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Project 3: Topological Acoustics (TA) Sensing of the Natural Environment

Essentially, the conventional approach to acoustic sensing has relied on the spectral, intensity response of a system or environment’s sound field. The geometric phase of acoustic waves has hitherto been overlooked and excluded from sensing approaches. Therefore, incorporating the geometric phase in sensing modalities will reinvigorate the field of acoustic or seismic sensing. By exploiting the geometric phase, TA can be a sensing modality for the remote, direct, and continuous monitoring of forested areas. Long-wavelength seismic waves are pertinent for the TA sensing of forested environments. Few-tens of Hz seismic waves interact strongly with trees by resonant scattering that changes the geometric phase. The ground stiffness influences this phase change, which relates to subsurface temperatures changes for permafrost and/or forest-floor moisture levels. NewFoS will demonstrate for forested arctic region the nonlinear behavior and high sensitivity in the change of the geometric phase with the ground state. Theory predicts large detectable changes in phase due to changes in ground stiffness/temperature (up to π/1oC) for frequencies near tree resonances, versus a wave velocity change of only 2–3%/1–3oC for current seismic methods. The power of TA sensing lies in the geometric phase being a sensitive global metric for the wave-scattering environment. The modality of TA sensing of the environment can readily be translated to monitoring degradation of infrastructure in the built environment or the presence of flaws in manufactured parts. Therefore, NewFoS outcomes includes the development of modalities for high sensitivity non-destructive evaluation (NDE) of engineered structures and parts. 

Meet the team

Susan

Susan Beck

University of Arizona

Leading Project 3

slbeck@arizona.edu

 

 

Massimo

Massimo Ruzzene

University of Colorado Boulder

NewFoS Co-PI & Leading Project 3

massimo.ruzzene@colorado.edu

Falk

Falk Huettmann

University of Alaska, Fairbanks

Research Collaborator

fhuettmann@alaska.edu

Keith Runge

Keith Runge

University of Arizona 

Knowledge Transfer Director & Research Collaborator 

krunge@arizona.edu

Marat

Marat Latypov

University of Arizona

Research Collaborator

latmarat@arizona.edu

Pierre

Pierre Deymier

University of Arizona

NewFoS Director & Research Collaborator 

deymier@arizona.edu

Samy

Samy Missoum

University of Arizona

Research Collaborator

smissoum@arizona.edu

 

