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1. Contribution of anthropogenic vibration sources to crack growth in natural rock arches

   https://doi.org/10.3389/feart.2022.1035652  

   Finnegan, Riley; Moore, Jeffrey R.; Geimer, Paul R. (October 2022, Frontiers in Earth Science)

   Natural arches are culturally valued rock landforms common in sedimentary rocks of the Colorado Plateau and additionally occur broadly around the world. Recent notable collapses of some of these landforms have highlighted the need to better understand the mechanics of their failure. While environmentally driven weathering has been the focus of most previous studies of arch collapse, comparably little attention has been given to anthropogenic vibration sources and how these often slight- to moderate-magnitude shaking events might steadily weaken arches over time. We collected 12–15 months of continuous ambient vibration data from arches and nearby bedrock in both anthropogenically ‘noisy’ and ‘quiet’ locations and used these datasets to develop an annual model of arch peak ground velocity based on magnitude-cumulative frequency distributions. Working from these models, we added vibration events of varying magnitude or frequency of occurrence, informed by field data, imitating arch vibration in response to different anthropogenic activities such as helicopter flights or induced earthquakes. We then applied subcritical fracture mechanics principles to predict annual crack growth rates in an idealized arch under these different vibration conditions. Our results demonstrate that in a single year, cracks grow minimally longer (∼1%) in ‘noisy’ environments than in areas not experiencing anthropogenic vibration energy. Few (1+) 30-s moderate-magnitude events (∼15 mm/s) or many (>37,000) 30-s low-magnitude events (∼2 mm/s) cause markedly increased crack growth. Our approach provides a valuable new framework for assessing the range and frequency of occurrence of vibrations experienced by an arch, and for predicting arch damage. Our results, in turn, yield important new outputs applicable in support of conservation management of these and similar landforms world-wide under exposure to a range of human-induced vibration activity. 

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2. Sparse Ambient Resonance Measurements Reveal Dynamic Properties of Freestanding Rock Arches

   https://doi.org/10.1029/2020GL087239  

   Geimer, Paul R.; Finnegan, Riley; Moore, Jeffrey R. (May 2020, Geophysical Research Letters)

   Abstract The dynamic properties of freestanding rock landforms are a function of fundamental material and mechanical parameters, facilitating noninvasive vibration‐based structural assessment. Characterization of resonant frequencies, mode shapes, and damping ratios, however, can be challenging at culturally sensitive geologic features, such as rock arches, where physical access is limited. Using sparse ambient vibration measurements, we describe three resonant modes between 1 and 40 Hz for 17 natural arches in Utah spanning a range of lengths from 3–88 m. Modal polarization data are evaluated to combine field observations with 3‐D numerical models. We find outcrop‐scale elastic moduli vary from 0.8 to 8.0 GPa, correlated with diagenetic processes and identify low damping at all sites. Correlation of dense‐array measurements from one arch validates predictions of simple bending modes and fixed boundary conditions. Our results establish use of sparse ambient resonance measurements for structural assessment and monitoring of arches and similar freestanding geologic features worldwide. 

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3. Vibration of natural rock arches and towers excited by helicopter-sourced infrasound

   https://doi.org/10.5194/esurf-9-1459-2021  

   Finnegan, Riley; Moore, Jeffrey R.; Geimer, Paul R. (January 2021, Earth Surface Dynamics)

   Abstract. Helicopters emit high-power infrasound in a frequency range thatcan coincide with the natural frequencies of rock landforms. While a singleprevious study demonstrated that close-proximity helicopter flight was ableto excite potentially damaging vibration of rock pinnacles, the effects on abroader range of landforms remain unknown. We performed a series ofcontrolled flights at seven sandstone arches and towers in Utah, USA,recording their vibration response to helicopter-sourced infrasound. Wefound that landform vibration velocities increased by a factor of up to 1000during close-proximity helicopter flight as compared to ambient conditionsimmediately prior and that precise spectral alignment between infrasoundand landform natural frequencies is required to excite resonance. We defineadmittance as the ratio of vibration velocity to infrasound pressure andrecorded values of up to 0.11 mm s−1 Pa−1. While our resultsdemonstrate a strong vibration response, the measured velocities are lowerthan likely instantaneously damaging values. Our results serve as a basisfor predicting unfavorable degradation of culturally significant rocklandforms due to regular helicopter overflights. 

