Transient response of the radio frequency inductively coupled plasma to a sudden change in power

A spray model and a droplet collision model are implemented into a radio frequency inductively coupled plasma model. The discrete parcel technique combined with the stochastic Monte Carlo method is used to solve the spray equation and determine the outcomes of droplet collisions in dense sprays. Plasma-spray interactions are considered by adding source terms to the conservation equations of mass, momentum and energy of the plasma phase. Two types of the outcomes of water droplets collisions, coalescence and grazing, are predicted and compared to the experimental and analytical results. The agreement is quite good. The effects of droplet collisions on droplet size distribution of the spray and the spray evaporation are investigated. It is found that the droplet collisions can increase the average droplets size of the spray. For the mono-disperse spray, the collisions can lead to a delay on the spray evaporation. However, for the poly-disperse spray, the effect of droplet collisions on the spray evaporation could not be predicted before the calculation due to the randomness of droplet collisions.

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“…The plasma model in this work is an extension of the work described by Mostgahimi et al, (15,16) and was described in Ref. 17.…”

Section: The Plasma Modelmentioning

confidence: 97%

Modeling Injection of Dense Liquid Sprays in Radio Frequency Inductively Coupled Plasmas

Yan

Mostaghimi

2005

Plasma Chem Plasma Process

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“…[17][18][19] Sakuta and his colleagues, for example, introduced a one-dimensional numerical approach to study the effects of plasma diameter and operating frequency on the dynamic behavior of RF plasmas. 17 Suekane et al presented modeling results for the time-dependent electron temperature and density over one RF cycle, neglecting the effect of a͒ Author to whom correspondence should be addressed; FAX 81-29-860-4701; electronic mail: ishigaki.takamasa@nims.go.jp convection.…”

Section: Introductionmentioning

confidence: 99%

Modeling of an induction plasma under transient turbulent flow conditions

Ishigaki

Boulos

2004

Journal of Applied Physics

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Effect of temperature on turbulent and laminar flow efficacy analysis of nanofluidsA renormalization group ͑RNG͒ k-⑀ turbulence model was employed to investigate the role of turbulence for the transient behavior of the radio frequency induction plasma discharge. Time-dependent conservation equations for the plasma and turbulence under local thermal equilibrium ͑LTE͒ conditions were solved numerically in two-dimensional, axisymmetric coordinates. Responses of energy, momentum, and turbulence to steplike and pulsed power changes in an Ar-H 2 plasma with a hydrogen volume concentration of 10.9%, and a total gas flow rate of 104.0 slpm were studied. The corresponding Reynolds number at the inlet of the discharge cavity was 2667. The turbulence model was validated qualitatively by comparing the predicted results with experimental observations under pulsed power conditions. It is found the transient behavior of the plasma energy and momentum are mainly governed by radial convection, while that of the turbulence is primarily determined by axial convection. These gave rise to a 5-10 ms delay in the response of the turbulence lagging behind the temperature field, for sudden power changes, under current operating conditions. A comparison between the results predicted using the RNG k-⑀ turbulence model and those obtained using the laminar model indicates the presence of turbulence leads to a longer relaxation time of plasma. Under pulsed power conditions, the plasma temperature responds to power changes almost instantaneously, and it is always in a transient state. In contrast, variation in the relative turbulent viscosity is insignificant and it is concluded that the turbulence is in a quasisteady state when the period of a pulse is between 10 and 15 ms. By comparing the predicted results with images obtained using a high-speed camera ͑0.67 ms/frame͒ under the same operating conditions, we found that the turbulence model predicted a more accurate transient behavior in terms of plasma volume and temperature than the laminar model does.

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“…The inserted nozzle is assumed to be water cooled at 300 K. On the nozzle wall, the velocity is set to zero. The boundary conditions for the vector potential form of Maxwell's equation are the same as those described in reference [Mostaghimi, 1998]. …”

Section: Boundary Conditionsmentioning

confidence: 99%