Density Functional Theory Study of Oxygen Adsorption on Polymer Surfaces for Atomic-Layer Etching: Implications for Semiconductor Device Fabrication

Longo, Roberto C.; Ranjan, Alok; Ventzek, Peter L. G.

doi:10.1021/acsanm.0c00618

Cited by 24 publications

(34 citation statements)

References 35 publications

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“…In contrast, the incomplete dehydrogenation of the surface film favored oxidation upon exposure to air. As recently predicted by theory [ 11 ] and confirmed by experiments [ 12 ], the C–H bond is replaced by C–OH even after receiving a very small fluence of O atoms. The discrepancy between the wettability and the oxygen concentration between the results reported by Duca et al [ 6 ] and Park et al [ 10 ] reveals a non-trivial relationship between these two properties of argon plasma-modified fluorine-containing polymers.…”

Section: Modification Of Pvdf Surface By Exposure To Argon Plasmasupporting

confidence: 67%

“…According to theoretical predictions [ 11 ], the substitution of hydrogen with the hydroxyl group is highly probable and exothermic. The initial stage in oxygen-plasma treatment of the PVDF materials should be the partial substitution of the surface C–H bonds with the C–OH functional groups.…”

Section: Modification Of Pvdf Surface By Exposure To Oxygen Plasmamentioning

confidence: 99%

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Non-Equilibrium Plasma Methods for Tailoring Surface Properties of Polyvinylidene Fluoride: Review and Challenges

et al. 2021

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Modification and functionalization of polymer surface properties is desired in numerous applications, and a standard technique is a treatment with non-equilibrium gaseous plasma. Fluorinated polymers exhibit specific properties and are regarded as difficult to functionalize with polar functional groups. Plasma methods for functionalization of polyvinylidene fluoride (PVDF) are reviewed and different mechanisms involved in the surface modification are presented and explained by the interaction of various reactive species and far ultraviolet radiation. Most authors used argon plasma but reported various results. The discrepancy between the reported results is explained by peculiarities of the experimental systems and illustrated by three mechanisms. More versatile reaction mechanisms were reported by authors who used oxygen plasma for surface modification of PVDF, while plasma sustained in other gases was rarely used. The results reported by various authors are analyzed, and correlations are drawn where feasible. The processing parameters reported by different authors were the gas pressure and purity, the discharge configuration and power, while the surface finish was predominantly determined by X-ray photoelectron spectroscopy (XPS) and static water contact angle (WCA). A reasonably good correlation was found between the surface wettability as probed by WCA and the oxygen concentration as probed by XPS, but there is hardly any correlation between the discharge parameters and the wettability.

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Section: Modification Of Pvdf Surface By Exposure To Argon Plasmasupporting

confidence: 67%

Section: Modification Of Pvdf Surface By Exposure To Oxygen Plasmamentioning

confidence: 99%

Non-Equilibrium Plasma Methods for Tailoring Surface Properties of Polyvinylidene Fluoride: Review and Challenges

et al. 2021

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“…34,35 More recently, DFT has provided understanding of surface reactions during ALE of aluminum oxide and polymers. 36,37 While ALE of copper has been reported recently experimentally, 38−40 quantification of the volatile reaction products has been challenging due to their low concentrations. It is therefore the goal of this work to combine experimental studies and theoretical insight to delineate the most probable reaction mechanism leading to selective ALE of copper.…”

Section: Introductionmentioning

confidence: 99%

“…Computational methods based on density functional theory (DFT), with at least gradient-corrected exchange-correlation functionals, now routinely provide atomic-scale understanding of many ground-state chemical reactions and materials properties. − DFT-based simulations have been instrumental to innovations in the fields of photovoltaics, − (photo)electrocatalysis, − energy storage devices, , and materials (bulk and surface) processing − to name a few. It has become an enabling approach for functional material design and chemical process development and has been used to evaluate gas-phase chemical processes relevant to the semiconductor industry, including chemical vapor deposition (CVD) and ALD of copper. , More recently, DFT has provided understanding of surface reactions during ALE of aluminum oxide and polymers. , While ALE of copper has been reported recently experimentally, − quantification of the volatile reaction products has been challenging due to their low concentrations. It is therefore the goal of this work to combine experimental studies and theoretical insight to delineate the most probable reaction mechanism leading to selective ALE of copper.…”

