Thermoacoustic Effects and Applications in Medicine, Security and Communication

#mtts #aps #applications #antenna #mttsapsuffc #simulation #em #medical #dml #microwave
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Thermoacoutsic effect describes the generation of acoustic waves from incident electromagnetic energy due to differential heat generation and absorption in an object. Thermoacoustic imaging (TAI) is a promising candidate for many biomedical applications including breast cancer detection. TAI creates an image of the internal morphological features of a dielectrically lossy sample by employing generated acoustic waves from absorbed microwave energy in the sample owing to the  thermoacoustic effect based on thermoelastic expansion. Malignant tissues, usually embracing higher dielectric loss, absorbing more energy and emanating stronger acoustic waves than the surrounding healthy tissues, may be distinguished in the image. The elegant marriage between microwave and ultrasound, whose advantages and drawbacks in biomedical imaging are in many ways complementary, endows TAI with the unique merit of high contrast inherited from microwave and excellent spatial resolution inherited from ultrasound. TAI is also non-ionizing and noninvasive compared with other existing breast cancer imaging modalities. A potential clinical feasible TAI system is more cost-efficient and compact than mammography and MRI.

In addition, we explore another novel potential application based on thermoacoustic effect for wireless communications, which is referred to as thermoacoustic communications (TAC). It is proposed as a potential complementary method to mitigate the challenge in conventional wireless communication from air to water, in which the electromagnetic wave cannot penetrate deep in water. TAC employs a microwave antenna in air to irradiate the water surface with a microwave signal encoded with information to be communicated. Some microwave energy is absorbed by the water and concomitant temperature increase and thermal expansion take place in the water. Acoustic waves are subsequently emanated from the water and propagate in the water with much less attenuation than electromagnetic waves and thus can propagate a long distance in the water.

Finally, an underwater device with an acoustic transducer can detect the generated acoustic signals and the information is acquired by decoding the signals. In this talk, I will present our theoretical and experimental studies on thermoacoustic effect and its applications


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  • Start time: 20 Apr 2023 01:30 PM
  • End time: 23 Apr 2023 02:30 PM
  • All times are (UTC-04:00) Eastern Time (US & Canada)
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  • UConn
  • Storrs, Connecticut
  • United States
  • Building: ITE
  • Room Number: 401
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  • Starts 17 April 2023 12:00 PM
  • Ends 23 April 2023 11:48 AM
  • All times are (UTC-04:00) Eastern Time (US & Canada)
  • No Admission Charge

  Speakers

Prof Hao Xin

Topic:

Prof Hao Xin - Univ of Arizona

OPEN PUBLIC PRESENTATION – IEEE APS Distinquished Lecturer

Presentation Title:  Thermoacoustic Effects and Applications in Medicine, Security and Communication

Speaker: Dr. Hao Xin

Biography:

Dr. Hao Xin is a professor of Electrical and Computer Engineering, and professor of Physics at the University of Arizona. He is also an IEEE Fellow. His current teaching and research interests are on high frequency (from microwave to THz) technologies, including passive and active circuits, antennas, properties and applications of new materials such as metamaterials and nano-materials for wireless communication, sensing, bio-medical, and energy harvesting. In 2016, he co-founded and served as the CTO and president of Lunewave Inc. to commercialize 3D printed Luneburg lens antennas for automotive radar sensors. Before joining the University of Arizona, he worked as research scientist at Rockwell Scientific Company and as Sr. Principal Multidisciplinary Engineer at Raytheon Missile Systems. He has published over 350 refereed papers and over 20 patents in related research areas. He served as the general co-chair of the 8th International Antenna Technology Workshop and the general secretary of the 39th International Infrared, Millimeter Wave and THz Conference. He was an associate editor for IEEE Antennas and Wireless Propagation Letters from 2012 to 2018. He is an associate editor for IEEE Antennas and Wireless Propagation Magazine and IEEE Journal of Radio Frequency ID. He currently serves as the chair of the Young Professionals Committee of the IEEE Antennas and Propagation Society. He is also the Tucson joint chapter chair of IEEE Microwave Theory and Techniques / Antennas and Propagation societies. Dr. Xin has current and previous research support (overall > $14M, individual expense > $8M) from DARPA, ARO, AFOSR, ONR, NSF, AFRL, and industry for his research on a broad range of topics related to microwave engineering. He has graduated and mentored 11 post-docs, 16 (including 6 visiting) PhD students, 10 MS students, and more than

60 undergraduate students.

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