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Seismic wave

Seismic waves are waves of that propagate through the or along its surface, typically generated by the sudden release of during earthquakes, volcanic eruptions, or human-induced events like explosions. These waves carry from their source outward in all directions, causing the ground to shake and providing critical data for understanding seismic events. Seismic waves are broadly classified into two categories: , which travel through the Earth's interior, and , which travel along the surface. Body waves include (primary waves), which are compressional and move parallel to their direction of propagation at speeds up to 8 km/s in the crust, compressing and expanding the material they pass through; and (secondary waves), which are shear waves that move material perpendicular to their propagation direction at about 60% of P-wave speed, unable to travel through liquids. Surface waves, such as and , are slower than body waves but often cause the most damage due to their larger amplitudes and longer durations, rolling along the surface like ocean waves. The propagation of seismic waves varies with the Earth's internal structure, as their speed and path are influenced by changes in density and material properties at layer boundaries. P waves refract and reflect at interfaces like the core-mantle boundary, creating shadow zones where certain waves do not arrive, while S waves are blocked entirely in the liquid outer core. Seismologists use these wave behaviors, recorded on seismographs as seismograms, to determine earthquake locations via of arrival times and to map the Earth's interior, revealing discoveries such as the solid inner and molten outer . Additionally, seismic waves enable the calculation of and , aiding in hazard assessment and mitigation strategies.

Fundamentals

Definition and Properties

Seismic waves are elastic waves that propagate through the Earth or other planetary bodies, generated by the sudden release of stress in the solid crust or mantle, and they carry energy from the source to distant detectors. These waves manifest as vibrations or disturbances in the elastic medium, transmitting mechanical energy without the permanent displacement of material. The term "seismic" derives from the Greek word seismos, meaning earthquake, reflecting their primary association with such events. Key properties of seismic waves include , which is the distance between successive wave crests; , the number of wave cycles per unit time; and , which measures the maximum of particles from their position and relates to the wave's . Particle motion varies, being either longitudinal ( to the direction of , causing and ) or transverse (perpendicular to , causing ). describes the orientation of particle motion in transverse waves, while wave depends on the elasticity and of the medium, with stiffer and less dense materials allowing faster . Seismic waves were first systematically observed and studied in association with earthquakes in the late , particularly through the pioneering work of John Milne, who developed the first horizontal seismograph capable of recording distant seismic events while working in . Milne's instruments and research established foundational methods for detecting and analyzing these waves globally. Unlike electromagnetic waves, which can propagate through , seismic waves are mechanical and require a solid, liquid, or gaseous medium for transmission, as they rely on interactions between particles in the material. Seismic waves encompass both body waves that travel through the Earth's interior and surface waves that propagate along the exterior.

Generation Mechanisms

Seismic waves are primarily generated through the sudden release of stored elastic strain energy in the , most commonly during earthquakes caused by frictional slip along faults. According to the , tectonic stresses accumulate over time due to plate movements, deforming rocks elastically until the stress exceeds the fault's frictional strength, leading to rapid slip and energy release in the form of seismic waves. This process begins at the , the subsurface point where rupture initiates, and propagates along the fault plane through dynamic rupture, converting stored into and radiated elastic waves. The initial slip at the source produces both compressional (P-wave) and shear (S-wave) components, with the frequency content of the generated waves typically decreasing as source size increases and rupture speed varies; rupture speeds in earthquakes often range from 2 to 3 km/s, influencing the spectrum of radiated energy. Other natural mechanisms include volcanic activity and landslides. In volcanic settings, seismic waves arise from the movement of , gas, or fluids within the volcano's plumbing system, or from explosive eruptions and associated ground deformation, generating volcano-tectonic earthquakes that mimic tectonic slip events. Landslides produce seismic waves through the sudden acceleration and impact of displaced rock and soil masses, creating impulsive signals from the kinetic energy of the sliding material, as observed in events like the where ground vibrations were recorded up to tens of kilometers away. Artificial sources generate seismic waves through controlled or incidental releases for industrial or scientific purposes. Explosions in operations or underground tests create isotropic wave radiation by rapidly expanding shock waves from the , inducing smaller earthquakes with magnitudes typically below 6.0. In seismic surveys, controlled sources such as vibroseis trucks on land or air guns in marine environments produce repeatable wave pulses by generating vibrations or pressure releases, allowing for high-resolution imaging of subsurface structures. Among natural sources, megathrust earthquakes along zones produce the largest seismic waves due to their extensive fault ruptures and immense energy release. The in , with a of 9.5, exemplifies this, as its rupture along the Nazca-South American plate boundary generated surface waves that circled the globe multiple times and triggered trans-Pacific tsunamis with waves up to 25 meters high.

Wave Types

Body Waves

Body waves are seismic waves that propagate through the volume of the , traveling in nearly straight paths from the source to the receiver. They are divided into two main types: P-waves, also known as primary waves, which are compressional and involve longitudinal particle motion; and S-waves, or secondary waves, which are shear waves with transverse particle motion. P-waves are faster and arrive first at seismic stations, while S-waves follow due to their lower speed. In P-waves, particles of the medium oscillate parallel to the direction of wave propagation, resulting in alternating and along the wave . S-waves, in contrast, cause particles to move perpendicular to the propagation direction, either side-to-side or up-and-down relative to the wave's travel. This transverse motion in S-waves requires a solid medium to transmit , distinguishing them from P-waves, which can propagate through solids, liquids, and gases. Typical velocities for P-waves in the range from 5 to 8 km/s, while S-waves travel at 3 to 4.5 km/s, with the ratio of P- to S-wave speeds often around 1.7 to 1.8. Both P- and S-wave velocities generally increase with depth in the Earth due to the rising from overlying material, which stiffens and enhances wave efficiency, though temperature effects can modulate this trend. S-waves cannot propagate through liquid regions, such as the , because liquids do not support shear stresses, leading to S-wave zones where these waves are absent beyond approximately 103° from the . P-waves, however, can traverse the outer but refract due to the velocity change at the core-mantle , allowing their detection in the zone for S-waves. S-waves are further classified by : SV-waves, where particle motion occurs in the vertical plane containing the direction, and SH-waves, with motion in the horizontal plane perpendicular to . These polarizations affect how S-waves interact with layered media and are key in seismic studies. Unlike surface waves, body waves travel faster through the 's interior and typically produce less intense ground motion at the surface, though their arrival provides critical data for analysis.

