Tag: Earthquakes

Earthquakes are illustrated in this collection of accurate, accessible science graphics, designed to make understanding the causes and effects of seismic activity clear and engaging. These visuals cover faulting, plate movements, earthquake waves, and associated hazards, helping explain how stress accumulation and release shape Earth’s surface. Ideal for educators, students, and geoscience enthusiasts, this earthquake graphic collection turns complex seismological concepts into visually rich, easy-to-grasp resources for teaching and learning about one of Earth’s most powerful natural phenomena.

Plate tectonic Earth map

Visually accessible and scientifically accurate global map of key plate tectonics characteristics on the Earth.

Visually accessible and scientifically accurate global map of key plate tectonics characteristics on the Earth. Superposed on the Earth’s surface topography (from s-ink.org/surface-topography-relief) are the seafloor age (from s-ink.org/oceanic-plate-age), plate boundaries (from s-ink.org/subduction-zones-map) and tectonic plate names (from s-ink.org/tectonic-plates-simple), active volcanoes (from s-ink.org/global-volcano-distribution), largest earthquakes (from s-ink.org/historic-earthquake-distribution), major rivers, and the outlines of the world map.

Data sets shown are from Amante and Eakins (2009), Müller et al. (1997), Argus et al. (2011), Bird (2003), Deep Sea Drilling Project (1989), NCEI Volcano Location Database, and Hayes (2018). The Scientific colour map ‘lipari‘ is used to represent data accurately and to all readers.

Creator: Fabio Crameri
This version: 16.12.2024
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri from Crameri and Pérez-Díaz (2025) is available via the open-access s-ink.org repository.
Related reference: Crameri, F., & Perez Diaz, L. (2025). The Evolving Role of Science Visuals in Geoscience: From Simple Illustrations to Storytelling Tools. τeκτoniκa, 2(2), I-VI. https://doi.org/10.55575/tektonika2024.2.2.102

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Earthquake distribution map (poster)

Global map of seismicity showing the distribution of large 5.8+ magnitude historic earthquakes derived from seismic wave measurements.

Global map of seismicity showing the distribution of large 5.8+ magnitude historic earthquakes derived from seismic wave measurements after the compilation by Hayes (2018). Shown are individual epicentres coloured by depth. For individual earthquake maps see: s-ink.org/historic-earthquake-distribution .

The Scientific colour map ‘oslo‘ is used to represent earthquake depth accurately and to all readers.

Creator: Fabio Crameri
This version: 17.11.2024
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri representing data from Hayes (2018) is available via the open-access s-ink.org repository.
Related reference: Hayes, G., 2018, Slab2 – A Comprehensive Subduction Zone Geometry Model: U.S. Geological Survey data release, https://doi.org/10.5066/F7PV6JNV

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Subduction earthquakes (crosssection)

Vertical crosssection through the Japan subduction zone highlighting large, subduction-related earthquakes recorded over the last decades and the spatial distribution of their hypocentres.

Vertical crosssection through the Japan subduction zone highlighting large, subduction-related earthquakes recorded by USGS over the last decades and the spatial distribution of their hypocentres, which outlines the downgoing plate and the single-sided nature of subduction zones on the Earth.

Creator: Fabio Crameri
This version: 23.09.2022
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri representing data from USGS is available via the open-access s-Ink repository.
Related reference: https://earthquake.usgs.gov

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Seismic hazard

Seismic hazard maps presenting the level of certain ground motions that have a 10% chance of exceedance during a 50-year time span.

Seismic hazard maps presenting the level of certain ground motions that have a 10% chance of exceedance (or a 90% chance of non-exceedance) during a 50-year time span (corresponding to a return period of 475 years). The seismic hazard data shown from Giardini et al. (2003) describes the peak ground acceleration. The Scientific colour map ‘bilbao‘ is used to represent data accurately and to all readers.

Creator: Fabio Crameri
This version: 15.12.2021
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri is available via the open-access s-Ink repository.
Related reference: Giardini, D., Grünthal, G., Shedlock, K. M. and Zhang, P.: The GSHAP Global Seismic Hazard Map. In: Lee, W., Kanamori, H., Jennings, P. and Kisslinger, C. (eds.): International Handbook of Earthquake & Engineering Seismology, International Geophysics Series 81 B, Academic Press, Amsterdam, 1233-1239, 2003.

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Seismic wave travel paths

A schematic highlighting the travel paths of seismic waves through the Earth’s interior.

