Directly tuning the surface morphologies and electron pathway of graphite/diamond composite films for enhanced electron field emission

Cathode electron field emitters are widely used in high-power and high-frequency vacuum electron devices. The development of novel technique to fabricate the emitters with high electron field emission performance has stimulated extensive research. Here we present a unique one-step microwave plasma chemical vapor deposition process to fabricate the graphite/diamond composite films. The gaseous methane is replaced by liquid n-butylamine, which acts as the single reactive carbon source. The components and surface morphologies of the graphite/diamond composite films can be effectively tuned upon changing the de-position temperatures. The vertically oriented graphite/diamond composite film with a graphite-diamond -graphite nanostructure is obtained and shows superior electron field emission performance of low turn-on field (E0 = 4.0 V/mu m) and high emission current density (J@8.8 V/mu m = 13.0 mA/cm(2)). Our study reveal that the sharp edges, appropriate distribution density of the nanosheets, as well as good electron pathway from the bulk to the surface are the key ingredients for the electron field emission performance. This work on graphite/diamond composite films provides a new carbon source instead of methane to fabricate the emitters with high electron field emission performance, which may promote the industrial-scale applica-tion. (c) 2022 Elsevier B.V. All rights reserved.

Automated summary

This study presents a unique one-step microwave plasma chemical vapor deposition process to fabricate graphite/diamond composite films with high electron field emission performance. The researchers found that sharp edges, appropriate distribution density of nanosheets, and a good electron pathway from the bulk to the surface are key factors for electron field emission performance.