Surface Waves

Surface waves are seismic waves that propagate along the 's surface or along interfaces between layers within the , typically exhibiting lower velocities and higher amplitudes compared to body waves. These waves are dispersive, meaning their varies with , which leads to different components traveling at different speeds and spreading out over . They are generated primarily by the interaction of body waves with the surface or layer boundaries, often resulting from s or explosions, and they tend to dominate the later arrivals on seismograms after the initial body wave phases. Rayleigh waves, named after Lord Rayleigh who predicted them theoretically in 1885, involve particle motion that traces an elliptical, retrograde path in the vertical plane aligned with the direction of propagation. Their speed is approximately 0.9 times that of (S) waves in the same medium, typically ranging from 2 to 4 km/s in crustal rocks, and they are particularly prominent in soft sediments where they can amplify ground motion due to lower velocities in unconsolidated materials. These waves roll along the surface similar to ocean waves but with combined vertical and horizontal components, making them a primary contributor to surface deformation. Love waves, proposed by in 1911, feature horizontal particle motion transverse to the propagation direction, with no vertical component, resembling shear waves confined to the surface. They arise from the guiding of (horizontal shear) body waves in layered media with a low-velocity surface layer over a higher-velocity substrate, such as over , and their velocities lie between those of S waves and waves, often 2.5 to 4.5 km/s depending on and structure. Love waves require horizontal layering for their existence and are less affected by fluid-saturated layers compared to other surface waves. Stoneley waves occur at interfaces between two solids or between a solid and a fluid, such as in boreholes filled with drilling mud adjacent to rock formations. They propagate as guided waves along the boundary, with motion involving both the solid and fluid, and play a minor role in global seismology but are crucial for borehole logging where they provide information on formation permeability, fractures, and interface properties. Their velocity is slower than that of compressional waves in the surrounding media, typically around 1.5 km/s in fluid-filled boreholes. Normal modes represent the free oscillations of the entire as a whole, excited by large earthquakes, and include spheroidal modes with radial and tangential displacements (analogous to waves) and toroidal modes with purely tangential, rotational displacements (analogous to Love waves). These modes have periods ranging from tens of minutes to hours, with fundamental spheroidal modes around 20 minutes and extending longer, allowing them to be observed globally as standing waves that circle the planet multiple times. They provide insights into 's deep internal structure through their eigenfrequencies. Surface waves are responsible for the majority of structural damage in earthquakes due to their larger amplitudes and prolonged duration of shaking, which can resonate with and . In the 1985 Michoacán earthquake (magnitude 8.0), Rayleigh waves trapped and amplified within the soft of caused extreme ground motions lasting over two minutes, leading to the collapse of numerous mid-rise tuned to periods of 1-2 seconds and resulting in thousands of casualties.

Propagation and Interaction

Travel Through Earth Layers

Seismic P-waves and S-waves propagate through 's interior by refracting at major discontinuities due to abrupt changes in wave velocities caused by variations in material density and composition. At the , which separates the crust from the mantle at depths of approximately 5–10 km beneath and 20–90 km under , both wave types experience a sudden increase in velocity as they enter the denser mantle rocks, leading to upward refraction of their paths. Similarly, at the core-mantle boundary around 2,900 km depth, P-waves refract sharply due to a velocity drop from the solid mantle into the liquid outer core, while S-waves are blocked entirely. In the mantle, both P- and S-waves accelerate with increasing depth owing to rising and gradients that enhance rigidity, as modeled by the (PREM). According to PREM, P-wave velocities rise from about 8 km/s near the surface to roughly 13 km/s just above the core-mantle boundary, while S-wave velocities increase from around 4.5 km/s near the surface to about 7 km/s at the boundary. S-waves cannot propagate through the outer core because of its liquid state, resulting in their complete absence beyond this layer. Within the core, P-waves decelerate to approximately 8 /s in the liquid outer core due to the reduced rigidity of the molten iron-nickel , then accelerate to about 11 /s upon entering the solid inner core at around 5,150 depth, where shear strength returns. This blockage of S-waves creates an S-wave on Earth's surface, spanning angular distances of 103° to 180° from the , where no direct S-waves arrive because their paths are obstructed by the outer . The P-wave , a weaker effect from , lies between 103° and 142° but is less pronounced as some P-waves graze the core and emerge. Seismic wave paths include direct traversals through , reflected variants such as (P-wave reflected at the core-mantle boundary) and (S-wave reflected there), and refracted core phases like PKP, which denotes a P-wave that enters the outer , travels through it, and exits back into . Travel-time curves for these phases exhibit branching patterns, with core-penetrating arrivals like PKP appearing later and more dispersed due to the slower velocities and longer paths involved. The existence of Earth's core was first inferred in 1906 by Richard Dixon Oldham, who analyzed seismograms from distant earthquakes and noted the absence of S-waves beyond about 100°–120° angular distance, indicating a central region impermeable to shear waves. In 1913, Beno Gutenberg refined this understanding by confirming the outer core's liquidity through detailed measurements of P-wave slowdowns and the precise boundaries, establishing the at the core-mantle interface. The solid inner core was discovered in 1936 by Inge Lehmann, who identified accelerations in P-wave velocities on seismograms from distant earthquakes, indicating a solid central region within the liquid outer core.

Reflection, Refraction, and Attenuation

Seismic waves reflect at interfaces between media with contrasting acoustic properties, such as or discontinuities. This reflection arises when part of the wave's energy bounces back upon encountering the , with the reflected governed by the contrast, defined as the product of and seismic . Stronger contrasts, like those at sediment-basement interfaces, produce larger reflections, while weaker ones yield minimal energy return; for instance, the Earth's acts as a perfect reflector, generating surface multiples that propagate back into the subsurface. Refraction occurs as seismic waves traverse regions of varying , causing the ray path to bend toward the normal in faster media and away in slower ones, in accordance with : the sine of the incidence angle divided by the velocity in the first medium equals the sine of the refraction angle divided by the velocity in the second. This bending is pronounced at gradual velocity gradients, such as those in the crust or . In models incorporating low-velocity zones, can produce triplications, where waves following divergent paths arrive in overlapping clusters, complicating travel-time interpretations but revealing subsurface structure. Attenuation describes the progressive loss of seismic wave , primarily through anelastic processes involving internal in viscoelastic materials and by small-scale heterogeneities that redirect . These mechanisms dissipate wave amplitude exponentially with distance and are characterized by the quality factor , defined as Q = 2\pi \times \frac{\text{stored [energy](/page/Energy)}}{\text{[energy](/page/Energy) lost per cycle}}, where higher values (e.g., 300–500 in ) indicate lower . Attenuation exhibits frequency dependence, with higher frequencies attenuating more rapidly due to increased interaction with material defects, resulting in the selective of short-period signals over long distances. Geometric spreading contributes to amplitude reduction independent of material properties, as wave energy distributes over an expanding . For body waves propagating spherically, amplitude decreases as $1/r, where r is the radial distance, reflecting the of energy dilution. Surface waves, confined to two dimensions, exhibit slower decay proportional to $1/\sqrt{r}, allowing them to maintain higher amplitudes at teleseismic distances. Mantle anisotropy, stemming from lattice-preferred orientation of minerals like , induces directionally dependent velocity variations, altering reflection and paths based on wave and azimuth. This azimuthal influences wave speeds by up to 5–10% in the , complicating isotropic models. Recent global Q models, constructed using dense seismic arrays such as USArray and international networks, map lateral variations in , highlighting low-Q zones linked to partial melt or high temperatures, with resolutions improving to ~500 km scale.

