Abstract
Amorphous hydrogenated silicon nitride thin films a-SiNx:H (abbreviated later by SiNx) were deposited by Electron Cyclotron Resonance plasma enhanced chemical vapor deposition method (ECR-PECVD). By changing ratio of gas flow (R = NH3/SiH4) in the reactor chamber different stoichiometric layers x = [N]/[Si] ([N] and [Si] atomic concentrations) are successfully deposited. Part of the obtained films has subsequently undergone rapid thermal annealing RTA (800°C/1 s) using halogen lamps. Optical and structural characterizations are then achieved by spectroscopic ellipsometry (SE), ion beam analysis and infrared absorption techniques. The SE measurements show that the tuning character of their refractive index n(λ) with stoichiometry x and their non-absorption properties in the range of 250 - 850 nm expect for Si-rich SiNx films in the ultraviolet UV range. The stoichiometry x and its depth profile are determined by Rutherford backscattering spectrometry (RBS) while the hydrogen profile (atomic concentration) is determined by Elastic Recoil Detection Analysis (ERDA). Vibrational characteristics of the Si-N, Si-H and N-H chemical bonds in the silicon nitride matrix are investigated by infrared absorption. An atomic hydrogen fraction ranging from 12% to 22% uniformly distributed as evaluated by ERDA is depending inversely on the stoichiometry x ranging from 0.34 to 1.46 as evaluated by RBS for the studied SiNx films. The hydrogen loss after RTA process and its out-diffusion depend strongly on the chemical structure of the films and less on the initial hydrogen concentration. A large hydrogen loss was noted for non-thermally stable Si-rich SiNx films. Rich nitrogen films are less sensitive to rapid thermal process.
Highlights
Amorphous hydrogenated silicon nitride film (SiNx) deposited at low temperature by plasma assisted CVD has several applications in semiconductor and photovoltaic industry
We study the effect of the main technological parameters, with keeping the other parameters constants, on the optical and structural properties of the SiNx:H films produced in a remote Electron Cyclotron Resonance (ECR-) CVD reactor
The chemical structure of SiNx films were analyzed by fourier-transform infrared spectroscopy (FTIR), Infrared-transmission measurements were performed on a Bruker Equinox 55 Fourier transform infrared spectrometer using a MIR-source, a KBr beamsplitter and DTGS detector
Summary
Amorphous hydrogenated silicon nitride film (SiNx) deposited at low temperature by plasma assisted CVD has several applications in semiconductor and photovoltaic industry. SiNx films deposited by PECVD technique in all its variants exhibit several advantageous properties It is a low temperature process, relatively cost-effective, with high deposition rate, adjustable refractive index and high quality passivating films. SiNx films, compared to other dielectric films such as silicon dioxide, are more suitable candidates for photovoltaic applications They are used as antireflecting coating (ARC), back surface reflector for optical purpose in the front and the back side of Si-based solar cells due to its tunable refractive index. By adjusting thickness and refractive index, stacking layers could be used instead of a simple one to optimize the properties of solar cells efficiency From electrical viewpoint, they are used as hydrogen source for the bulk passivation of recombining centers in low-cost defected-rich Si-based solar cells thanks to the thermal post-deposition of metal contacts (mc-Si, poly-Si and ruban-Si) [5]-[7]. The thermal stability of the deposited films will be probed after a rapid thermal anneal using halogen lamps as heating source
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