Section: Introductionmentioning

confidence: 99%

Precise Control of Nanoscale Cu Etching via Gas-Phase Oxidation and Chemical Complexation

et al. 2021

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We present a cyclic process for selective and anisotropic atomic layer etching of copper: an oxygen plasma modulates the depth and directionality of the oxidized layer, while formic acid vapor selectively removes the copper oxide scale from the metallic copper. Via density functional theory, with finite temperature and pressure free energy corrections, we evaluate the feasibility of formation of gas-phase Cu(II) and Cu(I) complexes with formate, water, formic acid, and combinations thereof as ligands. These complexes result from the neutralization reaction between copper oxide (CuO and Cu2O) and formic acid, with and without water. We identified and evaluated the formation free energies of formato, formic acid, aquahydroxo, and aquaformato complexes of Cu(II) and Cu(I). Under relevant experimental pressures, we find the water-free dimeric tetra(μ-formato)dicopper(II) “paddlewheel” complex (Cu2(HCOO)4) to be the most favorable etching product, with its formation reaching equilibrium conditions from CuO. The most likely precursor for the dimer is the diformatodi(formic acid)copper(II) monomer, which favorably dimerizes under the same water-lean condition at which the dimer persists. Stabilization of gas-phase Cu (oxide) derivatives thus can be achieved through complexation, enabling gas-phase etching of Cu. This work provides complementary experimental and theoretical studies that illuminate the nature of highly controlled etching with formic acid of nanoscopic CuO(s) layers covering Cu nanoarchitectures, which is relevant for the fabrication of next-generation integrated circuits.

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“…However, very few rigorous computational studies of thermal ALE processes using quantum chemical calculations have been reported so far. Of note is the work of Ventzek and co-workers 53 who presented a DFT study focusing on the ALE of polymer surfaces using an oxygen flux and Hamaguchi and co-workers 54,55 who investigated the self-limiting behavior of hexafluoroacetylacetone (hfacH) on Ni and NiO. However, the above computational studies were based on known ALE processes.…”

Section: Introductionmentioning

confidence: 99%

In silico design of a thermal atomic layer etch process of cobalt

Natarajan

Nolan

Theofanis

et al. 2021

Journal of Vacuum Science &Amp; Technology A: Vacuum, Surfaces, and Films

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Thermal atomic layer etch (ALE), facilitating the removal of up to one monolayer of material per cycle, is growing in importance for thin-film processing. The number of available ALE processes is much smaller than for atomic layer deposition, its complementary growth process. Quantum chemical simulations are a key approach in the development of new thermal ALE processes, however, methodologies and workflows need to be developed. In this regard, the present paper reports a simulation-based approach toward the development of new thermal ALE processes using metallic cobalt as a test case. We demonstrate a predictive process discovery approach for ALE in which target volatile etch products and the corresponding gas phase reactants are chosen from the literature, an overall ALE cycle for each combination of reactant is investigated for thermochemical favorability, and the detailed mechanisms of the individual reaction steps in the proposed ALE processes are studied using density functional theory. From these results, we derive a temperature-pressure process window for each combination of reactants at typical reactant and product pressures allowing the selection of an ALE process window. For Co ALE, we investigated propene, butyne, silane, and trimethyl silane as a first pulse reactant and CO as the second pulse reactant. We propose propene and CO as the best combination of reactants for Co ALE. Propene adsorbs with sufficient strength to the target Co atom at temperatures below the CO decomposition temperature of 440 K, which results in the lowest energy etch species. This approach is equally relevant for the ALE process design of elemental, binary, and ternary materials.

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Density Functional Theory Study of Oxygen Adsorption on Polymer Surfaces for Atomic-Layer Etching: Implications for Semiconductor Device Fabrication

Cited by 24 publications

References 35 publications

Non-Equilibrium Plasma Methods for Tailoring Surface Properties of Polyvinylidene Fluoride: Review and Challenges

Non-Equilibrium Plasma Methods for Tailoring Surface Properties of Polyvinylidene Fluoride: Review and Challenges

Precise Control of Nanoscale Cu Etching via Gas-Phase Oxidation and Chemical Complexation

In silico design of a thermal atomic layer etch process of cobalt

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