Litcius/Paper detail

Dynamics of high-speed electrical tree growth in electron-irradiated polymethyl methacrylate

Kathryn M. Sturge, Noah Hoppis, Ariana M. Bussio, J. Barney, B. Beaudoin, Cameron J. Brown, B.E. Carlsten, Carolyn Chun, Bryson Callie Clifford, John Cumings, Nicholas Dallmann, Jack R. FitzGibbon, Emily H. Frashure, Ashley E. Hammell, José Hannan, S. L. Henderson, Miriam E. Hiebert, James E. Krutzler, Joseph P. Lichthardt, Mark Marr-Lyon, Thomas Montano, Nathan A. Moody, Alexander H. Mueller, P.G. O’Shea, Ryan T. Schneider, K. Smith, Bryce C. Tappan, Clayton Tiemann, D. Walter, T. Koeth

2024Science22 citationsDOI

Abstract

Dielectric materials are foundational to our modern-day communications, defense, and commerce needs. Although dielectric breakdown is a primary cause of failure of these systems, we do not fully understand this process. We analyzed the dielectric breakdown channel propagation dynamics of two distinct types of electrical trees. One type of these electrical trees has not been formally classified. We observed the propagation speed of this electrical tree type to exceed 10 million meters per second. These results identify substantial gaps in the understanding of dielectric breakdown, and filling these gaps is paramount to the design and engineering of dielectric materials that are less susceptible to electrostatic discharge failure.

Topics & Concepts

DielectricDielectric strengthMaterials scienceElectrical breakdownTree (set theory)ElectronIrradiationComposite materialLiquid dielectricType (biology)Engineering physicsOptoelectronicsElectrical engineeringPhysicsEngineeringMathematicsGeologyNuclear physicsMathematical analysisPaleontologyHigh voltage insulation and dielectric phenomenaElectrostatic Discharge in ElectronicsLightning and Electromagnetic Phenomena