Discharge physics and atomic layer etching in Ar/C4F6 inductively coupled plasmas with a radio frequency bias

Yoon, Min Young; Yeom, H. J.; Kim, Jung-Hyung; Chegal, Won; Cho, Yong Jai; Kwon, Deuk-Chul; Jeong, Jong‐Ryul; Lee, Hyo-Chang

doi:10.1063/5.0047811

Cited by 27 publications

(21 citation statements)

References 110 publications

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“…The ICP power and RF bias voltage were 1.5 kW and 600 V, respectively, where the stable and high-density plasma, called inductive (H) mode, is sustained without plasma instability caused by negative ions and/or dust particles. 25 The plasma density measured by a microwave cutoff probe was 9 × 10 10 cm −3 as the high plasma density, which also confirms the pure H mode regime of the ICP. 26 This test was conducted under power conditions slightly stronger than those previously used in research because it was necessary to study various etching mechanisms, including chemical, mixing, and physical etching of the ceramics.…”

Section: ■ Experimental Sectionsupporting

confidence: 59%

“…The details of equipment and etching conditions are provided in Figure and Table . The ICP power and RF bias voltage were 1.5 kW and 600 V, respectively, where the stable and high-density plasma, called inductive (H) mode, is sustained without plasma instability caused by negative ions and/or dust particles . The plasma density measured by a microwave cutoff probe was 9 × 10 10 cm –3 as the high plasma density, which also confirms the pure H mode regime of the ICP .…”

Section: Methodsmentioning

confidence: 55%

“…Using the shadow mask frame made of nickel–cobalt alloy, the specimen was partially covered, except for the area to be plasma-etched, which had a width of 500 μm and 100 μm. Plasma etching tests were performed in a radio-frequency (RF) biased inductively coupled plasma (ICP) chamber using CF 4 (40 sccm), O 2 (10 sccm), and Ar (10 sccm) mixed gases . A CF 4 -rich atmosphere was maintained during the experiment.…”

Section: Methodsmentioning

confidence: 99%

“…Plasma etching tests were performed in a radio-frequency (RF) biased inductively coupled plasma (ICP) chamber using CF 4 (40 sccm), O 2 (10 sccm), and Ar (10 sccm) mixed gases. 25 A CF 4 -rich atmosphere was maintained during the experiment. The details of equipment and etching conditions are provided in Figure 1 and Table 2.…”

Section: ■ Experimental Sectionmentioning

confidence: 99%

See 3 more Smart Citations

Correlation with the Microstructure and Synergistic Physiochemical Etching Resistance of Nanocomposites under Fluorine-Containing Plasma Conditions

Jin

Hong

et al. 2022

ACS Appl. Mater. Interfaces

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In the semiconductor fabrication industry, high-power plasma is indispensable to obtain a high aspect ratio of chips. For applications to ceramic components including the dielectric window and ring in the semiconductor etching chamber, the Y2O3 ceramics have attracted interest recently based on excellent erosion resistance. When a high bias voltage is applied in a plasma environment containing fluorine gas, both chemical etching and ion bombardment act simultaneously on the ceramic components. During this etching process, severe erosion and particles generated on the ceramic surface can have effects on overall equipment effectiveness. Herein, we report the outstanding plasma etching resistance of Y2O3–MgO nanocomposite ceramics under a CF4/Ar/O2 gas atmosphere; the erosion depth of this material is 40–79% of that of the reference materials, Y2O3 ceramics. In a robust approach involving effective control of the microstructure with different initial particles and sintering conditions, it is possible to understand the relationship between etching behavior and microstructure evolution of the nanocomposite ceramic. The results indicate that the nanocomposite with fine and homogeneous domain distribution can decrease particle generation and ameliorate its life cycle; accordingly, this is a promising alternative candidate material for ceramic components in plasma chambers.

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Section: ■ Experimental Sectionsupporting

confidence: 59%

Section: Methodsmentioning

confidence: 55%

Section: Methodsmentioning

confidence: 99%

Section: ■ Experimental Sectionmentioning

confidence: 99%

See 2 more Smart Citations

Correlation with the Microstructure and Synergistic Physiochemical Etching Resistance of Nanocomposites under Fluorine-Containing Plasma Conditions

Jin

Hong

et al. 2022

ACS Appl. Mater. Interfaces

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“…In recent years, the critical dimension of semiconductor device has been reduced by a few nanometers, and the aspect ratio of patterns has been increased [1][2][3][4]. Accordingly, the need for technologies with atomic-level control in semiconductor manufacturing processes has grown as well.…”

Section: Introductionmentioning

confidence: 99%

Brief Review of Atomic Layer Etching Based on Radiofrequency-Biased Ar/C₄F₆-Mixture-Based Inductively Coupled Plasma Characteristics

Yeom

Jeong

Kim

et al. 2023

Appl. Sci. Converg. Technol.

