Title :
Metallic nanofilm as resonance-free airborne ultrasound emitter
Author :
Daschewski, M. ; Harrer, Andreas ; Prager, J. ; Kreutzbruck, M. ; Beck, Uwe ; Lange, Tobias ; Weise, Matthias
Author_Institution :
Fed. Inst. for Mater. Res. & Testing (BAM), Berlin, Germany
Abstract :
A novel approach for the generation of broadband airborne ultrasound by using the thermo-acoustic effect is presented in this contribution. We investigate the applicability of resonance-free thermo-acoustic emitters for generation of very short high pressure airborne ultrasound pulses. A thermoacoustic emitter consisting of a 30 nm thin metallic film on a usual soda-lime glass substrate generates sound pressure values of more than 140 dB at 60 mm distance. The results are compared with conventional piezoelectric airborne ultrasound transducers. Our investigations show the applicability of the thermo-acoustic devices for broadband and high pressure ultrasound emitters using pulse excitation.
Keywords :
metallic thin films; nanostructured materials; thermoacoustics; ultrasonic transducers; broadband airborne ultrasound generation; distance 60 mm; piezoelectric airborne ultrasound transducer; pulse excitation; resonance-free airborne ultrasound emitter; resonance-free thermoacoustic emitter effect; size 30 nm; soda-lime glass substrate; thermoacoustic device; thin metallic nanofilm; very short high pressure airborne ultrasound pulse generation; Acoustics; Atmospheric measurements; Broadband communication; Titanium; Transducers; Ultrasonic imaging; Velocity measurement; broadband airborne ultrasound; high pressure airborne ultrasound; resonance-free ultrasound transducer; sound particle velocity measurement; thermo-acoustic;
Conference_Titel :
Ultrasonics Symposium (IUS), 2012 IEEE International
Conference_Location :
Dresden
Print_ISBN :
978-1-4673-4561-3
DOI :
10.1109/ULTSYM.2012.0241