A schematic highlighting the travel paths of seismic waves through the Earth’s interior. Seismic waves travelling through the Earth follow a curving path due to changes in composition, pressure, and temperature within the layers of the Earth. They follow the same laws of refraction and reflection at interfaces as others waves. When they encounter boundaries between different media, the waves behave according to Snell’s law, with the resulting angle of refraction across the boundary depending on the velocity difference between the two media. Seismic wave arrivals, and the lack of arrivals of direct S- and P-waves, at distant seismic stations have taught us that there are multiple layers within the Earth.

Creator: Fabio Crameri
This version: 25.10.2021
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri is available via the open-access s-Ink repository.
Related reference: –

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Historic earthquake distribution

Global distribution map of large 5.8+ magnitude historic earthquakes derived from seismic wave measurements.

Global map showing the distribution of large 5.8+ magnitude historic earthquakes derived from seismic wave measurements after the compilation by Hayes (2018). Shown are individual epicentres coloured by depth. For a nice looking poster graphic, see s-ink.org/earthquake-distribution-map-poster .

The Scientific colour map ‘oslo‘ is used to represent earthquake depth accurately and to all readers.

Creator: Fabio Crameri
Original version: 14.10.2021
This version: 17.11.2024
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri representing data from Hayes (2018) is available via the open-access s-ink.org repository.
Related reference: Hayes, G., 2018, Slab2 – A Comprehensive Subduction Zone Geometry Model: U.S. Geological Survey data release, https://doi.org/10.5066/F7PV6JNV

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Earth processes

A schematic highlighting some of the most relevant Earth processes.

A schematic highlighting some of the most relevant Earth processes. Illustrated are an early Earth (without a fully developed solid inner core, left) that evolves into a dynamic, present-day-style Earth (right), which generates and erases geologic records of its transforming states and is now experiencing unprecedented environmental change. The arcuate lines surrounding globe illustrate the protective geomagnetic field that arises from the fluid dynamics within the outer core (light grey, illustrated with curled lines). The solid inner core is shown to scale as a darker grey. The mantle and crust (continental rocks are light brown, ocean floor basalts are dark brown; thicknesses greatly exaggerated, with mantle thickness to scale) is a single system driven by convection within the mantle that arises from radioactive decay of heat-producing elements and the loss of the deeply buried planet’s formational energy through cooling of the core. The lithosphere (crust and coldest mantle) is broken into separating and colliding plates whose distribution influence critical element distribution, earthquakes, volcanism, topography, critical zone, climate, water cycle, biogeochemistry, and biodiversity. The Earth is blanketed in a thin atmosphere (light blue). The profile of a landscape highlights Earth surface processes, the sedimentary record of Earth’s history, human influence, and geohazards to people. Displacement on faults may produce sudden strong earthquakes (creating significant hazards) or develop slowly with virtually imperceptible earthquakes. Landslides and coastal retreat, sea level rise, and tsunamis also present hazards to the coastal community. Uplifted hills will experience weathering (light brown) such that dense bedrock develops porosity and holds moisture and groundwater (light blue) that is exploited by vegetation. Deep groundwater aquifers (blue) are key water resources. Precipitation (blue lines) is returned to the atmosphere by evaporation and transpiration (blue dots) with excess water recharging groundwater or running off. Biologically-mediated gas exchange with the atmosphere occurs across the planet. Older sedimentary rocks (stippled brown) and young to contemporary sediments provide records of Earth’s evolving climate, biogeochemistry, and biodiversity. Humans are acting as geologic agents and affecting Earth processes in many ways, including through climate change (via urbanization, release of greenhouse gases, and vegetation change); nutrient input to terrestrial aquatic systems and the oceans (from agriculture and urban wastewater); changes in erosion and sedimentation (from land use change, dams, and other influences on river flow and sediment load); modification of the geographic distribution of biodiversity (from climate and land use change); and exacerbation of hazards (through rising sea level, more intense storms, land use change, and drought-induced wildland fires).

Creator: Fabio Crameri
This version: 14.09.2021
License: Attribution-ShareAlike 4.0 International (CC BY-SA 4.0)
Specific citation: This graphic by Fabio Crameri from Crameri et al. (2022) is available via the open-access s-Ink.org repository.
Related reference:
Crameri, F., G.E. Shephard, and E.O. Straume (2022, Pre-print), Effective high-quality science graphics from s-Ink.org, EarthArXiv, https://doi.org/10.31223/X51P78
National Academies of Sciences, Engineering, and Medicine 2020. A Vision for NSF Earth Sciences 2020-2030: Earth in Time. Washington, DC: The National Academies Press. https://doi.org/10.17226/25761

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