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4. An update on techniques to assess normal-mode behavior of rock arches by ambient vibrations

   https://doi.org/10.5194/esurf-9-1441-2021  

   Häusler, Mauro; Geimer, Paul Richmond; Finnegan, Riley; Fäh, Donat; Moore, Jeffrey Ralston (January 2021, Earth Surface Dynamics)

   Abstract. Natural rock arches are rare and beautiful geologic landforms with important cultural value. As such, their management requires periodic assessment of structural integrity to understand environmental and anthropogenic influences on arch stability. Measurements of passive seismic vibrations represent a rapid and non-invasive technique to describe the dynamic properties of natural arches, including resonant frequencies, modal damping ratios, and mode shapes, which can be monitored over time for structural health assessment. However, commonly applied spectral analysis tools are often limited in their ability to resolve characteristics of closely spaced or complex higher-order modes. Therefore, we investigate two techniques well-established in the field of civil engineering through application to a set of natural arches previously characterized using polarization analysis and spectral peak-picking techniques. Results from enhanced frequency domain decomposition and parametric covariance-driven stochastic subspace identification modal analyses showed generally good agreement with spectral peak-picking and frequency-dependent polarizationanalyses. However, we show that these advanced techniques offer the capability to resolve closely spaced modes including their corresponding modal damping ratios. In addition, due to preservation of phase information, enhanced frequency domain decomposition allows for direct and convenient three-dimensional visualization of mode shapes. These techniques provide detailed characterization of dynamic parameters, which can be monitored to detect structural changes indicating damage and failure, and in addition have the potential to improve numerical models used for arch stability assessment. Results of our study encourage broad adoption and application of these advanced modal analysis techniques for dynamic analysis of a wide range of geological features. 

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5. The 2023 US 50-State National Seismic Hazard Model: Overview and implications

   https://doi.org/10.1177/87552930231215428  

   Petersen, Mark D; Shumway, Allison M; Powers, Peter M; Field, Edward H; Moschetti, Morgan P; Jaiswal, Kishor S; Milner, Kevin R; Rezaeian, Sanaz; Frankel, Arthur D; Llenos, Andrea L; et al (February 2024, Earthquake Spectra)

   The US National Seismic Hazard Model (NSHM) was updated in 2023 for all 50 states using new science on seismicity, fault ruptures, ground motions, and probabilistic techniques to produce a standard of practice for public policy and other engineering applications (defined for return periods greater than ∼475 or less than ∼10,000 years). Changes in 2023 time-independent seismic hazard (both increases and decreases compared to previous NSHMs) are substantial because the new model considers more data and updated earthquake rupture forecasts and ground-motion components. In developing the 2023 model, we tried to apply best available or applicable science based on advice of co-authors, more than 50 reviewers, and hundreds of hazard scientists and end-users, who attended public workshops and provided technical inputs. The hazard assessment incorporates new catalogs, declustering algorithms, gridded seismicity models, magnitude-scaling equations, fault-based structural and deformation models, multi-fault earthquake rupture forecast models, semi-empirical and simulation-based ground-motion models, and site amplification models conditioned on shear-wave velocities of the upper 30 m of soil and deeper sedimentary basin structures. Seismic hazard calculations yield hazard curves at hundreds of thousands of sites, ground-motion maps, uniform-hazard response spectra, and disaggregations developed for pseudo-spectral accelerations at 21 oscillator periods and two peak parameters, Modified Mercalli Intensity, and 8 site classes required by building codes and other public policy applications. Tests show the new model is consistent with past ShakeMap intensity observations. Sensitivity and uncertainty assessments ensure resulting ground motions are compatible with known hazard information and highlight the range and causes of variability in ground motions. We produce several impact products including building seismic design criteria, intensity maps, planning scenarios, and engineering risk assessments showing the potential physical and social impacts. These applications provide a basis for assessing, planning, and mitigating the effects of future earthquakes. 

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