Dielectrics are the fundamental building blocks of electrical insulation for centuries. Many components in power systems must be electrically insulated for proper functionality. Although dielectric materials have been studied in every aspect of science and technology from chemistry, physics, utility power, and advance electric power systems, as the systems became large and complicated, higher electrical stresses are imposed onto dielectrics and insulation. Continuous partial discharge or corona activities are a serious problem usually associated with insulation degradation, electromagnetic interference (EMI), and the upset of poorly protected sensitive circuits without proper shielding. For example, in space/aerospace context the influence of factors such as reduced ambient pressures, outgassing, existence of ionosphere and space plasma must also be considered, along with high frequency and localized high field stresses on insulation. This presentation is an overview of dielectric material fundamentals, including the high voltage electrical insulation of space power and high voltage pulsed systems over the years. The studies of pertinent high voltage effects on insulation including theory, technology development, and applications that encompasses phenomena such as high electric field stress, high magnetic flux, and high frequency issues relating to the performance of all insulation media are also presented.

In general, power devices and systems operating in vacuum or sub-atmospheric pressures are more susceptible to partial discharges, corona, or volume discharges due to the partial vacuum conditions. In space power systems, for example, these activities are usually are great concerns and require major design considerations. Currently space power systems operate voltages higher than the traditional 28 V. With the availability of high power electronic devices operating at higher switching frequencies, these power systems also operate under frequencies and waveforms quite different from those studied and developed for earthbound power distribution systems. Thus, these advancements make the corona and partial discharge problems more important than before.  This presentation is an overview of systems and components subject non-uniform, high frequency and high fields operated in sub-atmospheric pressures and associated high frequency gaseous breakdown. Also reviewed are the breakdown characteristics of gases, such as helium, nitrogen and air, under unipolar repetitively pulsed voltage at frequencies varying from 10 kHz to 240 kHz in partial vacuum.   Comparison with dc and unipolar kHz frequency sinusoidal fields is also discussed. Breakdown voltage as a function of pressure in the range where “Pashce” minimum occurs, along with optical emission characteristics of plasma at breakdown are presented.