Detection and Analysis

Measurement Techniques

The measurement of seismic waves began in the late with the development of mechanical seismographs, such as the horizontal instrument invented by Ernst von Rebeur-Paschwitz, which recorded the first teleseismic event on April 17, 1889, in Potsdam, Germany, detecting ground motion from a distant in . These early devices used inertial masses suspended by to register horizontal or vertical displacements on or smoked drums, providing qualitative records of wave arrivals but limited by low sensitivity and analog constraints. Modern seismographs have evolved to instruments capable of capturing a wide of frequencies and . The Streckeisen , introduced in the , exemplifies this advancement as a very-broadband with a exceeding 140 and a from approximately 2.8 mHz to 10 Hz, enabling high-fidelity recordings of both weak teleseismic signals and local events. These sensors employ force-feedback mechanisms to maintain linear response across vast amplitude scales, far surpassing the capabilities of early mechanical systems. Seismic sensors vary by the physical quantity they measure and their intended application. Velocity sensors, such as geophones, detect ground velocity and are widely used in exploration for their sensitivity to higher-frequency waves in the 10-100 Hz range, often deployed in arrays for subsurface imaging. sensors, or strong-motion accelerometers, measure ground during intense shaking, with ranges up to 3.5 , and are essential for assessments of structural response to earthquakes. Strainmeters complement these by quantifying crustal or tilt through relative displacements over baselines of meters to kilometers, providing data on slow deformations and low-frequency tilts that traditional seismometers may miss. Global and regional seismic networks integrate these sensors for comprehensive monitoring. The Incorporated Research Institutions for Seismology (IRIS) manages the Global Seismographic Network (GSN), comprising 152 broadband stations worldwide (as of 2025) that deliver real-time digital data for studying Earth's interior. Similarly, the GEOSCOPE network, operated by the Institut de Physique du Globe de Paris, maintains 33 very-broadband stations (as of 2025) focused on global and Earth's dynamics, with data freely accessible via the International Federation of Digital Seismograph Networks. Local arrays, such as those in tectonic zones, enhance resolution through dense deployments of geophones or accelerometers. The transition to digital recording in the 1970s, spurred by advances in magnetic tape and early computers, dramatically increased data volume and accessibility, replacing analog film with quantifiable traces that facilitated quantitative analysis. A landmark in this evolution was the World-Wide Standardized Seismograph Network (WWSSN), established in the early 1960s with approximately 120 standardized analog stations, which provided uniform high-quality data that confirmed key evidence for plate tectonics, including consistent body-wave patterns across global events. Seismograms from such networks typically display primary (P) and secondary (S) wave arrivals as sharp onsets, followed by longer surface wave trains that dominate later portions of the record, with amplitudes reflecting wave propagation effects like attenuation. Data processing involves filtering to mitigate , such as microseismic or cultural interference, using techniques like or transforms to isolate seismic signals while preserving character. Innovations include fiber-optic (DAS), which repurposes existing telecommunication cables as dense sensor arrays (channels spaced ~1 m apart) for high-resolution recordings over kilometers; deployments since 2020, including ocean-bottom applications in 2023-2025, have demonstrated its utility in capturing microseismic events and near-surface structures with unprecedented spatial .

Locating Seismic Events

Locating seismic events relies on the analysis of arrival times of primary (P) and secondary (S) recorded at multiple seismograph stations. The time difference between S and P wave arrivals, known as the S-P interval, provides an estimate of the distance from the source to each station, as P waves travel faster than S waves through Earth's materials. This interval approximates the source distance divided by the difference in their velocities (Vp - Vs), enabling to pinpoint the . To determine the , including depth, data from at least three stations are required for the via geometric of circles. Absolute travel times are computed using one-dimensional models, such as the iasp91 model, which parameterizes seismic velocities radially for predictions of arrivals. Depth is resolved through modeling, where synthetic seismograms are matched to observed data to constrain parameters, or by analyzing depth phases like , which is the S reflecting as a P wave off the near the , yielding time differences sensitive to focal depth. Earthquake magnitudes are calculated post-location to quantify event size. The local magnitude scale () is derived from the maximum amplitude of recorded waves on a Wood-Anderson seismograph, calibrated for local distances up to about 600 km and originally defined for events. The moment magnitude (Mw), preferred for larger events, is based on the , calculated as the product of , rupture area, and average slip, derived from long-period waveform analysis of body and surface waves. Errors in location arise primarily from inaccuracies in velocity models, which can bias travel-time predictions, and from sparse station coverage, leading to poor azimuthal distribution and larger uncertainties in epicenter and depth. Integration of real-time Global Positioning System (GPS) data with seismic records improves accuracy by providing independent measures of ground displacement, enabling rapid finite-fault modeling and refined hypocenters during events. The U.S. Geological Survey initiated routine earthquake locations in the 1920s, coinciding with the deployment of the Wood-Anderson seismometer network for monitoring local seismicity in California. Advances in machine learning for phase picking include PhaseNet (2019) and more recent transformer-based methods (as of 2025), which automate precise P and S phase identification from continuous waveforms, enhancing location efficiency for large datasets and supporting real-time earthquake early warning systems.

Applications

Earthquake Seismology

Earthquake seismology relies on the analysis of seismic waves generated by natural tectonic events to probe Earth's interior, assess risks, and monitor global seismic activity. These waves, originating from fault ruptures during earthquakes, carry information about the source mechanism, propagation path, and local site conditions, enabling scientists to reconstruct rupture dynamics and infer subsurface structures. Unlike controlled sources used in other fields, earthquake-generated waves provide snapshots of dynamic processes in active fault zones, contributing to a deeper understanding of plate tectonics and seismic hazards. Seismic wave plays a crucial role in revealing tectonic structures, such as fault zones and slabs, by mapping variations that indicate material properties and thermal states. Tomographic techniques analyze travel-time delays of - and S-waves from multiple s to construct three-dimensional models of the subsurface, identifying high- (high-Vp) anomalies associated with cold, rigid subducting slabs. For instance, in zones like the , these high-Vp regions correspond to descending that remains cooler than surrounding , influencing and . Such has delineated slab geometries in regions like the Mariana zone, where local highlights contrasts at slab interfaces. In hazard assessment, seismic waves inform predictions of ground shaking intensity through ground motion prediction equations (GMPEs), which relate wave amplitudes to , distance, and source characteristics. These empirical models, such as those developed for horizontal-component motions, use observed peak ground accelerations and spectral values from body and surface waves to estimate shaking levels for probabilistic maps. Site effects further modify wave propagation, with sedimentary basins causing of low-frequency waves due to constructive and trapping, potentially increasing ground motions by factors of 2–3 in urban areas like the . This basin exacerbates damage during events, as seen in simulations of wave in deep basins. Global monitoring leverages seismic waves for real-time applications, including earthquake early warning systems that detect initial P-waves to forecast impending stronger shaking. The system, operational across the U.S. , processes P-wave arrivals from a dense network to issue alerts seconds before S-waves and surface waves arrive, allowing actions like slowing trains or protecting infrastructure. Additionally, surface waves from large submarine earthquakes contribute to tsunami generation by coupling with ocean displacements, where vertical seafloor motion from Rayleigh waves transfers energy to long-period water waves that propagate across oceans. Event location, determined from wave arrival times, serves as a prerequisite for these alerts. A prominent example is the 2011 Tohoku-Oki earthquake (Mw 9.0), where back-projection analysis of teleseismic waves imaged the rupture propagating northward along the interface at approximately 2 km/s, revealing a complex sequence of slip patches that released energy over 150 seconds. This wave-based imaging highlighted the up-dip migration of the rupture toward the , culminating in shallow slip exceeding 50 meters and triggering a devastating . Recent advances in earthquake seismology incorporate to enhance forecasting using seismic wave data, addressing gaps in traditional models. Post-2020 approaches, such as neural point processes trained on continuous , improve predictions by automating phase picking and identifying patterns in wave energies from mainshocks and , achieving higher accuracy in spatial and temporal forecasts for sequences like those following the 2023 Turkey earthquakes. As of 2025, has further advanced by generating earthquake catalogs approximately five times more complete than traditional methods and improving through integration with observational data. These methods integrate geophysical constraints with features to model triggering mechanisms, outperforming epidemic-type sequence models in probabilistic assessments.

