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b'Acoustic methods in geophysicsFeatureseries data, and of changes in the phenomenon being studied.Hupe, P., Ceranna, L., Le Pichon, A., Matoza, R. S., & Mialle, P., 2022. Such tools for data mining and the analysis of very large timeInternational Monitoring System infrasound data products for series data sets may support the ongoing development andatmospheric studies and civilian applications. Earth Syst. Sci. application of acoustic methods for geophysical applications.Data Discuss., 2022, 1-40. doi:10.5194/essd-2021-441This may also be supported by the growing availability ofJackson, L. C., Biastoch, A., Buckley, M. W., Desbruyres, D. G., smartphone apps such as RedVox (https://www.redvoxsound. Frajka-Williams, E., Moat, B., & Robson, J., 2022. The evolution com/) for recording infrasound and sharing the data with aof the North Atlantic Meridional Overturning Circulation global community of users, as well as by relatively inexpensivesince 1980. Nature Reviews Earth & Environment, 3(4), 241-254. hardware for both audible frequencies (e.g. the Kinabaludoi:10.1038/s43017-022-00263-2recorder, Karlsson etal. 2021) and infrasound, often with designJohnson, J. B., Watson, L. M., Palma, J. L., Dunham, E. M., details in the public domain. An example for infrasound is the& Anderson, J. F., 2018. Forecasting the Eruption of an Raspberry Boom (RBOOM)(https://shop.raspberryshake.org/ Open-Vent Volcano Using Resonant Infrasound Tones. product/turnkey-iot-atmospheric-infrasound-monitor-rboom/). Geophysical Research Letters, 45(5), 2213-2220. doi:https://doi.org/10.1002/2017GL076506References Karlsson, E. C. M., Tay, H., Imbun, P., & Hughes, A. C., 2021. The Kinabalu Recorder, a new passive acoustic and Alexander, R. L., OModhrain, S., Roberts, D. A., Gilbert, J. A., andenvironmental monitoring recorder. Methods in Ecology Zurbuchen, T.H, 2014. 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C., 2020.doi:10.1146/annurev-earth-072420-065213Distributed Acoustic Sensing as a DistributedLiu, D.-l., Leng, X.-p., Wei, F.-q., Zhang, S.-j., & Hong, Y., 2015. Hydraulic Sensor in Fractured Bedrock. Water ResourcesMonitoring and recognition of debris flow infrasonic signals. Research, 56(9), e2020WR028140. doi:https://doi. Journal of Mountain Science, 12(4), 797-815. doi:10.1007/org/10.1029/2020WR028140 s11629-015-3471-4Bedard, A. J., 2021. Waterfall low-frequency vibrations andLorenz, R. D., Balme, M. R., Gu, Z., Kahanp, H., Klose, M., infrasound: implications for avian migration and hazardKurgansky, M. V., . . . Wei, W., 2016. History and Applications detection. Journal of Comparative Physiology A, 207(6), 685- of Dust Devil Studies. Space Science Reviews, 203(1), 5-37. 700. doi:10.1007/s00359-021-01510-5 doi:10.1007/s11214-016-0239-2Collins, B. D., Stock, G. M., Eppes, M.-C., Lewis, S. W., Corbett, S.Lorenz, R. D., & Christie, D., 2015. Dust devil signatures in C., & Smith, J. 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Geophysicalcharacteristic mechanisms of infrasonic precursors during the Research Letters, 40(9), 1748-1753. doi:https://doi. damage process of impending earthquake sources. PLoS One, org/10.1002/grl.50384 16(10), e0257345. doi:10.1371/journal.pone.0257345JUNE 2022 PREVIEW 46'