Modeling & Simulation VII

Low pressure plasmas are widely used in microelectronics processing and are actively researched for surface sterilisation. To understand and optimise plasma sources for these applications, the fluxes of reactive neutrals and ions to surfaces are often a key focus. However, ultraviolet (UV) photons are known to be important for surface damage in microelectronics processing, and as drivers of microorganism inactivation during sterilisation studies. Nevertheless, they typically receive less attention than ions and neutrals. In this work, UV formation in inductively coupled plasma sources operated in oxygen and nitrogen containing mixtures is studied using both numerical modelling and experimental measurements.

In nitrogen/oxygen plasmas, UV emission is found to mainly originate from excited states of NO. Across the E-H mode transition, UV emission intensity and the NO ground state density, as measured by laser induced fluorescence, are found to be decoupled. This offers opportunities for optimising processes where NO fluxes to surfaces are beneficial, but UV fluxes should be avoided. An experimentally informed collisional radiative model for UV emission from the NO(A) state is developed and used to explain the measured trends. Here, it is found that NO(A) formation is dominated by collisions with excited nitrogen, specifically N₂(A).

In argon/oxygen plasmas, vacuum UV (VUV) photon formation from excited O atoms is studied using a newly developed zero-dimensional (0-D) simulation framework, including a collisional radiative model. Simulations demonstrate that the relative flux of VUV photons compared with O atoms and positive ions can be tailored over orders of magnitude by varying pressure and power in the system, offering insights into regimes of operation where photon related surface damage can be minimised for microelectronics processing. Simulations also suggest that control of flux ratios can also be achieved through pulsing of the power input to the plasma, offering further insights into optimum process regimes.

Funding acknowledgement

EPSRC Centre for Doctoral Training in Fusion Energy (EP/L01663X/1) and the Deutsche Forschungsgemeinschaft (DFG, German Research Foundation) - Project Number 424927143.