102 (2024)0277786Xhttps://repository.li.mahidol.ac.th/handle/20.500.14594/101423In pursuit of advancing large array receiver capabilities and enhancing the 16-element Heterodyne Array Receiver Program (HARP) instrument on the James Clerk Maxwell Telescope (JCMT), we have successfully fabricated 230 GHz finline superconductor-insulator-superconductor (SIS) mixers. These mixers are critical for assessing the potential and prospective for the HARP instrument's upgrade. Unlike the existing HARP's mixer, we replace the probe antenna with an end-fire unilateral finline as the waveguide to planar circuit transition. This mixer design is expected to operate from about 160-260 GHz (approximately 47% bandwidth), and the mixer chips' current-voltage (I-V) curves have been characterized, showing promising results with a quality factor (Rsg/Rn) exceeding 9.3. Evaluation of the double-sideband (DSB) receiver noise temperature (Trx) is currently underway. Once successfully characterised, our immediate aim is to scale the mixer to operate at HARP's frequency range near 345 GHz to achieve similar broad RF bandwidth performance. Ongoing simulations are currently being conducted for the design of the 345 GHz finline mixer. This work marks a crucial step toward enhancing HARP receiver performance with better sensitivity and wider Intermediate Frequency (IF) bandwidth, enabling higher-frequency observations, and expanding the scientific potential of the JCMT and its collaborative partners.MathematicsMaterials ScienceComputer SciencePhysics and AstronomyEngineeringConference PaperSCOPUS10.1117/12.30181512-s2.0-852047363401996756X