Exploration Seismology

Exploration seismology employs artificially generated seismic waves to image subsurface structures for resource extraction and , primarily distinguishing itself from natural studies by using controlled sources to achieve high-resolution profiles. This technique originated with the first commercial application in the 1920s in the , where surveys detected salt domes for oil exploration. Key methods include , which produces stacked profiles by emitting waves from controlled sources and recording echoes from geological interfaces, and seismology, which measures wave bending to determine shallow profiles for site assessment. In , land-based surveys utilize vibroseis trucks that generate controlled vibrations across a range of 10 to 60 Hz to penetrate deeper layers, while marine operations deploy arrays to release high-pressure air bubbles, creating acoustic pulses that propagate through and . These methods stack multiple traces to enhance signal-to-noise ratios, forming detailed images of subsurface reflectors. , conversely, excels in shallow investigations by analyzing first-arrival times of refracted waves along layer boundaries, providing models for depths up to several hundred meters. Primary applications focus on and gas reservoir , where reflections reveal "bright spots"—high-amplitude anomalies caused by impedance contrasts between hydrocarbon-filled rocks and surrounding formations, aiding in . Seismic methods also characterize geothermal reservoirs by delineating permeable zones through and analysis, and CO2 storage sites by integrity and injection horizons to ensure containment. P-waves serve as the main imaging tool due to their faster propagation and lower attenuation in fluids, enabling clear stratigraphic mapping. Converted waves, such as PS modes where a downgoing P-wave reflects as an S-wave, enhance fluid detection by providing sensitivity that distinguishes gas from through velocity ratios. surveys offer volumetric imaging for complex reservoirs, while time-lapse surveys repeat acquisitions to monitor production-induced changes, such as fluid migration or pressure variations, over time. Modern advancements include full-waveform inversion (FWI), implemented widely since the 2000s, which iteratively matches observed and modeled waveforms to build high-resolution velocity models, improving depth imaging accuracy beyond traditional methods. As of 2025, is increasingly applied to simulate realistic seismic wavefields and enhance for subsurface imaging. Environmental considerations are integral, with noise reduction techniques like source signature minimizing , and marine surveys incorporating for impacts, such as procedures to protect marine mammals from hearing damage and behavioral disruption.

Mathematical Framework

Notation and Basic Equations

In , standard notation for seismic wave propagation includes the mass density \rho, typically measured in kg/m³, which influences wave speeds and . The \lambda and \mu describe the elastic properties of isotropic , where \lambda relates to and \mu (the ) to rigidity, both in units of . Compressional (P-wave) velocity is denoted V_p and (S-wave) velocity as V_s, representing the speeds of longitudinal and transverse waves, respectively. Additionally, \omega signifies in rad/s, and k the in rad/m, linking spatial and temporal wave characteristics via the \omega = c k, where c is . The foundational wave equation for seismic displacements in homogeneous isotropic media is the scalar form \nabla^2 u = \frac{1}{c^2} \frac{\partial^2 u}{\partial t^2}, where u is the displacement field and c the , approximating propagation for either P- or S-waves when specialized. This governs the time evolution of disturbances, with solutions representing traveling waves. The constitutive relation from for linear isotropic elasticity connects stress \sigma and strain \epsilon tensors as \sigma = \lambda (\operatorname{tr} \epsilon) I + 2\mu \epsilon, where \operatorname{tr} \epsilon is the trace of the strain tensor and I the tensor; this equation links mechanical deformation to elastic forces driving wave propagation. For anisotropic media, such as crystalline rocks, the Christoffel equation determines and polarizations: \det(\Gamma_{ij} - \rho v^2 \delta_{ij}) = 0, where \Gamma_{ij} = c_{ijkl} n_k n_l is the Christoffel tensor formed from the tensor c_{ijkl} and unit propagation direction \mathbf{n}, with v the and \delta_{ij} the . This eigenvalue problem yields three solutions corresponding to quasi-P, quasi-SV, and quasi-SH waves, essential for modeling velocity in the . Common units in seismic analysis include velocities V_p and V_s in km/s, reflecting typical crustal scales (e.g., 5–8 km/s for V_p), and travel times in seconds for event location. The seismic moment M_0, quantifying source strength, is given by M_0 = \mu A D, where \mu is shear modulus, A the rupture area, and D the average slip, with M_0 in N·m.

Wave Speed Formulas

In isotropic elastic media, the speed of compressional (P) waves is given by the formula V_p = \sqrt{\frac{\lambda + 2\mu}{\rho}} = \sqrt{\frac{K + \frac{4}{3}\mu}{\rho}}, where \lambda and \mu are the Lamé parameters, \rho is the density, K is the bulk modulus, and \mu is the shear modulus. The speed of shear (S) waves is V_s = \sqrt{\frac{\mu}{\rho}}. These expressions arise from the linear constitutive relations and the in solids. \sigma, which relates the lateral to the axial under uniaxial , connects P- and S-wave speeds via \sigma = \frac{V_p^2 - 2V_s^2}{2(V_p^2 - V_s^2)}. For a solid where \lambda = \mu, this yields \sigma = 0.25, a value typical for many crustal rocks in models. The velocities derive from the elastic , specifically Navier's equation \rho \ddot{\mathbf{u}} = (\lambda + 2\mu) \nabla (\nabla \cdot \mathbf{u}) - \mu \nabla \times (\nabla \times \mathbf{u}), by assuming solutions of the form \mathbf{u} = \mathbf{A} e^{i(\mathbf{k} \cdot \mathbf{x} - \omega t)}. Substituting yields the \omega = c k, where the c emerges from the Christoffel equation for longitudinal (P-wave) and transverse (S-wave) polarizations in isotropic media, decoupling into scalar and vector potentials. Wave speeds vary with depth due to changes in elastic properties and density, as parameterized in the Preliminary Reference Earth Model (PREM), where V_p(z) and V_s(z) are tabulated or interpolated from spherical Earth integrals fitting global seismic data; for example, V_p increases from about 6 km/s in the upper crust to over 13 km/s in the lower mantle. Anelastic effects introduce attenuation, modifying the elastic velocity to a complex form V = V_{\text{elastic}} / (1 + i/(2Q)), where Q is the quality factor quantifying energy loss per cycle; this correction accounts for slight dispersion and imaginary components in viscoelastic propagation.

