Some Aspects of Reactive Complex Plasmas

Berndt, Johannes; Kovačević, Eva; Stefanović, Ilija; Stepanović, Olivera; Hong, Suk–Ho; Boufendi, Laïfa; Winter, J.

doi:10.1002/ctpp.200910016

Cited by 106 publications

(117 citation statements)

References 79 publications

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“…1, R p,LLS is constant in phase (IV). This is in perfect agreement with constant particle growth rates in comparable Ar/C 2 H 2 RF plasmas determined ex-situ by means of SEM by Berndt et al 4 Consequently, this is a verification that, indeed, n p is constant. In Fig.…”

Section: -supporting

confidence: 90%

“…Once these nanoparticles reach a critical density, they rapidly coagulate (III) to ultimately form permanently negatively charged particles, typically 20-50 nm in size. After coagulation, the particle size increases linearly 4 by deposition of plasma species on their surface (stage IV) while their density n p remains constant; 7 i.e., the negatively charged particles are confined within the positive plasma potential and no new particles are created since reactive species are rather deposited on the particle's surface than creating new particles. When the particles become too large, the confining electric force is not able to overcome the nonconfining ones anymore, the particles are lost from the discharge and n p starts to decrease.…”

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confidence: 99%

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Surprising temperature dependence of the dust particle growth rate in low pressure Ar/C2H2 plasmas

Beckers

Kroesen

2011

Applied Physics Letters

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We have experimentally monitored the growth rate of dust particles in a low pressure Ar/C2H2 radiofrequency discharge as a function of the gas temperature Tg and independent of the C2H radical density and the gas density. Used diagnostics are laser light scattering and measurements of the phase angle between the RF voltage and current. In contrast to most literature, we demonstrate that the growth rate is not a monotonically decreasing function of Tg but shows a maximum around Tg = 65 °C. In addition, we demonstrate that the phase angle is an accurate measure to monitor the particle growth rate.

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Section: -supporting

confidence: 90%

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confidence: 99%

Surprising temperature dependence of the dust particle growth rate in low pressure Ar/C2H2 plasmas

Beckers

Kroesen

2011

Applied Physics Letters

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“…Dusty plasmas are due to the simultaneous presence in the same place of dust particles and plasmas, but a noteworthy aspect is that dust particles can be formed in the plasma itself. In this last case, the fundamental requirement is the presence of molecular precursors [11]. These precursors result from the presence of reactive gases (silane SiH 4 [5,[12][13][14][15][16], methane CH 4 [17][18][19], acetylene C 2 H 2 [17,20,21]) or from material erosion (physical or chemical) at the molecular level [22][23][24][25][26].…”

Section: Introductionmentioning

confidence: 99%

Dust particles in low-pressure plasmas: Formation and induced phenomena

Mikikian

Cavarroc

Couëdel

et al. 2010

Pure and Applied Chemistry

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Formation of dust particles is a common mechanism in low-pressure plasmas. These big particles (in comparison with other plasma species) are sometimes the desired final products of the process, but they may also constitute a severe drawback in certain contexts. In either situation, it is necessary to understand growth mechanisms well, in order to control or avoid dust particle formation. One of the problems that has to be overcome is that dust particle growth is usually a continuous mechanism: once started, it can enter into a cyclic regime where new generations of dust particles are succeeding one after the other. This cyclic phenomenon often induces a side effect consisting of instabilities of a few tens of Hz. This paper discusses the main characteristics of dust successive generations, and particularly the importance of dust-free spaces (void) involved in this process. Finally, some aspects related to deposition when several generations coexist will be presented.

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“…For example, Fig. 4a shows a nanoparticle surface close to the typical cauliflower structure observed in hydrocarbon plasmas [14]. On the contrary, Fig.…”

Section: Analysis Of Synthesized Nanoparticlesmentioning

confidence: 77%