A wideband sensitive needle ultrasound sensor based on a polarized PVDF-TrFE copolymer piezoelectric film has been developed,which is capable of providing a noise equivalent pressure of 14 Pa and a uniform frequency r...A wideband sensitive needle ultrasound sensor based on a polarized PVDF-TrFE copolymer piezoelectric film has been developed,which is capable of providing a noise equivalent pressure of 14 Pa and a uniform frequency response ranging from 1 to 25 MHz.Its high sensitivity(1.6μV∕Pa)and compact size were achieved by capitalizing on the large electromechanical coupling coefficient of PVDF-TrFE and minimizing parasitic capacitance in a two-stage amplifier structure.The detection sensitivity of the newly designed sensor outperformed commercially available hydrophones with an equivalent sensing element area by a factor of 9.The sensor has been successfully integrated into a light scanning optoacoustic microscopy(OAM)system with a limited working space.Submicrometer resolution images were subsequently attained from living mice without employing signal averaging.The miniature sensor design can readily be integrated into various OAM systems and further facilitate multimodal imaging system implementations.展开更多
基金support from the UZH Postdoc Grant.Dr.Pavel Subochev acknowledges support by RSF project 19-75-10055(development of needle PVDF-TrFE US sensor)support by Center of Excellence“Center of Photonics”funded by the Ministry of Science and Higher Education of the Russian Federation,Contract No.075-15-2022-316(measurements of sensitivity and NEP of needle PVDF-TrFE US sensor).
文摘A wideband sensitive needle ultrasound sensor based on a polarized PVDF-TrFE copolymer piezoelectric film has been developed,which is capable of providing a noise equivalent pressure of 14 Pa and a uniform frequency response ranging from 1 to 25 MHz.Its high sensitivity(1.6μV∕Pa)and compact size were achieved by capitalizing on the large electromechanical coupling coefficient of PVDF-TrFE and minimizing parasitic capacitance in a two-stage amplifier structure.The detection sensitivity of the newly designed sensor outperformed commercially available hydrophones with an equivalent sensing element area by a factor of 9.The sensor has been successfully integrated into a light scanning optoacoustic microscopy(OAM)system with a limited working space.Submicrometer resolution images were subsequently attained from living mice without employing signal averaging.The miniature sensor design can readily be integrated into various OAM systems and further facilitate multimodal imaging system implementations.