References

  1. [1]
    The Science of Earthquakes | U.S. Geological Survey - USGS.gov
    The energy radiates outward from the fault in all directions in the form of seismic waves like ripples on a pond. The seismic waves shake the earth as they move ...
  2. [2]
    Seismic Waves and Earth's Interior
    Seismic waves are propagating vibrations that carry energy from the source of the shaking outward in all directions.Missing: authoritative | Show results with:authoritative
  3. [3]
    Body waves inside the earth - Earthquake Hazards Program
    Both P and S waves travel outward from an earthquake focus inside the earth. The waves are often seen as separate arrivals recorded on seismographs.
  4. [4]
    Exploring the Earth Using Seismology - IRIS
    Earthquakes create seismic waves that travel through the Earth. By analyzing these seismic waves, seismologists can explore the Earth's deep interior.
  5. [5]
    Seismic Waves and Determining Earth's Structure
    Seismic waves are vibrations in the earth that transmit energy and occur during seismic activity such as earthquakes, volcanic eruptions, and even man-made ...Missing: authoritative | Show results with:authoritative
  6. [6]
    Seismology - Michigan Technological University
    What are Seismic Waves? Seismic waves are caused by the sudden movement of materials within the Earth, such as slip along a fault during an earthquake. ...Missing: properties | Show results with:properties<|control11|><|separator|>
  7. [7]
    Seismic Wave Demonstrations and Animations - Purdue University
    Feb 26, 2010 · Wave characteristics and particle motions of these wave types can be easily illustrated using the seismic wave animations.
  8. [8]
    9.1 Understanding Earth through Seismology – Physical Geology
    Seismology is the study of vibrations within Earth. These vibrations are caused by various events, including earthquakes, extraterrestrial impacts, explosions, ...
  9. [9]
    John Milne's contributions to modern seismology | SAGE - IRIS
    Dec 2, 2021 · John Milne's notable contributions include the development of a horizontal seismograph capable of recording earthquakes globally.Missing: history | Show results with:history
  10. [10]
    Understanding Earthquakes: History of Seismology to 1910
    In Japan, three English professors, John Milne, James Ewing, and Thomas Gray, working at the Imperial College of Tokyo, invented the first seismic instruments ...
  11. [11]
    Wave and Wave Properties - University of Hawaii at Manoa
    The two main types of waves are mechanical waves and electromagnetic waves. Mechanical waves are disturbances in any medium or substance. Examples of ...
  12. [12]
    Earthquakes and Seismic Waves
    Earthquakes release energy as seismic waves, revealing Earth's interior and helping locate quake sources to understand tectonic processes and earthquake ...Missing: definition properties
  13. [13]
    Earthquakes & Earth's Interior - Tulane University
    Sep 24, 2015 · The study of how seismic waves behave in the Earth is called seismology. Seismic waves are measured and recorded on instruments called ...<|control11|><|separator|>
  14. [14]
    Geology of the earthquake source: an introduction - Lyell Collection
    Earthquakes arise from frictional 'stick–slip' instabilities as elastic strain is released by shear failure, almost always on a pre-existing fault.Earthquake Mechanism And... · Earthquake Size And Scaling... · Chapters In This Volume
  15. [15]
    The rupture extent of low frequency earthquakes near Parkfield, CA
    Models and observations suggest that earthquake ruptures usually progress at speeds of 2–3 km s–1, or 60–95 per cent of the shear wave speed Vs (Kanamori ...
  16. [16]
    Monitoring Volcano Seismicity Provides Insight to Volcanic Structure
    Volcano seismologists study several types of seismic events to better understand how magma and gases move towards the surface.
  17. [17]
    Seismic signals generated by the March 22nd Oso Landslide
    Mar 26, 2014 · The seismic signals (ground vibrations) generated by the motion of the Oso landslide were very well recorded by the Pacific Northwest Seismic Network (PNSN).
  18. [18]
    Can nuclear explosions cause earthquakes? | U.S. Geological Survey
    A nuclear explosion can cause an earthquake and even an aftershock sequence. However, earthquakes induced by explosions have been much smaller than the ...
  19. [19]
    The Defining Series: Beginner's Guide to Seismic Surveying - SLB
    Sep 9, 2015 · Sound waves are examples of P-waves. During reflection seismic surveys, seismic waves are generated at or near the Earth surface using a seismic ...
  20. [20]
    M 9.5 - 1960 Great Chilean Earthquake (Valdivia Earthquake)
    Waves as high as 5.5 m (18 ft) struck northern Honshu about 1 day ... This quake was preceded by 4 foreshocks bigger than magnitude 7.0, including ...
  21. [21]
    Earthquakes - General Interest Publication - USGS.gov
    Nov 30, 2016 · P waves push tiny particles of Earth material directly ahead of them or displace the particles directly behind their line of travel. Shear waves ...
  22. [22]
    [PDF] CRUST 5.1: A global crustal model at 5° × 5° - Walter D. Mooney
    5.7-6.3 km/s, and the middle and lower crusts are defined as the portions of the crust with P wave velocities of 6.4-6.7 km/s and 6.8-7.4 km/s, respectively.
  23. [23]
    Seismic Shadow Zone: Basic Introduction - IRIS
    The seismic shadow zone is where seismographs cannot detect earthquakes. S waves are stopped by the liquid outer core beyond 103°, and P waves are refracted ...
  24. [24]
    [PDF] The Seismic Wave Equation
    S-wave particle motion is often divided into two components: the motion within a vertical plane through the propagation vector (SV -waves) and the horizontal ...
  25. [25]
    Surface Waves - Michigan Technological University
    A Rayleigh wave rolls along the ground with a more complex motion than Love waves. Although Rayleigh waves appear to roll like waves on an ocean, the ...Missing: Stoneley normal modes generation effects sources
  26. [26]
    Rayleigh Waves - an overview | ScienceDirect Topics
    Rayleigh wave is defined as a type of surface acoustic wave that propagates on a solid surface with a semi-infinite boundary, characterized by a compound ...Missing: generation | Show results with:generation
  27. [27]
    [PDF] Seismic Waves and Earthquake location
    Two basic types of elastic waves or seismic waves are generated by an earthquake; these are body waves and surface waves. These waves cause shaking that is felt ...
  28. [28]
    What are the Effects of Earthquakes? | U.S. Geological Survey
    Rayleigh and Love waves mainly cause low-frequency vibrations which are more efficient than high-frequency waves in causing tall buildings to vibrate.
  29. [29]
    12.2 Seismic Waves and Measuring Earthquakes – Physical Geology
    Rayleigh waves (R-waves) are characterized by vertical motion of the ground surface, like waves rolling on water. Love waves (L-waves) are characterized by side ...
  30. [30]
    Love Wave - an overview | ScienceDirect Topics
    Love waves are a major type of surface wave having a horizontal motion that is shear or transverse to the direction of propagation.
  31. [31]
    Seismic Waves - Purdue University
