ED14A-07
Telepresence teacher professional development for physics and math constructs focused on US and Thai classrooms' TC-1 slinky seismometer networks

Monday, 14 December 2015: 17:30
310 (Moscone South)
Dean Livelybrooks1, Blake Anthony Parris1, Alex Cook1, Max Kant1, Nick Wogan1, Alexa Zeryck1, Dhiti Tulyatid2 and Douglas R Toomey1, (1)University of Oregon, Eugene, OR, United States, (2)Department of Mineral Resources, Bangkok, Thailand
Abstract:
As part of the Broader Impacts of the Cascadia Initiative, a seismic study of the Cascadia margin, and the Magnetotelluric Observations of Cascadia using a Huge Array (MOCHA) collaboration we have developed school- and museum/library-based networks of TC-1 educational seismometers. The TC-1 is constructed such that its ‘guts’ are visible through an transparent acrylic outer cylinder, thus it is an excellent demonstration of how fundamental physics constructs can be leveraged to design and operate a vertical-channel seismometer capable of recording signals from large earthquakes world-wide. TC-1 (aka ‘slinky seismometer’) networks therefore serve as the application for projects-based learning (PBL) physics and data science instruction in Oregon and Thai classrooms.

The TC-1 acts as a simple harmonic oscillator, employing electromagnetic induction of a moving magnet within a wire coil. Movement of the lower magnet within an electrically conductive pipe dampens motion such that P-, S- and Surface wave phases can be identified. Further, jAmaSeis software can be configured to simultaneously show live signals from three TC-1s and has tools necessary to pick phases for earthquake signals and, thus, locate earthquake epicenters.

Leveraging a long-standing collaboration between the Royal Thai Distance Learning Foundation and the University of Oregon, we developed five, 2-hour, two-way teacher professional development sessions that were transmitted live to Thai K-12 teachers and others starting mid-August, 2015. As an example, one session emphasized hands-on activities to analyze the effect of spring stiffness, inertial mass and initial displacement on the resonance frequency of a simple oscillator. Another pedagogical goal was to elucidate how math is important to understanding the analysis of seismic data, for example, how cross-correlation is useful for distinguishing between genuine earthquake signals and, say, a truck rolling by a TC-1 station. UO graduate and undergraduate physics majors played critical roles in this outreach effort. We will report on: lessons learned around developing and staging international outreach sessions; how outreach development impacted UO students; and how this teacher professional development was received by our Thai colleagues.