Generation of uniform large-area very high frequency plasmas by launching two specific standing waves simultaneously

Chen, Hsin‐Liang; Tu, Yen-Cheng; Hsieh, Cheng-Chang; Lin, Deng-Lain; Leou, Keh-Chyang

doi:10.1063/1.4895703

Cited by 6 publications

(3 citation statements)

References 37 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Thus, the higher growth rate with dense film were produced. In addition, most researcher got that the higher frequency would also result in a reduced sheath thickness and a lower voltage potential across the electrodes that makes the deposition growth of films greater and provide better uniformity of films thickness [8]. Thus, the roughness of the SiC thin films is 5.43nm, 11.94nm and 13.91nm obtained at 100MHz, 160MHz and 200MHz respectively which is greatly become more compact as the frequency increased.…”

Section: Atomic Force Microscopymentioning

confidence: 99%

Crystallinity And Morphology Of Silicon Carbide Thin Films Deposited Using Very High Frequency Plasma Enchanced Chemical Vapor Deposition

Muizzudin,

Ismail,

Omar

2018

IJET

View full text Add to dashboard Cite

Conventional plasma enchanced chemical vapor deposition (PECVD) has been widely used since decades to deposit silicon carbide (SiC) thin film. However, lower RF frequency tends to produce hydrogenated amorphous silicon carbide (a-SiC:H) and poly-crystalline (p-SiC) type of films. This work aims to investigate the crystallinity, morphology and deposition temperature of SiC thin films at higher RF frequency. SiC thin films have been prepared on silicon substrates by using very high frequency plasma enhanced chemical vapor deposition (VHF-PECVD). The utilisation of plasma at higher frequency is predicted to give a great impact to allow the chemical reaction at lower temperature with better crystallinity and morphology compared to conventional PECVD method. In this work, the substrate temperature and deposition time were kept constant at 400oC and 15 minutes respectively, while the RF frequency was veried between 100 MHz to 200 MHz. The crystallinity of SiC thin film samples was observed using Raman Spectroscopy while the morphology was examined under the atomic force microscopy (AFM) and scanning electron microscopes (SEM). The results shown that the crystallinity and morphology of the samples were slightly improved as frequency increases. It was observed that the surface roughness of SiC thin films is improves from 5.43 nm at 100 MHz to 13.91 nm at 200 MHz.

show abstract

Section: Atomic Force Microscopymentioning

confidence: 99%

Crystallinity And Morphology Of Silicon Carbide Thin Films Deposited Using Very High Frequency Plasma Enchanced Chemical Vapor Deposition

Muizzudin,

Ismail,

Omar

2018

IJET

View full text Add to dashboard Cite

show abstract

“…In solar and display applications, large area PECVD chambers are often rectangular to accommodate rectangular substrates. These PECVD and PEALD plasmas sources have been extended to the VHF range in recent years [25].…”

Section: Rectangular Capacitively Coupled Plasma Reactormentioning

confidence: 99%

Modeling of low pressure plasma sources for microelectronics fabrication

Agarwal¹,

Bera²,

Kenney³

et al. 2017

J. Phys. D: Appl. Phys.

View full text Add to dashboard Cite

Chemically reactive plasmas operating in the 1 mTorr–10 Torr pressure range are widely used for thin film processing in the semiconductor industry. Plasma modeling has come to play an important role in the design of these plasma processing systems. A number of 3-dimensional (3D) fluid and hybrid plasma modeling examples are used to illustrate the role of computational investigations in design of plasma processing hardware for applications such as ion implantation, deposition, and etching. A model for a rectangular inductively coupled plasma (ICP) source is described, which is employed as an ion source for ion implantation. It is shown that gas pressure strongly influences ion flux uniformity, which is determined by the balance between the location of plasma production and diffusion. The effect of chamber dimensions on plasma uniformity in a rectangular capacitively coupled plasma (CCP) is examined using an electromagnetic plasma model. Due to high pressure and small gap in this system, plasma uniformity is found to be primarily determined by the electric field profile in the sheath/pre-sheath region. A 3D model is utilized to investigate the confinement properties of a mesh in a cylindrical CCP. Results highlight the role of hole topology and size on the formation of localized hot-spots. A 3D electromagnetic plasma model for a cylindrical ICP is used to study inductive versus capacitive power coupling and how placement of ground return wires influences it. Finally, a 3D hybrid plasma model for an electron beam generated magnetized plasma is used to understand the role of reactor geometry on plasma uniformity in the presence of E × B drift.

show abstract

“…Both experimental [19][20][21] and numerical [22][23][24] research indicated that by varying the phase difference between the two sources applied to the top and bottom electrodes, i.e., the so-called phase-shift control, the plasma currents redistributed and therefore the plasma uniformity could be optimized. Moreover, Chen et al pointed out that the plasma nonuniformity decreased significantly by launching a traveling wave, which was generated by the superposition of two standing waves with the same amplitude and out of phase by 90 • in space and time [25][26][27]. Bera et al introduced the electric potential and the magnetic vector potential to calculate the ES field and the EM field, respectively, and they presented different electron density distributions with various combinations of powers at 60 MHz and 180 MHz [28].…”

Section: Introductionmentioning

confidence: 99%

How to address the issue of uniformity in large area capacitively coupled plasmas? A modeling investigation

Zhang

Wang

2020

Plasma Sources Sci. Technol.

View full text Add to dashboard Cite

Recently, the electrical asymmetry effect (EAE) has been proven effective not only in separate control of the ion energy and ion flux, but also in modulation of the plasma radial uniformity. Since no major change in reactor constructions is required, this method is promising and of significant importance in the plasma industry. In this work, a two-dimensional electromagnetic fluid model is employed to investigate the influence of the EAE on the plasma density distribution under various voltages (i.e., the peak-to-peak voltage V 0 equals to 33 V, 56 V and 100 V) and pressures (i.e., 50 mTorr, 200 mTorr and 750 mTorr), in H 2 capacitively coupled plasma (CCP) discharges sustained by multiple consecutive harmonics. The results indicate that at V 0 = 33 V or 750 mTorr, the plasma density is characterized by a broad maximum at the radial center, and the effectiveness of the EAE on the modulation of the plasma radial uniformity is limited. When V 0 becomes higher, the plasma distribution varies obviously by adjusting the phase shift of the fundamental frequency θ 1 . For instance, when θ 1 increases from 0 to 2π at V 0 = 56 V, the plasma density shifts from uniform over center-high to uniform. Moreover, at V 0 = 100 V, the best uniformity is observed at θ 1 = π. When the pressure decreases to 50 mTorr, although the uniformity varies significantly with θ 1 , the plasma density stays low, which may not be welcomed in the plasma processing. Different influences of the EAE on the plasma radial uniformity can be understood by examining the electron heating induced by the sheath expansion and the electric field reversal under various discharge conditions. The results obtained in this work could help us to have a better understanding of the EAE on the plasma radial uniformity, which would be useful to improve the plasma processing in large area CCP reactors.

show abstract

Generation of uniform large-area very high frequency plasmas by launching two specific standing waves simultaneously

Cited by 6 publications

References 37 publications

Crystallinity And Morphology Of Silicon Carbide Thin Films Deposited Using Very High Frequency Plasma Enchanced Chemical Vapor Deposition

Crystallinity And Morphology Of Silicon Carbide Thin Films Deposited Using Very High Frequency Plasma Enchanced Chemical Vapor Deposition

Modeling of low pressure plasma sources for microelectronics fabrication

How to address the issue of uniformity in large area capacitively coupled plasmas? A modeling investigation

Contact Info

Product

Resources

About