Thermal‐ and Plasma‐Enhanced Copper Film Deposition via a Combined Synthesis‐Transport CVD Technique

Polyakov, Maxim S.; Badalyan, A. M.; Каичев, В. В.; Игуменов, И. К.

doi:10.1002/cvde.201307078

Cited by 5 publications

(2 citation statements)

References 33 publications

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“…Specifically, gas-phase formic acid (HCOOH) is used here to demonstrate its capability to react preferentially with Cu oxide over Cu metal at a relatively mild temperature (80 °C). Although HCOOH has been utilized as a reducing agent for CVD and ALD of Cu, − the mechanism that leads to etching is believed to be via acid–base reaction between HCOOH and Cu oxide, resulting in the formation of gaseous neutralization products, namely, water vapor (H 2 O(g)) and Cu(II)-formato complexes. Decomposition of HCOOH on Cu and Cu oxide, which generally only occurs at temperatures greater than 180 °C, simply reduces the oxide back to its metallic form and does not lead to etching. , Leveraging the above-mentioned etching selectivity for the oxide, we have developed a two-step cyclic process, consisting of: (1) oxidation via exposure to O 2 plasma to form a surface copper-oxide layer and (2) selective removal of the oxide layer via etching with HCOOH vapor, leaving a pristine metal Cu surface behind.…”

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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Section: Introductionmentioning

confidence: 99%

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

et al. 2021

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“…The crystal is becoming more complete due to the fact that high temperature facilitate the growth of crystal and the temperature region is more suitable for crystal growth. Compared to Copper film on Mica [8], our films have smoother surface. Consequently, the surface structure will be suitable for graphene growth.…”

Section: Resultsmentioning

confidence: 85%

Epitaxial Growth of Copper Film by MOCVD

Huang

Zhang

et al. 2016

KEM

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Copper thin films were deposited on single crystal sapphire substrate via metal-organic MOCVD using Cu (acac)2 as precursor. X-ray diffraction (XRD) and Scanning Electronic Microscope (SEM) were employed for studying preferred orientation and microstructure. Atomic Force Microscope was utilized in order to characterize roughness of copper thin layer. By calculation of the Gibbs free energy, the reactions have been deeply understood. Depositions were carried out at various substrate temperatures in the rage 473K to 673K. It has been revealed that temperature determined the orientation and microstructure of copper films. At 673K, copper films have exhibited preferred orientation, smooth surface and connected grains, which proved that this copper thin film can act as precursor. Based on the study of epitaxial growth of copper films, a schematic diagram of epitaxial growth relationship is suggested for the step by step depositions processes.

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N9 substituent mediated structural tuning of copper–purine complexes: chelate effect and thin film studies

et al. 2017

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Thermal‐ and Plasma‐Enhanced Copper Film Deposition via a Combined Synthesis‐Transport CVD Technique

Cited by 5 publications

References 33 publications

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

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

Epitaxial Growth of Copper Film by MOCVD

N9 substituent mediated structural tuning of copper–purine complexes: chelate effect and thin film studies

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