RF sputtering of epitaxial lead chalcogenide films in argon and krypton plasma

Zimin, S. P.; Amirov, I. I.; Горлачев, Е. С.

doi:10.1088/0268-1242/26/5/055018

Cited by 24 publications

(20 citation statements)

References 30 publications

(49 reference statements)

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“…Then, the prepared samples were put in a chemical vapour deposition and treated by RF plasma, as shown in Figure 1c. In our case, 60 W power of RF (Ar + average energy with about 10-30 eV, which is around the 15 eV sputtering threshold energy of Ag [18,19]) was chosen to exert on samples. Such power of plasma can provide enough kinetic energy on the surfaces of AgNWs and meanwhile avoid sputtering.…”

Section: Resultsmentioning

confidence: 99%

Low Temperature RF-Plasma Initiated Rapid and Highly Ordered Fracture on Ag Nanowires

Dai

Zhao³

et al. 2020

Applied Sciences

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Highly ordered Ag particle-chains (AgPCs) have been obtained from Ag nanowires (AgNWs) by radio frequency (RF) plasma treatment. Such conversion is attributed to the fast nonequilibrium diffusion of Ag atoms (liquid-like behavior) on AgNWs surfaces through the plasma bombarding. Further, the formed AgPCs highly coincide with the predictions by Rayleigh instability. In contrast to heat treatment, AgPCs are formed rapidly, highly ordered and at temperature below 100 • C. Furthermore, aperiodicity and wire-wire welding instead of highly ordered particle-chains has been observed as the AgNWs are overlapped by plasma treatment. This work should provide a new perspective for metallic particle-chains fabrication.

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Section: Resultsmentioning

confidence: 99%

Low Temperature RF-Plasma Initiated Rapid and Highly Ordered Fracture on Ag Nanowires

Dai

Zhao³

et al. 2020

Applied Sciences

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“…The first approach used by Zayachuk et al [33] is based on the classical consideration of the interactions between ions and multi-component materials, which suggests that the sputtering predominantly involves individual atoms of certain chemical elements. The second approach, which was used in our previous studies [12] and applied again in this work, considers that the dissociation energies of molecules in the crystalline and gaseous states for lead chalcogenides exceed the values of the sublimation energy [34]. Therefore, during the sputtering of lead chalcogenides, whole molecules and their complexes predominantly leave the surface rather than individual atoms.…”

Section: Resultsmentioning

confidence: 99%

Variation of Surface Nanostructures on (100) PbS Single Crystals during Argon Plasma Treatment

et al. 2022

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The nanostructuring of the (100) PbS single crystal surface was studied under varying argon plasma treatment conditions. The initial PbS single crystals were grown by high-pressure vertical zone melting, cut into wafer samples, and polished. Subsequently, the PbS single crystals were treated with inductively coupled argon plasma under varying treatment parameters such as ion energy and sputtering time. Plasma treatment with ions at a minimum energy of 25 eV resulted in the formation of nanotips with heights of 30–50 nm. When the ion energy was increased to 75–200 eV, two types of structures formed on the surface: high submicron cones and arrays of nanostructures with various shapes. In particular, the 120 s plasma treatment formed specific cruciform nanostructures with lateral orthogonal elements oriented in four <100> directions. In contrast, plasma treatment with an ion energy of 75 eV for 180 s led to the formation of submicron quasi-spherical lead structures with diameters of 250–600 nm. The nanostructuring mechanisms included a surface micromasking mechanism with lead formation and the vapor–liquid–solid mechanism, with liquid lead droplets acting as self-forming micromasks and growth catalysts depending on the plasma treatment conditions (sputtering time and rate).

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“…Secondly, the high flux density of argon ions heats the film surface. During the surface bombardment with argon ions having 200 eV energy, the surface temperature can increase up to 225 8C after 30 s [14]. Therefore, even at low treatment durations the In-Ga (In-Ga-Cu) nanoinclusions become liquid.…”

Section: Methodsmentioning

confidence: 99%

Plasma‐assisted self‐formation of nanotip arrays on the surface of Cu(In,Ga)Se₂ thin films

Zimin

Горлачев

Гременок

et al. 2017

Phys. Status Solidi C

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In this paper, we report on the phenomenon of nanostructure self‐formation on the surface of Cu(In,Ga)Se2 (CIGS) thin films during inductively coupled argon plasma treatment with its duration varied from 10 to 120 s. The initial films were grown on glass substrates using the selenization technique. During the CIGS film surface treatment in the high‐density low‐pressure radio‐frequency inductively coupled argon plasma there took place a formation of arrays of uniform vertical nanostructures, which shape with increasing processing duration changed from nanocones to nanorods and back to nanocones. A model of the nanotip plasma‐assisted self‐formation associated with the implementation of micromasking and vapor–liquid–solid mechanisms involving metallic In‐Ga (In‐Ga‐Cu) liquid alloy droplets is proposed.

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RF sputtering of epitaxial lead chalcogenide films in argon and krypton plasma

Cited by 24 publications

References 30 publications

Low Temperature RF-Plasma Initiated Rapid and Highly Ordered Fracture on Ag Nanowires

Low Temperature RF-Plasma Initiated Rapid and Highly Ordered Fracture on Ag Nanowires

Variation of Surface Nanostructures on (100) PbS Single Crystals during Argon Plasma Treatment

Plasma‐assisted self‐formation of nanotip arrays on the surface of Cu(In,Ga)Se₂ thin films

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RF sputtering of epitaxial lead chalcogenide films in argon and krypton plasma

Cited by 24 publications

References 30 publications

Low Temperature RF-Plasma Initiated Rapid and Highly Ordered Fracture on Ag Nanowires

Low Temperature RF-Plasma Initiated Rapid and Highly Ordered Fracture on Ag Nanowires

Variation of Surface Nanostructures on (100) PbS Single Crystals during Argon Plasma Treatment

Plasma‐assisted self‐formation of nanotip arrays on the surface of Cu(In,Ga)Se2 thin films

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Plasma‐assisted self‐formation of nanotip arrays on the surface of Cu(In,Ga)Se₂ thin films