Journal
IEEE TRANSACTIONS ON ULTRASONICS FERROELECTRICS AND FREQUENCY CONTROL
Volume 69, Issue 10, Pages 2785-2797Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TUFFC.2022.3189338
Keywords
Acoustic characterization; electrical characterization; electrode patterning; excimer laser; fine pitch; flexible circuit cabling; high-frequency ultrasound; high-density interconnect; laser lithography; laser machining
Categories
Funding
- Terry Fox Research Institute New Frontiers Program Project Grant in Porphysome Nanoparticle-Enabled Image Guided Cancer Interventions
- Natural Sciences and Engineering Research Council of Canada [RGPIN-2017-06834]
- Ontario Graduate Scholarship
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Micro-ultrasound (micro-US) has become an invaluable tool in research and clinical applications. This study presents a method for connecting array elements in spatially constrained conditions and demonstrates its effectiveness in connecting with a micro-US array. The proposed manufacturing methods facilitate the development of flexible endoscopic or small-footprint micro-US devices.
Microultrasound (micro-US) has become an invaluable tool for preclinical research and in emerging applications in clinical diagnosis and treatment guidance. Several such applications can benefit from arrays with a small footprint and endoscopic form factor. However, critical challenges arise in making electrical connections to array elements in such spatial constraints. In this work, we describe a method to pattern a high-density flexible circuit cabling on a copper-on polyimide film, using laser ablation of a polymer resist and wet etching, and then demonstrate a connection to a micro-US array. We investigate laser ablation process parameters and evaluate the ability to consistently pattern continuous copper traces. A minimum 30-mu m pitch was achieved with 5-mu m-wide electrode lines, and continuity of a 5-m-long trace is demonstrated. A flexible circuit with 30-mm-long traces with 30-mu m line and 30-mu m space before fan-out was fabricated to connect in an interleaved manner to a 32-element array with 30 mu m element pitch. Metal deposition and laser ablation were used to connect and pattern the element electrodes to the copper traces of the flexible circuit. Electrical and acoustic measurements show good yield and consistent impedance across channels. Element pulse-echo tests demonstrated device functionality; the two-way pulse had 43-MHz center frequency and 40% fractional bandwidth (-6 dB). The pro-posed manufacturing methods facilitate the prototyping and fabrication of flexible endoscopic or small-footprint micro-US devices.
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