2002
DOI: 10.1088/0963-0252/11/4/307
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Multi-dipolar plasmas for uniform processing: physics, design and performance

Abstract: The scaling up of conventional distributed electron cyclotron resonance plasmas presents limitations in terms of plasma density, limited to the critical density, and of uniformity, due to the difficulty of achieving constant amplitude standing wave patterns along linear microwave applicators in the metre range. The alternative solution presented in this study is the extension of the concept of distribution from one-to two-dimensional networks of elementary plasma sources sustained at electron cyclotron resonan… Show more

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Cited by 89 publications
(91 citation statements)
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“…Up to 2016, an aluminum disk shaped metallization was locally performed by using the DMW (Distributed Microwave Plasmas), a technology developed by LPSC [18]. The crystal surface preparation and metal deposition were thus performed by a sequential plasma process consisting in two steps of reactive plasma cleaning followed by plasma-assisted sputtering.…”
Section: B Detector Processing and Pulse Signal Readoutmentioning
confidence: 99%
“…Up to 2016, an aluminum disk shaped metallization was locally performed by using the DMW (Distributed Microwave Plasmas), a technology developed by LPSC [18]. The crystal surface preparation and metal deposition were thus performed by a sequential plasma process consisting in two steps of reactive plasma cleaning followed by plasma-assisted sputtering.…”
Section: B Detector Processing and Pulse Signal Readoutmentioning
confidence: 99%
“…The microwave power from a 2 kW generator at 2.45 GHz (Sairem V R ) is divided in 12 channels, so that the power injected into each cell can be adjusted independently, allowing a good controllability of the uniformity profile. 36 Each ECR cell includes a water cooled permanent magnet that provides a localized magnetic field of 875 Gauss necessary for electron cyclotron resonance. A water cooled magnetic filter (see Fig.…”
Section: Methodsmentioning
confidence: 99%
“…34 However, filament discharges are incompatible with most of the equipments used for micro-and nanoelectronic industry. Recently, a new type of ECR plasma source was build, namely, the multidipolar ECR, [36][37][38] which allows one to produce an easy scalable plasma source in various configurations, free of magnetic field in plasma volume, operating even below 10 mTorr. From the point of view of industrial applications, a negative ion plasma source that can provide the following characteristics is desirable: no contamination by filaments, no density jumps; negligible magnetic field in plasma volume; a density ratio of negative ion to electron higher than 50 (as to make it possible to bias the substrate positively without affecting the plasma potential, V pl , and to avoid overheating by electrons 33,34 ); stable operation at low pressure with no plasma potential drift; 34 good controllability of ion species and high etching rates.…”
Section: Introductionmentioning
confidence: 99%
“…[3]. Our new reactor, named ATOS, which has been operational since October 2007, will be briefly presented here.…”
Section: Principle and Descriptionmentioning
confidence: 99%