Publication detail

Controlling the plasmonic properties of titanium nitride thin films by radiofrequency substrate biasing in magnetron sputtering

MASCARETI, L. BARMAN, T. BRICCHI, BC. MÜNZ, F. LI BASSI, A. KMENT, Š. NALDONI, A.

Original Title

Controlling the plasmonic properties of titanium nitride thin films by radiofrequency substrate biasing in magnetron sputtering

Type

journal article in Web of Science

Language

English

Original Abstract

Titanium nitride (TiN) is a promising plasmonic material alternative to gold and silver thanks to its refractory character, low resistivity (<100 mu Omega cm) and compatibility with microelectronic industry processes. Extensive research is currently focusing on the development of magnetron sputtering as a large-scale technique to produce TiN thin films with low resistivity and optimized plasmonic performance. As such, more knowledge on the correlation between process parameters and the functional properties of TiN is needed. Here we report the effect of radiofrequency (RF) substrate biasing during the sputtering process on the structural, optical and electrical properties of TiN films. We employ spectroscopic ellipsometry as a sensible characterization method and we show that a moderate RF power, despite reducing the grain size, allows to achieve optimal plasmonic quality factors and a low resistivity (<100 mu Omega cm). This is attributed to the introduction of a slight under-stoichiometry in the material (i.e., TiN0.85), as opposite to the films synthesized without bias or under intense bombardment conditions. RF substrate biasing during magnetron sputtering appears thus as a viable tool to prepare TiN thin films at room temperature with desired plasmonic properties.

Keywords

Titanium nitride thin films; Magnetron sputtering; Plasmonics; Spectroscopic ellipsometry; Electrical resistivity

Authors

MASCARETI, L.; BARMAN, T.; BRICCHI, BC.; MÜNZ, F.; LI BASSI, A.; KMENT, Š.; NALDONI, A.

Released

15. 7. 2021

Publisher

ELSEVIER

Location

AMSTERDAM

ISBN

1873-5584

Periodical

APPLIED SURFACE SCIENCE

Year of study

554

Number

1

State

Kingdom of the Netherlands

Pages from

149543-1

Pages to

149543-9

Pages count

9

URL