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1

Electronic Resource

Metastable chlorine ion transport in a diverging field electron cyclotron resonance plasma (1992)

Nakano, Toshiki ; Sadeghi, Nader ; Trevor, Dennis J. ; [et al.]

[S.l.] : American Institute of Physics (AIP)

Journal of Applied Physics 72 (1992), S. 3384-3393

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ISSN: 1089-7550

Source: AIP Digital Archive

Topics: Physics

Notes: For applications in ultralarge scale integration, low pressure, high density plasmas are being developed for etching and deposition of thin films. To control critical parameters such as the flux and energy distribution of ions impacting surfaces, it is necessary to understand how these parameters are influenced by physical and electromagnetic design. In this work, we extend previous measurements of ion velocity distributions in Ar/He electron cyclotron resonance plasmas to Cl2/He plasmas. Using Doppler-shifted laser-induced fluorescence spectroscopy, we measure metastable Cl ion velocity distributions parallel and perpendicular to the magnetic field as a function of magnetic field amplitude, pressure, and microwave power. We also examine the effects of the wafer platen on the distribution functions by repeating the measurements after removing the platen. Surprisingly, little qualitative difference is seen when chlorine and argon discharges are compared; this is most likely a result of the low pressures employed ((approximately-less-than)0.15 Pa). As in Ar, we find nearly isotropic ion velocity distributions when the source is operated as a magnetic mirror. Downstream, we consistently observe bimodal ion velocity distributions: the fast component, created in the source, appears to follow magnetic flux lines into the reactor; the slow component, created mostly where the plasma expands from the source into the reaction chamber, is more isotropic. Despite the localized input of energy by cyclotron resonance heating, the spread in ion velocities is largely determined by distributed ionization and spatial variations in the plasma potential.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.351460

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2

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Erratum: "Ion transport in an electron cyclotron resonance plasma'' [J. Appl. Phys. 70, 2552 (1991)] (1992)

Sadeghi, Nader ; Nakano, Toshiki ; Trevor, Dennis J. ; [et al.]

[S.l.] : American Institute of Physics (AIP)

Journal of Applied Physics 71 (1992), S. 3648-3648

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ISSN: 1089-7550

Source: AIP Digital Archive

Topics: Physics

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.351402

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3

Electronic Resource

Ion transport in an electron cyclotron resonance plasma (1991)

Sadeghi, Nader ; Nakano, Toshiki ; Trevor, Dennis J. ; [et al.]

[S.l.] : American Institute of Physics (AIP)

Journal of Applied Physics 70 (1991), S. 2552-2569

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ISSN: 1089-7550

Source: AIP Digital Archive

Topics: Physics

Notes: Electron cyclotron resonance (ECR) plasma reactors are being developed for etching and deposition of thin films during integrated circuit fabrication. To control critical parameters such as the flux and energy distribution of ions impacting surfaces, it is necessary to understand how these parameters are influenced by physical construction, electromagnetic design, and chemical kinetics. In this work, we report detailed measurements of ion velocity distributions in both the source and reactor regions of an ECR system using mixtures of Ar and He. Using Doppler-shifted laser-induced fluorescence spectroscopy, we measure metastable Ar-ion velocity distributions parallel and perpendicular to the magnetic field direction as a function of magnetic field amplitude, pressure, rf bias voltage, and microwave power. The measurements, in turn, are used to estimate the magnitude of electrostatic potentials and fields parallel and perpendicular to the magnetic field. Indicative of ion trapping, we find nearly isotropic ion velocity distributions when the source is operated as a magnetic mirror and the He partial pressure is low; higher He pressures tend to cool the parallel velocity distribution. Downstream, we consistently observe bimodal ion velocity distributions: the fast component, created in the source, follows magnetic flux lines into the reactor; the slow component, created mostly where the plasma expands from the source into the reaction chamber, is more isotropic. The relative amplitudes of these two components, the average ion energy, and the ion energy distribution are easily controlled by changing pressure and magnetic field.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.350332

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4

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Diagnostics of high density plasma reactors used in the processing of electronic and photonic materials (invited) (abstract) : Proceedings of the 9th topical conference on high temperature plasma diagnostics (1992)

Gottscho, Richard A. ; Nakano, Toshiki ; Sadeghi, Nader ; [et al.]