    Love waves are surface waves. The disturbance that is propagated is horizontal and perpendicular to the direction of propagation. The amplitudes of the Love ...<|separator|>
  32. [32]
    Properties and Applications of Love Surface Waves in Seismology ...
    The frequency of Love waves generated by earthquakes is rather low comparing to that used in sensor technology and ranges typically from 10 mHz to 10 Hz.
  33. [33]
    Seismic Borehole Geophysics | US EPA
    Jan 22, 2025 · Low frequency, high amplitude Stoneley waves are produced as a result of the seismic source traveling through the borehole fluid and into the ...
  34. [34]
    Stoneley Wave - an overview | ScienceDirect Topics
    The Stoneley wave is sensitive to borehole interface conditions, including wall roughness, presence of fractures and washouts, and permeability of the ...
  35. [35]
    Permeability and borehole Stoneley waves; comparison between ...
    We performed laboratory experiments to evaluate theoretical models of borehole Stoneley wave propagation in permeable materials.
  36. [36]
    [PDF] Normal modes of the Earth - Institut de Physique du Globe de Paris
    Spheroidal eigenfunctions have W = 0, while toroidal eigenfunctions have U = V = 0. An example spectrum obtained for a large earthquake is presented in Figure 1 ...
  37. [37]
    Normal Modes | Global Seismology
    Rayleigh-wave equivalent spheroidal modes nSl (P-SV motion) and Love-wave equivalent toroidal modes nTl (SH motion) with radial order n and angular order l ...
  38. [38]
    [PDF] 12.510 Introduction to Seismology - MIT OpenCourseWare
    There are more spheroidal than toroidal modes. for a rotating sphere. In 3D spherical harmonics, each spherical harmonic or normal mode of the Earth can be ...
  39. [39]
    [PDF] Surface waves - CSUN
    sediment is thick. In the Mexico City earthquake (1985) streets were observed to rise and fall as the surface waves passed, causing great damage from high ...
  40. [40]
    Seismic response of the Mexico City Basin: A review of twenty years ...
    Oct 17, 2006 · Twenty years after the destructive 1985 earthquake (Ms = 8.1) we review published research on seismic response in the Mexico Basin, especially ...
  41. [41]
    Seismic Evidence for Internal Earth Structure
    Seismic Waves. When an earthquake occurs the seismic waves (P and S waves) spread out in all directions through the Earth's interior. Seismic stations ...
  42. [42]
    3.2 Imaging Earth's Interior – Physical Geology – H5P Edition
    The core-mantle boundary is apparent as a sudden drop in P-wave velocities, where seismic waves move from solid mantle to liquid outer core. The boundary ...
  43. [43]
    Preliminary reference Earth model - ScienceDirect.com
    The horizontal and vertical velocities in the upper mantle differ by 2–4%, both for P and S waves. The mantle below 220 km is not required to be anisotropic.
  44. [44]
    Seismic Shadow Zones: S wave shadow zone - IRIS
    A seismic shadow zone is where seismographs can't detect earthquakes. S waves are stopped by the liquid outer core and don't appear beyond ~103° angular ...Missing: 103-180 | Show results with:103-180
  45. [45]
    [PDF] Guide to Seismic Phases
    PKP. A P wave that has traveled through the mantle. (“P”), been transmitted across the mantle-outer core boundary and traveled through the outer core (“K ...
  46. [46]
    [PDF] Beno Gutenberg - National Academy of Sciences
    Gutenberg was quite aware of the non-seismological arguments for a liquid core from the tides and from the figure of the Earth. But in Gutenberg's view, a very ...
  47. [47]
    Seismic Reflection | US EPA
    Apr 18, 2025 · Seismic rays are reflected by interfaces formed by materials that have a sufficient contrast in acoustic impedance. Acoustic impedance is a ...
  48. [48]
    Seismic Reflection- Incorporated Research Institutions for Seismology
    Seismic reflection works off of the basic principle of impedance contrasts between two different geologic units, where either the density, velocity, or both is ...
  49. [49]
    [PDF] A Short Course in Seismic Reflection Profiling II. Theory
    The product Vρ is called the acoustic impedance. Note that the reflection coefficient is proportional to the acoustic impedance contrast. Because very large ...
  50. [50]
    Seismology: Notes: Snell's Law - Pamela Burnley UNLV
    Snell's Law describes the path a wave takes to propagate between two points in the least time. It states that the refracted ray angle is smaller than the ...
  51. [51]
    Seismic Wave Behavior: A single boundary refracts & reflects - IRIS
    Snells Law describes how seismic ray paths bend as they travel from one material into another. They bend toward vertical when going from fast to slow; and; bend ...
  52. [52]
    [PDF] 12.510 Introduction to Seismology - MIT OpenCourseWare
    A third important case is a low velocity zone, where velocity decreases with depth and then increases. Rays entering the low-velocity zone bend down, rather ...
  53. [53]
    [PDF] Scattering and Attenuation of High-Frequency Seismic Waves
    If only body waves are considered, a distinction can be made between P and S codas. The former is the train of waves placed between direct P and S phases. The ...<|control11|><|separator|>
  54. [54]
    [PDF] Seismic-wave Attenuation and the state of the upper mantle by Sean ...
    Seismic-wave attenuation, as represented by the specific quality factor Q, is strongly controlled by the state of the propagation medium.
  55. [55]
    2000 lectures - Geology & Geophysics, Department
    If a velocity does not change across a boundary there won't be refraction but there will be a reflection because the acoustic impedance has changed.
  56. [56]
    [PDF] Basic Seismology: Some Theory and Observations
    For a simple spherical wave the surface area grows as r2 (r is distance) and amplitude scales as 1/r. Amplitude can actually increase if the wave is focused ...
  57. [57]
    [PDF] GE 162 Introduction to Seismology - CalTech GPS
    Guided waves have slow geometrical spreading ∝ 1/√rr. Actually decay a bit ... transmitted waves of amplitude 1, R and T, respectively (z points down):.
  58. [58]
    [PDF] Seismology 2: Anisotropy and Attenuation
    The solution for the damped harmonic oscillator incorporated the damping through the quality factor Q. Attenuation for seismic waves (and a variety of other ...<|control11|><|separator|>
  59. [59]
    [PDF] Observations of Mantle Seismic Anisotropy Using Array Techniques
    Measurements of seismic anisotropy, or the dependence of seismic velocities on the propagation direction and polarization of the wave, may reveal flow and ...
  60. [60]
    Imaging Attenuation From Array Analysis of Surface Waves - Bao
    Sep 18, 2024 · Modeling attenuation from seismic-wave amplitude records is important for understanding the temperature structures and dynamic features of the ...
  61. [61]
    Seismology | 125 years since the first recorded seismogram
    Apr 17, 2014 · The widely recognised first teleseismic seismogram was recorded on April 17, 1889, in Potsdam, Germany by E. von Rebeur-Pacshwitz.
  62. [62]
    Common roots of modern seismology and of earth tide research. A ...