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Among the next-generation semiconductor manufacturing processes, plasma-assisted atomic layer etching (ALE) has garnered significant attention along with an increase in demand for damage-free and precise process technology. In typical ALE, an atomic layer is etched in each cycle by repeating a modification step through a chemical reaction using a reactive gas and a removal step through physical etching. Polymer-rich fluorocarbon gases, such as C 4 F 8 and C 4 F 6 , are generally used as reactive gases for ALE to protect the sidewalls of high-aspect-ratio patterns. Compared with C 4 F 8 , C 4 F 6 has a lower global warming potential and an excellent etch selectivity, thus, it can be a candidate for next-generation etching gas. Among the plasma sources for ALE, inductively coupled plasma (ICP) is widely used because of its low plasma potential and low electron temperature. Moreover, the ion energy and electron density in an ICP can be independently controlled using an additional bias system. In ALE performed using a radiofrequency (RF)-biased ICP, the plasma characteristics change in each step, because the reactive gas is injected and purged in the modification step, and a bias is applied in the removal step. Hence, an ALE process design or a recipe tuning based on an understanding of the plasma characteristics in each step is required for precisely controlling the process. This review introduces and discusses ALE process and plasma characteristics using RF-biased ICP and C 4 F 6 (Hexafluoro-1,3-butadiene).

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Evaluation of H₂ Plasma‐Induced Damage in Materials for EUV Lithography

Choe,

Choi,

Kim

et al. 2023

Adv Materials Inter

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Ultrafine semiconductor fabrication by lithography has undergone a significant transition from deep ultraviolet (DUV) to extreme ultraviolet (EUV) processes, which presents new challenges. Specifically, the damage caused to components utilized in an EUV system, such as multilayer mirrors, reticles, and pellicles within lithography equipment, owing to EUV‐induced H2 plasma, is a critical issue that directly affects the process yield and equipment lifespan. To address these issues, it is crucial to establish an environment similar to that of EUV‐induced plasma and develop a method to evaluate the resulting damage. Accordingly, an evaluation method is developed for assessing the material damage caused by hydrogen radicals and ions in inductively coupled H2 plasma. In these systems, the electron density ranged from 5 × 108 to 3.5 × 1010 cm−3, the electron temperature ranged from 1 to 4 eV, and the ion energy ranged from several to tens of eV; these conditions closely align with the environment of an EUV‐induced H2 plasma. The damage to Mo2C, a potential EUV pellicle material, is quantitatively analyzed by measuring the fraction of the pore area and examining the chemical characteristics after exposing the samples to various plasma conditions, including electron density, gas pressure, and exposure time.

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Discharge physics and atomic layer etching in Ar/C4F6 inductively coupled plasmas with a radio frequency bias

Cited by 27 publications

References 110 publications

Correlation with the Microstructure and Synergistic Physiochemical Etching Resistance of Nanocomposites under Fluorine-Containing Plasma Conditions

Correlation with the Microstructure and Synergistic Physiochemical Etching Resistance of Nanocomposites under Fluorine-Containing Plasma Conditions

Brief Review of Atomic Layer Etching Based on Radiofrequency-Biased Ar/C₄F₆-Mixture-Based Inductively Coupled Plasma Characteristics

Evaluation of H₂ Plasma‐Induced Damage in Materials for EUV Lithography

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Discharge physics and atomic layer etching in Ar/C4F6 inductively coupled plasmas with a radio frequency bias

Cited by 27 publications

References 110 publications

Correlation with the Microstructure and Synergistic Physiochemical Etching Resistance of Nanocomposites under Fluorine-Containing Plasma Conditions

Correlation with the Microstructure and Synergistic Physiochemical Etching Resistance of Nanocomposites under Fluorine-Containing Plasma Conditions

Brief Review of Atomic Layer Etching Based on Radiofrequency-Biased Ar/C4F6-Mixture-Based Inductively Coupled Plasma Characteristics

Evaluation of H2 Plasma‐Induced Damage in Materials for EUV Lithography

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Product

Resources

About

Brief Review of Atomic Layer Etching Based on Radiofrequency-Biased Ar/C₄F₆-Mixture-Based Inductively Coupled Plasma Characteristics

Evaluation of H₂ Plasma‐Induced Damage in Materials for EUV Lithography