Journal
IEEE TRANSACTIONS ON ULTRASONICS FERROELECTRICS AND FREQUENCY CONTROL
Volume 69, Issue 2, Pages 779-786Publisher
IEEE-INST ELECTRICAL ELECTRONICS ENGINEERS INC
DOI: 10.1109/TUFFC.2021.3125766
Keywords
Diffraction limit; subwavelength ultrasonic focusing; superresolution imaging
Categories
Funding
- Brazilian Agency Conselho Nacional de Desenvolvimento Cientifico e Tecnologico-CNPq [311107/2020-6, 309375/2018-5, 437757/2018-8]
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This article reports the development and characterization of an ultrasonic transducer that can (super)focus ultrasonic waves beyond the diffraction limit. The transducer consists of an additive manufactured case, a circular flat piezoelectric actuator, and a core-shell lens. It is capable of resolving subwavelength structures and producing high-quality images.
Highly sensitive ultrasound probes are needed to expand the capabilities of biomedical ultrasound and industrial nondestructive testing (NDT). Pursuing better imaging quality, while keeping fabrication costs low, is an important trend in the current development of ultrasound imaging systems. In this article, we report the development and characterization of an ultrasonic transducer that (super)focuses ultrasonic waves beyond the so-called diffraction limit, that is, the beamwaist is roughly narrower than one wavelength. The transducer comprises an additive manufactured case with a circular flat piezoelectric actuator fixed at the bottom and a core-shell lens (with a stainless steel core and a polymer shell) placed at the probe's conical tip. The core-shell lens is responsible to superfocusing effect of ultrasonic waves. Operating at approximately 3 MHz, the transverse and axial resolution for C- and B-scan images are, respectively, 0.65 lambda and 3(lambda/)2, with the wavelength being lambda =0.5mm. The system depth-of-field is 6.3 lambda. To demonstrate the transducer capability to resolve subwavelength structures, we successfully obtain images of a copper wire forming a Y-intersection, whose branches a diameter similar to human hair (0.15 approximate to 0.3 lambda). Our results represent a solid step toward the development of ultrasonic superresolution transducer applied for biomedical imaging and shallow NDT of materials.
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