    As an example of this interdisciplinarity, the first recording of a distant earthquake was obtained at Potsdam in April 1889 using an instrument designed by E.
  63. [63]
    [PDF] Principles of Broadband Seismometry - Nanometrics Inc.
    ... STS-1 seismometer, the first high-quality very broadband sensor. ... function of frequency gives the clearest representation of seismometer dynamic range.
  64. [64]
    [PDF] STS-1 and STS-2 Sensors in National Seismic Networks
    Its dynamic range is better than 140 dB in the frequency range of 0.0001. Hz to 10 Hz relative to 1 [m2/s3] (not relative to the sensor's clipping level). Its ...Missing: broadband specifications
  65. [65]
    Full article: A beginner's guide to seismic sensors
    Aug 29, 2024 · The original, and still the most common, sensor used for land seismic surveys is the geophone. The geophone consists of a case that contains the geophone ...
  66. [66]
    Understanding the Fundamentals of Earthquake Signal Sensing ...
    Strong motion sensors measure large amplitude seismic signals and are usually accelerometers. Strong motion accelerometers can measure up to 3.5 g with a system ...
  67. [67]
    [PDF] Seismic Sensors and their Calibration
    There are two basic types of seismic sensors: inertial seismometers which measure ground motion relative to an inertial reference (a suspended mass), and ...<|separator|>
  68. [68]
    https://streckeisen.swiss/assets/downloads/seismic-sensors-and-their-calibration.pdf
  69. [69]
    GEOSCOPE Network - Institut de Physique du Globe de Paris
    The GEOSCOPE network is primarily dedicated to research and its data are used for studies of Earth structure and dynamics, seismic sources, time dependent ...
  70. [70]
    Global seismographic networks part I: A brief history | SAGE - IRIS
    Aug 22, 2022 · In this two-part science highlight series, we first focus on the history of global seismographic networks, as well as advances in instrumentation.
  71. [71]
    [PDF] World-Wide Standardized Seismograph Network: A Data Users Guide
    Nov 13, 2014 · Data from the WWSSN played a pivotal role in developing the paradigm of Plate. Tectonics in the 1960s. Reliable P- and S-wave travel times ...
  72. [72]
    T phase observations in global seismogram stacks - Buehler - 2015
    Jul 20, 2015 · It is important to be aware of coherent energy late in seismograms, as this might influence surface-wave studies or noise assessments. The ...
  73. [73]
    Noise reduction for broad-band, three-component seismograms ...
    Summary. We develop a data-adaptive polarization filter that can spectacularly reduce microseismic noise contamination in three-component broad-band seismo.
  74. [74]
    Distributed Acoustic Sensing (DAS) Research Coordination Network ...
    DAS records ground motion along fiber-optic cables that are comparable to those obtained by single-component accelerometers or geophones. The transformative ...
  75. [75]
    Research Advances on Distributed Acoustic Sensing Technology for ...
    Distributed Acoustic Sensing (DAS) has emerged as a groundbreaking technology in seismology, transforming fiber-optic cables into dense, cost-effective seismic ...
  76. [76]
    Triangulation to Locate an Earthquake | U.S. Geological Survey
    Triangulation can be used to locate an earthquake. The seismometers are shown as green dots. The calculated distance from each seismometer to the earthquake ...
  77. [77]
    How Can I Locate the Earthquake Epicenter?
    Use the time difference between the arrival of the P and S waves to estimate the distance from the earthquake to the station. (From Bolt, 1978.) Measure the ...
  78. [78]
    Traveltimes for global earthquake location and phase identification
    The new iasp91 traveltime tables are derived from a radially stratified velocity model which has been constructed so that the times for the major seismic ...
  79. [79]
    Accurate Depth Determination for Moderate‐Magnitude ...
    Jan 30, 2019 · Improved focal-depth determination through automated identification of the seismic depth phases pP and sP. Bulletin of the Seismological ...Existing Approaches to Depth... · Methodology · Validation With Real Data...
  80. [80]
    Estimating earthquake source depth using teleseismic broadband ...
    Jul 2, 2025 · SynDepth was developed to provide NEIC with a tool that enables rapid, accurate, and quantifiable estimates of earthquake source depth.
  81. [81]
    Magnitude Types | U.S. Geological Survey - USGS.gov
    ML Ml, or ml (local), ~2.0 to ~6.5, 0 - 600 km, The original magnitude relationship defined by Richter and Gutenberg in 1935 for local earthquakes. It is based ...
  82. [82]
    Accuracy and Precision of Earthquake Location Programs: Insights ...
    Dec 3, 2024 · ... velocity model yields a median error of 79 ms compared to the 3D model. This analysis reveals that the simplified velocity model contributes ...
  83. [83]
    Application of real‐time GPS to earthquake early warning in ...
    Jun 11, 2013 · Real-time 1Hz GPS data can be used to provide earthquake early warning GPS provides a real-time magnitude estimate and fault rupture ...
  84. [84]
    Seismographs - Keeping Track of Earthquakes - USGS.gov
    Harry Wood and John Anderson developed the Wood-Anderson seismometer in the 1920's to record local earthquakes in southern California. It photographically ...
  85. [85]
    a deep-neural-network-based seismic arrival-time picking method
    We present a deep-neural-network-based arrival-time picking method called “PhaseNet” that picks the arrival times of both P and S waves.SUMMARY · INTRODUCTION · DATA · METHOD
  86. [86]
    Local earthquake seismic tomography of the Southernmost Mariana ...
    Nov 26, 2023 · We employed seismic tomography to examine the velocity structure of the upper mantle in the Southernmost Mariana subduction zone.
  87. [87]
    Control of slab tears and slab flat wedging on volcanism in ... - Nature
    Oct 28, 2024 · Our tomographic results revealed high-velocity anomalies in the Pacific Plate and Yakutat slab, while the low-velocity areas within the Pacific ...Missing: Vp | Show results with:Vp
  88. [88]
    Update of the Graizer-Kalkan ground-motion prediction equations ...
    A ground-motion prediction equation (GMPE) for computing medians and standard deviations of peak ground acceleration and 5-percent damped pseudo spectral ...<|separator|>
  89. [89]
    Source‐Dependent Amplification of Earthquake Ground Motions in ...
    Jun 17, 2019 · Deep sedimentary basins amplify long-period shaking from seismic waves, increasing the seismic hazard for cities sited on such basins.
  90. [90]
    ShakeAlert – Because seconds matter.
    ShakeAlert is an Earthquake Early Warning system that detects earthquakes quickly to deliver alerts before strong shaking, aiming to reduce earthquake impact.System Information · ShakeAlert® System Algorithms · Media Kit · ContactMissing: P- waves
  91. [91]
    Tsunami Generation: Earthquakes - NOAA
    Sep 27, 2023 · Most tsunamis are generated by earthquakes with magnitudes over 7.0 that occur under or very near the ocean and less than 100 kilometers (62 ...
  92. [92]
    BSSA, 103:2B, Electronic Supplement to Kubo & Kakehi
    For the 2011 Tohoku earthquake, the seismic arrays were located in the land ... The rupture front propagates at a speed of 2.0 km/s. We call this model ...<|separator|>
