This cool demonstration was brought to us via Twitter by Earth and Environmental Science Teacher, Ryan Hollister (follow him at @phanertic).
Using PocketLab's 3-axis accelerometer, the PocketLab app's video function, and an Earthquake Machine (instruction on how to build one here, more resources here), Ryan provides his students with a unique way to visualize a difficult concept.
His first PocketLab video simulates a high-friction/stress Earthquake model. Energy is stored, elastically, and then suddenly released as a large Earthquake. The high-friction/stress results in Earthquakes with lower frequency but greater magnitude.
Used my @ThePocketLab to help students visualize relationship of friction/stress to frequency and size of EQ. pic.twitter.com/iohqx1EcOh
— Ryan Hollister (@phaneritic) January 29, 2016
His second video models a "slow-creep" of a continental plate along a fault-line, similar to sections of the San Andreas fault and the Cascadia subduction zone. The video simulates a low-friction/stress Earthquake model. Energy is released much more frequently but at lower magnitudes. Ryan points out that over time both models release the same energy, just in different ways. High friction equals fewer but larger Earthquakes whereas low friction equals frequent but smaller Earthquakes.
Here's the low-friction EQ model that simulates creeping section of San Andreas recorded w/ @ThePocketLab pic.twitter.com/aruoAI4E0P
— Ryan Hollister (@phaneritic) January 29, 2016
For some interesting articles on slow-creep Earthquakes check these out here and here. For a terrifying read if you're a resident of the Pacific Northwest, check out this New Yorker article from July 2015 (it even scared the White House to pay more attention to the Cascadia subduction zone).