Kundu

Tribikram Kundu

University of Arizona

Research Collaborator

tkundu@u.arizona.edu

Araceli

Araceli Hernández Granados

University of Arizona

Knowledge Transfer Support

aracelihg@arizona.edu

Abhijit Samadhan Sardar

University of Arizona

Graduate Research Assistant

abhijitsardar@arizona.edu

Bingxu

Bingxu Luo

University of Arizona

Postdoctoral Researcher

bingxuluo@arizona.edu

Elizabeth

Elizabeth Whitney

University of Alaska, Fairbanks

Graduate Research Assistant

ewhitney5@alaska.edu

Guangdong

Guangdong Zhang

University of Arizona

Affiliate Graduate Research Assistant

guangdongzhang@arizona.edu

I-Tzu Huang

University of Arizona

Undergraduate Research Assistant

itzuhuang@arizona.edu

Andy

I-Ting (Andy) Ho

University of Arizona

Lab Manager/Research Support

iho@arizona.edu

Jacob Lewton

University of Colorado Boulder

Graduate Research Assistant

jale6182@colorado.edu

Jiayang

Jiayang (Owen) Wang

University of Arizona

Postdoctoral Researcher

jw1011@arizona.edu

Shruti

Shruti Singh

University of Arizona

Graduate Research Assistant

shrutis@arizona.edu

Sinan

Sinan Sabah Schabib

University of Arizona

Graduate Research Assistant

sinanschabib@arizona.edu

Zhuocheng (Leo) Huang

University of Arizona

Graduate Research Assistant

zhuochenghuang@arizona.edu

Publications

Lata, T. D., Deymier, P. A., Runge, K., Uehara, G. S., & Hodges, T. M. W. (2023). Underwater acoustic sensing using the geometric phase. The Journal of the Acoustical Society of America, 154(5), 2869–2877. https://doi.org/10.1121/10.0022322
Zhang, G., Deymier, P. A., Runge, K., & Kundu, T. (2024) Monitoring damage growth and topographical changes in plate structures using sideband peak count-index and topological acoustic sensing techniques. Ultrasonics, 141, 107354. https://doi.org/10.1016/j.ultras.2024.107354
Zhang, G., Deymier, P. A., Runge, K., & Kundu, T. (2024). Peridynamics based modeling for investigating the effect of topography and topological acoustic sensing performance in monitoring damage growth. Proceedings of the 2024 51st Annual Review of Progress in Quantitative Nondestructive Evaluation. Denver, Colorado. July 21–24, 2024. V001T10A003. ASME. https://doi.org/10.1115/QNDE2024-137228
Zhang, G., Kundu, T., Deymier, P. A., & Runge, K. (2024). A comparative study of geometric phase change- and sideband peak count-based techniques for monitoring damage growth and material nonlinearity. Sensors. 24(20), 6552 https://doi.org/10.3390/s24206552
Ho, I-T., Muralidharan, K., Tin, S., Bayly, D., Gockel, B., Reale, M., & Kundu, T. (2024). Non-destructive evaluation of additively manufactured superalloy IN718 via integrating microfocus X-ray computed tomography and non-linear acoustics. Additive Manufacturing. 96, 104539. https://doi.org/10.1016/j.addma.2024.104539
Runge, K., & Deymier, P. A. (2024). Topological acoustic sensing using the geometric phase. The Journal of the Acoustical Society of America, 155(3_Supplement), A304–A304. https://doi.org/10.1121/10.0027593
Kundu, T., & Zhang, G. (2024). Sideband Peak Count – a new nonlinear ultrasonic technique for monitoring damage progression in engineering materials. E-Journal of Nondestructive Testing, 29(6). https://doi.org/10.58286/29889
Zhang, G., Hu, B., Hamad Alnuaimi, Amjad, U., Deymier, P. A., Runge, K., & Kundu, T. (2024). Numerical modeling with experimental verification investigating the effects of nonlinearities on the sideband peak count-index technique and topological acoustic sensing. 68–68. https://doi.org/10.1117/12.3010021
Ho, I-T., Muralidharan, K., Runge, K., Hernandez Granados, A., Kundu, T., & Deymier, P. A. (2025). Monitoring defects in plates using topological acoustic sensing and sideband peak counting. Ultrasonics. 149, 107568. https://doi.org/10.1016/j.ultras.2025.107568
Zhang, G., Kundu, T., Deymier, P. A., & Runge, K. (2025). Topological acoustic sensing for defect localization in heterogeneous plate structures using Lamb waves. Proc. SPIE, Health Monitoring of Structural and Biological Systems XIX, March 2025, SPIE's Annual International Symposium on Smart Structures and Nondestructive Evaluation, Vancouver, Canada. 13437-5. https://doi.org/10.1117/12.3049106
Zhang, G., Kundu, T., Deymier, P.A., & Runge, K. (2025). Defect localization in heterogeneous plate structures using the geometric phase change – index of Lamb waves. Ultrasonics. 152, 107654. https://doi.org/10.1016/j.ultras.2025.107654
Zhang, G., Kundu, T., Deymier, P. A., & Runge, K. (2025). Defect localization in plate structures using the geometric phase of Lamb waves. Ultrasonics, 145, 107492. https://doi.org/10.1016/j.ultras.2024.107492
Runge, K., & Beck, S. (2025). Seismic Sensing Analysis With Geometric Phase: From Land to Sea. Marine Technology Society Journal, 59(1), 59–61. https://doi.org/10.4031/mtsj.59.1.5
Hu, B., Kundu, T., Deymier, P. A., & Runge, K. (2025). Diagnostic imaging for damage detection in plates based on topological acoustic (TA) sensing technique. Ultrasonics, 107750–107750. https://doi.org/10.1016/j.ultras.2025.107750
Khademitab, M., Ho, I-Ting., Jenssen, E., Heim, M., Gradi, A. J., Beamer, C., Kundu, T., & Mostafaei, A. (2025). Effects of powder recycling, binder deposition, and HIP treatment on structure-property relationships in binder jetted 316 L stainless steel. Materials Today Communications, 113432. https://doi.org/10.1016/j.mtcomm.2025.113432
Ho, I-Ting., Sunder, A., Runge, K., Kundu, T., Luo, B., Beck, S., & Deymier, P. A. (2025). Geometric phase sensing using cross-correlations for structural anomaly detection under broadband and stochastic excitations. Journal of Nondestructive Evaluation Diagnostics and Prognostics of Engineering Systems, 1–24. https://doi.org/10.1115/1.4069302
Ho, I-Ting., Bayly, D., Thome, P., & Tin, S. (2025). A New Method for the Microfocus X-ray Computed Tomography Visualization and Quantitative Exploration of Reinforcement Particles in Additively Manufactured Superalloy IN718. Journal of Nondestructive Evaluation, 44(3). https://doi.org/10.1007/s10921-025-01243-4
Luo, B., Deymier, P.A., Beck, S.L., Runge, K., Huettmann, F., DeVaughn, S., Latypov, M (2025). Geometric phase sensing of environmental conditions using ambient seismic noise: An application from southwest Iceland.  Journal of Geophysical Research: Earth and Space Science.   https://doi.org/10.1029/2025EA004509
Singh, S., Kim, H.-J., & Kundu, T. (2025). Non-destructive characterization of lightweight and sustainable rubber modified cementitious system. Journal of Non-Destructive Testing & Evaluation (JNDE), 22(4), 25–38.
Singh, S., Zeng, H., Amjad, U., Kim, H.-J., & Kundu, T. (2026). Characterization of carbonation curing influence on nonlinear ultrasonic response and mechanical performance of mortar. Materials, 19(5), 874. https://doi.org/10.3390/ma19050874