[1] [1] R. A. Kruger, K. D. Miller, H. E. Reynolds, W. L. Kiser Jr, D. R. Reinecke, G. A. Kruger, "Breast cancer in vivo: Contrast enhancement with thermoacoustic CT at 434 MHz-feasibility study," Radiology 216(1), 279–283 (2000).

[2] [2] M. Xu, G. Ku, X. Jin, L. V. Wang, B. D. Fornage, K. K. Hunt, "Breast cancer imaging by microwaveinduced thermoacoustic tomography," Proc. SPIE 5697, 45–48 (2005).

[3] [3] Y. Zhao, Z. Ji, B. Qin, D. Xing, "A thermoacoustic imaging system with variable curvature and multidimensional detection adapted to breast tumor screening," J. Appl. Phys. 124, 144902 (2018).

[4] [4] Z. Chi, Y. Zhao, J. Y, T. Li, G. Zhang, H. Jiang, "Thermoacoustic tomography of in vivo human finger joints," IEEE Trans. Biomed. Eng. 66(6), 1598–1608 (2019).

[5] [5] Z. Chi, L. Huang, S. Ge, H. Jiang, "Technical Note: Anti-phase microwave illumination-based thermoacoustic tomography of in vivo human finger joints," Med. Phys. 46(5), 2363–2369 (2019).

[6] [6] Z. Chi, Y. Zhao, L. Huang, Z. Zheng, H. Jiang, "Thermoacoustic imaging of rabbit knee joints," Med. Phys. 43(12), 6226–6233 (2016).

[7] [7] L. Liu, K. He, L. V. Wang, "Transcranial ultrasonic wave propagation simulation: Skull insertion loss and recovery," Proc. SPIE 6437, 64370X (2007).

[8] [8] Y. Zhao, T. Shan, Z. Chi, H. Jiang, "Thermoacoustic tomography of germinal matrix hemorrhage in neonatal mouse cerebrum," J. X-ray Sci. Technol. 28, 83–93 (2020).

[9] [9] Y. Zhao, Z. Chi, L. Huang, Z. Zheng, J. Yang, H. Jiang, "Thermoacoustic tomography of in vivo rat brain," J. Innov. Opt. Health Sci. 10(4), 1740001 (2017).

[10] [10] X. Liang, H. Guo, Q. Liu, C. Wu, Y. Gong, L. Xi, "Thermoacoustic endoscopy," Appl. Phys. Lett. 116, 013702 (2020).

[11] [11] D. Feng, Y. Xu, G. Ku, L. V. Wang, "Microwaveinduced thermoacoustic tomography: Reconstruction by synthetic aperture," Med. Phys. 28(12), 2427–2431 (2001).

[12] [12] L. Yao, G. Guo, H. Jiang, "Quantitative microwaveinduced thermoacoustic tomography," Med. Phys. 37(7), 3752–3759 (2010).

[13] [13] Y. He, C. Liu, L. Lin, L. V. Wang, "Comparative effects of linearly and circularly polarized illumination on microwave-induced thermoacoustic tomography," IEEE Antenn. Wirel. Pr. 16, 1593– 1596 (2017).

[14] [14] C. Li, M. Pramanik, G. Ku, L. V. Wang, "Image distortion in thermoacoustic tomography caused by microwave diffraction," Phys. Rev. E 77(3), 031923 (2008).

[15] [15] A. Yan, L. Lin, S. Na, C. Liu, L. V. Wang, "Large field homogeneous illumination in microwaveinduced thermoacoustic tomography based on a quasi-conical spiral antenna," Appl. Phys. Lett. 113 (12), 123701 (2018).

[16] [16] Y. He, Y. Shen, X. Feng, C. Liu, L. V. Wang, "Homogenizing microwave illumination in thermoacoustic tomography by a linear to-circular polarizer based on frequency selective surfaces," Appl. Phys. Lett. 111(6), 063703 (2017).

[17] [17] B. Wang, Y. Sun, Z. Wang, X. Wang, "Three-dimensional microwave-induced thermoacoustic imaging based on compressive sensing using an analytically constructed dictionary," IEEE Trans. Microw. Theory Tech. 68(1), 377–386 (2010).

[18] [18] M. S. Aliroteh, A. Arbabian, "Microwave-induced thermoacoustic imaging of subcutaneous vasculature with near-field RF excitation," IEEE Trans. Microw. Theory Tech. 66(1), 577–588 (2018).

[19] [19] D. Zhang, H. He, ?. Zong, Y. Liu, "Microwave-induced thermoacoustic imaging of wood: A first demonstration," Wood Sci. Technol. 53(6), 1223– 1235 (2019).

[20] [20] J. Wang, Z. Zhao, Song, Jian, G. Chen, Z. Nie, Q. Liu, "Reducing the effects of acoustic heterogeneity with an iterative reconstruction method from experimental data in microwave induced thermoacoustic tomography," Med. Phys. 42(5), 2103– 2112 (2015).

[21] [21] J. Frikel, E. T. Quinto, "Artifacts in incomplete data tomography with applications to photoacoustic tomography and sonar," SIAM J. Appl. Math. 75(2), 703–725 (2015).

[22] [22] K. Shen, S. Liu, T. Feng, J. Yuan, B. Zhu, C. Tian, "Negativity artifacts in back-projection based photoacoustic tomography," J. Phys. D: Appl. Phys. 54, 074001 (2021).