  93. [93]
    Aftershock Forecasting - Annual Reviews
    Oct 12, 2023 · Aftershock forecasting is advancing through better statistical models, constraints on physical triggering mechanisms, and machine learning.
  94. [94]
    Forecasting future earthquakes with deep neural networks
    SUMMARY. We use the spatial map of the logarithm of past estimated released earthquake energies as input of fully convolutional networks (FCN) to forecast.
  95. [95]
    [PDF] Geophysical Abstracts 136-139 January-December 1949
    This method was first applied in Mexico in 1925 to the exploration of the ... Seismic exploration conducted in the coastal waters of the Gulf of. Mexico ...
  96. [96]
    [PDF] Special Publication 99-1 - Oklahoma Geological Survey
    Seismic-refraction data were used primarily to de- tect salt domes in the Gulf Coast region in the 1920s and 1930s, but their limited capability for ...Missing: Mexico | Show results with:Mexico
  97. [97]
    Acquisition - SEG Wiki
    Apr 21, 2020 · The generation of seismic waves (elastic waves) is carried out by the source. A source can be either natural such as: earthquakes, or ...
  98. [98]
    Seismic Refraction | US EPA
    Apr 2, 2025 · The seismic-refraction method measures the time a seismic-energy pulse takes to travel from a source point to several receivers after being redirected by one ...
  99. [99]
    Bob Hardage: Using seismic technologies in oil and gas exploration
    Jun 12, 2013 · So the vibroseis – which is what we would call the source station – becomes the energy source of the seismic waves. The wave field generated at ...
  100. [100]
    Exploration Seismics - an overview | ScienceDirect Topics
    To emit its signal, the Vibroseis source sweeps through a range of frequencies from about 10 to 60 Hz. Because seismic reflectors in the earth are more closely ...
  101. [101]
    Seismic Airguns - Discovery of Sound in the Sea
    May 19, 2024 · Seismic airguns are used primarily to examine the layers of the seafloor to study Earth's history or locate subsea oil and gas deposits.
  102. [102]
    What is Shallow Seismic Exploration? - Seis Tech
    Shallow seismic exploration is an engineering geological and geophysical exploration that uses the characteristics of seismic wave propagation in different ...
  103. [103]
    Seismic refraction‐methods as applied to shallow subsurface ...
    A highly compact and relatively portable seismograph has been developed which is particularly suited to the shallow exploration required for highway and other ...
  104. [104]
    Chapter 3: Seismic Applications - OnePetro
    DHIs include flat spots, bright spots (strong amplitude reflections), and dim ... oil/gas field to sparse seismic usage in 2D applications in older fields.Volumetrics, Trap Geometry... · Amplitude Variation With... · Seismic Inversion
  105. [105]
    Chapter 1: Overview of Seismic Attributes and Impedance Inversion
    Oct 25, 2024 · By 1970, oil companies were using bright-spot phenomena successfully to identify gas-saturated reservoirs (Forrest, 2000). Digital recording ...
  106. [106]
    Seismic characterization of geothermal sedimentary reservoirs
    Mar 4, 2020 · This study demonstrates how seismic reservoir characterization can provide supplementary quantitative facies and reservoir information in a ...Rock-Physics Analysis · Seismic Inversion · Data And Materials...
  107. [107]
    3D seismic structural characterization of faulted subsurface ...
    Apr 21, 2025 · We assess the key factors controlling CO 2 storage viability by unraveling the morphology of reservoir formations and regional sealing units using 3D seismic ...
  108. [108]
    [PDF] Converted-wave seismic exploration: a tutorial - CREWES
    Converted-wave seismic exploration involves a P wave converting to an S wave at the deepest point of penetration, then returning upward.
  109. [109]
    Converted-wave seismic exploration: Applications - GeoScienceWorld
    Mar 3, 2017 · The converted-wave (P-S) method uses P energy propagating downward, converting upon reflection to an upcoming S-wave.
  110. [110]
    Time-Lapse 4D Seismic Processing and Imaging - Viridien
    Accurate reservoir characterization and seismic monitoring using time-lapse 4D seismic data relies on expert data processing and imaging.
  111. [111]
    The Role of Time Lapse(4D) Seismic Technology as Reservoir ...
    4D seismic technology requires at least two 3D seismic surveys; an initial baseline survey before the production or CO2 sequestration, and a follow-up ...
  112. [112]
    An overview of full-waveform inversion in exploration geophysics
    Full-waveform inversion (FWI) is a challenging data-fitting procedure based on full-wavefield modeling to extract quantitative information from seismograms.
  113. [113]
    [PDF] Environmental Modeling of Acoustic Marine Seismic Sources - TGS
    The pressure wavefields emitted by 'air gun' sources in a marine seismic survey are formally measured as a variety of 'received sound levels' for observation ...
  114. [114]
    Quantitative Seismology, Aki and Richards, 2nd edition
    1. Introduction · 2. Basic Theorems in Dynamic Elasticity · 3. Representation of Seismic Sources · 4. Elastic Waves from a Point Dislocation Source · 5. Plane Waves ...
  115. [115]
    [PDF] Seismology
    This generalization of Snell's law shows an important concept that the whole system of seismic waves produced by reflection and transmission of plane waves in a ...
  116. [116]
    [PDF] Relationships between the velocities and the elastic ... - CREWES
    This paper reviews the equations of body-wave propagation in an elastic anisotropic medium and then focuses upon the particular case of orthorhombic symmetry.
  117. [117]
    Seismic Velocities | US EPA
    Jan 24, 2025 · Seismic velocities are usually expressed in SI units of meters per second. Occasionally, seismic velocities are expressed as kilometers per ...
  118. [118]
    [PDF] 6 Source Characterization
    The seismic moment, Mo (in dyne-cm), of an earthquake is given by. Mo = μ A D. (6.1) where μ is the shear modulus of the crust (in dyne/cm2), A is the area of ...
  119. [119]
    [PDF] Waves in an Isotropic Elastic Solid - Columbia University
    In an isotropic elastic solid, P-waves (longitudinal) travel at c = (λ+2µ)/ρ, and S-waves (transverse) at c = µ/ρ.
  120. [120]
    Quantitative Seismology - Keiiti Aki, Paul G. Richards - Google Books
    1. Introduction Suggestions for Further Reading 2. Basic Theorems in Dynamic Elasticity 2.1 Formulation 2.2 Stress-Strain Relations and the Strain-Energy ...
  121. [121]
    [PDF] Seismic Wave Propagation and Earth models - GFZpublic
    Fig. 2.3 The three components of ground-velocity proportional digital records of the P and S waves from a local event, an aftershock of the Killari-Latur ...
  122. [122]
    [PDF] Preliminary reference Earth model * - Harvard University
    Thehorizontal and vertical velocities in the upper mantle differby 2-4%, both for P and S waves. The mantle below 220 km is not required to be anisotropic.
  123. [123]
    [PDF] Seismic Q revisited
    This paper revisits the theories of Q (quality factor) as a measure of the attenuation and velocity dispersion of a wave field. Q is a dimensionless measure of ...<|control11|><|separator|>