Deposition of Cu/a-C:H Nanocomposite Films

Hanuš, Jan; Steinhartova, T.; Kylián, Ondřej; Kousal, Jaroslav; Malínský, P.; Choukourov, Andrei; Macková, Anna; Biederman, Hynek

doi:10.1002/ppap.201500208

Cited by 20 publications

(28 citation statements)

References 45 publications

(75 reference statements)

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“…Even though the pressure increase was realized by the increase of the flow rate of Ar, the changes in velocity of neutral gas and hence the changes in the residence time of NPs in the aggregation/growth region are in this case almost negligible. The changes in NP size are caused by less effective formation of condensation seeds at lower pressure, as we already explained in more detail in our previous studies …”

Section: Resultssupporting

confidence: 56%

Effect of magnetic field on the formation of Cu nanoparticles during magnetron sputtering in the gas aggregation cluster source

Vaidulych

Hanuš

Kousal

et al. 2019

Plasma Processes & Polymers

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Reliable production of nanoparticles (NPs) by magnetron sputtering in a gas aggregation source (GAS) is of great interest because of many potential applications. The size, shape, or structure of NPs can be tuned by the operational parameters of the GAS. In this study, fabrication of copper (Cu) NPs is investigated dependent on the magnetron magnetic field (MF)-a not much studied parameter. Decrease of the MF from 83 to 35 mT results in changes in the shape and size distribution of the NPs. MF also strongly affects the NPs deposition rate (DR). Electromagnetic trapping of the NPs in the vicinity of the magnetron target is proposed to be responsible for the changes in DR and polydispersity. The highest DR was reached at 45 mT. K E Y W O R D Scopper nanoparticles, gas aggregation source (GAS), magnetic field, magnetron sputtering

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Section: Resultssupporting

confidence: 56%

Effect of magnetic field on the formation of Cu nanoparticles during magnetron sputtering in the gas aggregation cluster source

Vaidulych

Hanuš

Kousal

et al. 2019

Plasma Processes & Polymers

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“…Ar flow was 4 sccm that corresponded to pressure 40 Pa inside the aggregation chamber 40. Under such conditions almost 10% of sputtered Cu atoms are bound in produced NPs, that is, efficiency in metal utilization is around 10% and the deposition rate is aproximatelly 0.1 mg min −1 …”

Section: Methodsmentioning

confidence: 99%

“…Under such conditions almost 10% of sputtered Cu atoms are bound in produced NPs, that is, efficiency in metal utilization is around 10% and the deposition rate is aproximatelly 0.1 mg min −1 . [3] In order to coat Cu NPs by plasma polymer shells a glass cylinder (inner diameter 92 mm, length 200 mm) with outer metal electrode was introduced in between the output orifice and the grounded substrate holder (see Figure 1). This auxiliary plasma source was powered by a RF power source (Dressler Ceasar, 13.56 MHz) connected to the outer electrode through a manually operated matching network.…”

Section: Methodsmentioning

confidence: 99%

“…Such gas aggregation sources of nanoparticles (GAS), introduced in the early‐1990s of the last century by Haberland et al, posseses in comparison with techniques based on chemical synthesis advantageous features such as relative simple and effective production of NPs, no or only limited use of potentially harmful solvents or chemical precursors as well as the possibility to combine the gas aggregation sources of nanoparticles with other vacuum‐based deposition methods. The latter enabled production of complex functional nanocomposite or nanostructured materials with different architectures including classical nanocomposites or multi‐layered structures, coatings with dual‐scale roughness, or materials with horizontal gradients of NPs embedded into a matrix material . Furthermore, the GAS systems were proved to be highly flexible also in terms of composition of produced NPs as they enabled fabrication of metallic, metal‐oxide as well as polymeric NPs …”

Section: Introductionmentioning

confidence: 99%

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Core@shell Cu/hydrocarbon plasma polymer nanoparticles prepared by gas aggregation cluster source followed by in‐flight plasma polymer coating

Kylián

Kuzminova

Vaydulych

et al. 2017

Plasma Processes & Polymers

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Core@shell Cu/hydrocarbon plasma polymer nanoparticles (NPs) have been prepared using a gas aggregation cluster source followed by in‐flight plasma polymer coating of produced Cu NPs. Conventional plasma polymerization of vapors of n‐Hexane or acetone has been applied. It is shown that this strategy for core@shell NPs production enables to achieve homogeneous shells with thickness in nanometer scale without impact on the properties of metallic cores (crystallinity, optical properties). In addition, it has been proved that the chemical properties of shells may be controlled by use of different organic precursors that enables production of NPs with different wettabilities.

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“…Regarding to the first mentioned aspect, the use of metal/plasma polymer nanocomposites is often hampered by the fact that plasma polymer is rather soft and does not withstand usual wear abrasion. Therefore in our previous work, we decided to grow hydrocarbon plasma polymer matrix under positive ion bombardment that result in growth of hard plasma polymer (C:H) or even amorphous hydrogenated carbon (a‐C:H) . Copper nanoparticles were in this study simultaneously delivered from the GAS in contrary to usual preparation technique based on metal magnetron sputtering combined with plasma polymerization (PECVD) of a hydrocarbon gas added to the working gas argon .…”

Section: Introductionmentioning

confidence: 99%

Deposition of Ag/a-C:H nanocomposite films with Ag surface enrichment

Vaidulych

Hanuš

Steinhartova

et al. 2017

Plasma Process Polym

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The nanocomposite films Ag/a‐C:H were prepared by vacuum‐based method which combines deposition of Ag nanoparticles by means of gas aggregation source (GAS) and PECVD deposition of a‐C:H matrix. The matrix was deposited in a mixture of Ar and n‐hexane on the substrates placed on the powered RF electrode facing the beam of Ag NPs from the GAS. Anisotropic plasma etching was used to increase Ag concentration on the surface of the coating. The influence of three types of plasma on the chemical composition of the coatings and on the size of Ag nanoparticles is described. It is shown that the best etching selectivity and thus the highest Ag surface concentration was reached in case of etching of grounded samples in low pressure oxygen plasma. This treatment enhances the short term antibacterial efficiency of produced coatings.

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Deposition of Cu/a-C:H Nanocomposite Films

Cited by 20 publications

References 45 publications

Effect of magnetic field on the formation of Cu nanoparticles during magnetron sputtering in the gas aggregation cluster source

Effect of magnetic field on the formation of Cu nanoparticles during magnetron sputtering in the gas aggregation cluster source

Core@shell Cu/hydrocarbon plasma polymer nanoparticles prepared by gas aggregation cluster source followed by in‐flight plasma polymer coating

Deposition of Ag/a-C:H nanocomposite films with Ag surface enrichment

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