The Modifying Effects of Significant Seismic Activities on the Electromagnetically Constitutive Parameters: On the Global Principles for the Effectively Resistant and Undestroyable Building Engineering During Significant Seismic Activities

Let us focus on a specific question that may has an ability of answering to build an efficient method that may give us possibility for producing the most effectively resistant and undestroyable buildings even if they get the most significant seismic activities. That question may be set up by discussions about possible expansions through topologically analytic mechanisms involving connective and transitive processes among significant seismic activities, thermodynamics, and electromagnetism; unfortunately, the expansions must be available of topological processes between thermodynamics and electromagnetism as the first stage, this stage takes one to build the thermodynamical electromagnetism as second stage. A unification is given in classical seismology as common between the natural earthquake related seismic activities and thermodynamic events without exact functional relations of these events; unfortunately, this unification is almost well-posed for earthquakes of less than 5.9 Richter magnitude, but it is ill-posed for earthquakes of equal and/or greater than 5.9 Richter magnitude¹, beside this, the well-posed unification is possible between significant seismic activities and electromagnetism^{2, 3}. The unification gives some results of those three events, these results may have significant roles in earthquake safe building construction engineering.

Principle 1: The electrical charge has non-zero volume and non-zero surface even if it is a free charge, an induced charge, and/or an ionic charge; therefore, there always be naturally correlation for electrical charge density through the kinetic energy with both heat and pressure.

The principle 1 gives the basic rules of transitions among heat, pressure, and electromagnetic interactions. The electromagnetic field distribution gains major effects at places near the activity domain than mechanical effects depending mechanical displacements and fluctuations during the most significant naturally seismic activities. The electromagnetically constitutive parameters change of everything in the active zone, significantly as consequences of those majorant effects; therefore, electromagnetic parameters have majorant effects rather than mechanically constitutive parameters in geophysical modeling and/or geotechnical modeling during the most significant natural seismic activities. That result plays the important and principal role in engineering for constructing, possibly the effectively resistant and undestroyable buildings during the most significant seismic activities. The earthquake zones spread forward to new seismic activities from passed activities; therefore, that result keeps its importance at all the geographic domains even if it is far away from the activity domains, but they are in the major geographic domain of the activity.

¹https://doi.org/10.5194/egusphere-egu2020-21121.

²https://doi.org/10.1109/APS.1996.549734.

⁴ISBN 951-22-5474-3, ISSN 1456-632X.