[S.l.] : American Institute of Physics (AIP)

Review of Scientific Instruments 63 (1992), S. 4920-4920

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ISSN: 1089-7623

Source: AIP Digital Archive

Topics: Physics , Electrical Engineering, Measurement and Control Technology

Notes: High-density plasmas are being used in the manufacture of electronic devices and systems because they provide high throughput at low pressure and low ion energy. Low pressure is desirable for maximizing process uniformity over large substrates while low ion energy is desirable for minimizing process-induced damage. However, the optimal design for a high density plasma reactor is unclear and the technology has largely developed empirically: many alternatives for magnetic and geometric design are offered for the same processing applications. In this talk we discuss diagnostic measurements of high density plasma reactors and how they can be used in developing improved reactor designs and in providing insight into materials processing. Laser-induced fluorescence measurements of metastable ion velocity distributions are made in both Ar and Cl2 electron cyclotron resonance and helicon plasmas. The effects of magnetic field configuration, power, and pressure on the energy and angular distributions of the ions will be described along with electron density measurements made by microwave interferometry. Where appropriate, comparisons will be made with the recent theoretical results of Graves and Porteous [D. B. Graves and R. K. Porteous, American Vacuum Society National Symposium, Seattle, WA, November (1991)].

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.1143548

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5

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Ion and neutral temperatures in electron cyclotron resonance plasma reactors (1991)

Nakano, Toshiki ; Sadeghi, Nader ; Gottscho, Richard A.

Woodbury, NY : American Institute of Physics (AIP)

Applied Physics Letters 58 (1991), S. 458-460

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ISSN: 1077-3118

Source: AIP Digital Archive

Topics: Physics

Notes: Ion and neutral temperatures are measured by high-resolution laser-induced fluorescence spectroscopy both in the source and downstream of an electron cyclotron resonance discharge through mixtures of Ar, Ar/Ne, and Ar/He. Contrary to previous reports, both ions and neutrals are found to be cold. In the source, ion temperatures perpendicular to the magnetic field are ≤0.5 eV; downstream they are ∼0.25 eV. Neutral temperatures in the source and downstream are 0.068 and 0.030 eV, respectively.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.104606

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6

Electronic Resource

Spatially resolved ion velocity distributions in a diverging field electron cyclotron resonance plasma reactor (1990)

Trevor, Dennis J. ; Sadeghi, Nader ; Nakano, Toshiki ; [et al.]

Woodbury, NY : American Institute of Physics (AIP)

Applied Physics Letters 57 (1990), S. 1188-1190

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ISSN: 1077-3118

Source: AIP Digital Archive

Topics: Physics

Notes: Electron cyclotron resonance plasma sources are gaining widespread use in plasma processing because they offer high ion flux with controllable energy and thereby high etching and deposition rates with minimal damage. However, it is unclear how ion energy distributions evolve from source to wafer as a function of plasma parameters such as pressure, microwave power, and magnetic field strength. Therefore, we used Doppler broadened and shifted laser-induced fluorescent line profiles to measure Ar+ metastable ion velocity distributions downstream from a divergent magnetic field electron cyclotron resonance source. Spatially resolved distributions, measured at positions above and across a wafer platen, differ markedly from shifted Maxwell–Boltzmann functions. Ions are accelerated along the magnetic field direction by a weak (∼0.5 V/cm), ambipolar electrostatic field. The ion energy component perpendicular to the electric field corresponds to a temperature of only 0.46±0.10 eV. On the edges of the platen, the magnetic and electrostatic fields diverge causing angled acceleration of ions.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1063/1.103482

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