A plastic feedthrough suitable for high-voltage DC femtosecond electron diffractometers

TL;DR

This paper presents a new high-voltage feedthrough design using UHMWPE that enables stable operation at 180 kV for ultrafast electron diffraction, improving high-voltage application reliability.

Contribution

The authors introduce a customizable, cost-effective HVFT made from UHMWPE, demonstrating its effectiveness at high voltages in ultrafast electron diffraction setups.

Findings

Achieved 180 kV voltage with the new HVFT after conditioning.

Demonstrated vacuum level of 1.8 x 10^{-8} Torr.

Proved the design's effectiveness in high-voltage applications.

Abstract

Highly energetic ultrashort electron bunches have the potential to reveal the ultrafast structural dynamics in relatively thicker in-liquid samples. However, direct current (DC) voltages higher than 100 kV are exponentially difficult to attain as surface and vacuum breakdown become an important problem as the electric field increases. One of the most demanding components in the design of a high-energy electrostatic ultrafast electron source is the high voltage feedthrough (HVFT), which must keep the electron gun from discharging against ground. Electrical discharges can cause irreversible component damage while voltage instabilities render the instrument inoperative. We report the design, manufacturing, and conditioning process for a new HVFT that utilizes ultra-high molecular weight polyethylene (UHMWPE) as the insulating material. Our HVFT is highly customizable, inexpensive, and has proven to be effective in high voltage applications. After a couple of weeks of gas and voltage conditioning, we achieved a maximum voltage of 180 kV with a progressively improved vacuum level of 1.8 x $10^{-8}$ Torr.