[23] [23] H. Nan, T. C. Chou, A. Arbabian, Segmentation and artifact removal in microwave-induced thermoacoustic imaging, 2014 36th Annual Int. Conf. IEEE Engineering in Medicine and Biology Society (2014), pp. 4747–4750.

[24] [24] M. Lazebnik, D. Popovic, L. McCartney, C. B. Watkins, M. J. Lindstrom, J. Harter, S. Sewall, T. Ogilvie, A. Magliocco, T. M. Breslin, W. Temple, D. Mew, J. H. Booske, M. Okoniewski, S. C. Hagness, "A large-scale study of the ultrawideband microwave dielectric properties of normal, benign and malignant breast tissues obtained from cancer surgeries," Phys. Med. Biol. 52(20), 6093–6115 (2007).

[25] [25] M. Lazebnik, L. McCartney, D. Popovic, C. BWatkins, M. J. Lindstrom, J. Harter, S. Sewall, A. Magliocco, J. H. Booske, M. Okoniewski, S. C. Hagness, "A large-scale study of the ultrawideband microwave dielectric properties of normal breast tissue obtained from reduction surgeries," Phys. Med. Biol. 52, 2637–2656 (2007).

[26] [26] E. A. Bermudez, O. R. Rico, "Measurement of complex dielectric permittivity in oils from high voltage transformers using a coaxial prob," Tecciencia 11(21), 61–67 (2016).

[27] [27] Z. Zheng, L. Huang, H. B. Jiang, "Label-free thermoacoustic imaging of human blood vessels in vivo," Appl. Phys. Lett. 113, 253702 (2018).

[28] [28] X. Wang, T. Qin, R. S. Witte, H. Xin, "Computational feasibility study of contrast-enhanced thermoacoustic imaging for breast cancer detection using realistic numerical breast phantoms," IEEE Trans. Microw. Theory Tech. 63, 1489–1501 (2015).

[29] [29] X. Liang, H. Guo, Q. Liu, C. Wu, Y. Gong, L. Xi, "Thermoacoustic endoscopy," Appl. Phys. Lett. 116, 013702 (2020).

[30] [30] X. Feng, F. Gao, Y. Zheng, "Magnetically mediated thermoacoustic imaging toward deeper penetration," Appl. Phys. Lett. 103, 083704 (2013).

[31] [31] I. Wol?, "Electromagnetic fields in lossy open dielectric spheres," 2018 Progress in Electromagnetics Research Symp. (2018), pp. 2520–25

[32] [32] 32. Y. Deng, X. Liu, "Electromagnetic imaging methods for nondestructive evaluation applications," Sensors- Basel 11(12), 11774–11808 (2011).

[33] [33] A. A. Bogdanov, K. L. Koshelev, P. V. Kapitanova, M. V. Rybin, S. A. Gladyshev, Z. F. Sadrieva, K. B. Samusev, Y. S. Kivshar, M. F. Limonov, "Bound states in the continuum and Fano resonances in the strong mode coupling regime," Adv. Photonics 1(1), 016001 (2019).

[34] [34] S. Tungjitkusolmun, E. J. Woo, H. Cao, J. Z. Tsai, V. R. Vorperian, J. G. Webster, "A new catheter design using needle electrode for subendocardial RF ablation of ventricular muscles: Finite element analysis and in vitro experiments," IEEE Trans. Bio-med. Eng. 47(1), 23–31 (2000).

[35] [35] M. Soltani, R. Rahpeima, F. M. Kashkooli, "Breast cancer diagnosis with a microwave thermoacoustic imaging technique—a numerical approach," Med. Biol. Eng. Comput. 57, 1497–1513 (2019).

[36] [36] R. Rahpeima, M. Soltani, F. M. Kashkooli, "Numerical study of microwave induced thermoacoustic imaging for initial detection of cancer of breast on anatomically realistic breast phantom," Comput. Meth. Prog. Biol. 196, 105606 (2020).

[37] [37] X. Wang, T. Qin, R. S. Witte, H. Xin, "Computational feasibility study of contrast enhanced thermoacoustic imaging for breast cancer detection using realistic numerical breast phantoms," IEEE Trans. Microw. Theory Tech. 63(5), 1489–1501 (2015).

[38] [38] L. Xu, X. Wang, "Focused microwave breast hyperthermia monitored by thermoacoustic imaging: A computational feasibility study applying realistic breast phantoms," IEEE J. Electromagn. RF Microw. Med. Biol. 4(2), 81–88 (2020).

[39] [39] H. Qin, Y. Cui, Z. Wu, Q. Chen, D. Xing, "Realtime thermoacoustic imaging-guidance for breast tumor resection," IEEE Photonics J. 12(3), 1 (2020).

[40] [40] Z. Chi, Y. Zhao, J. Yang, T. Li, G. Zhang, H. Jiang, "Thermoacoustic tomography of in vivo human finger joints," IEEE Trans. Biomed. Eng. 66(6), 1598–1608 (2019).

[41] [41] H. Nan, S. Liu, J. G. Buckmaster, A. Arbabian, "Beamforming microwave-induced thermoacoustic imaging for screening applications," IEEE Trans. Microw. Theory Tech. 67(1), 464–474 (2019).