AuN films - structure and chemical binding

Quintero, Jorge; Arango, P.J.; Ospina, Rogelio; Mello, Alexandre; Mariño, A.

doi:10.1002/sia.5766

Cited by 12 publications

(6 citation statements)

References 30 publications

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“…The literature has reported binding energies of 398.4 eV (near energy observed to S5, shown in Figure A) for RuN components . Energies of approximately 397.5 eV can be attributed to RuN components because values between 396.0 and 398.0 eV are characteristic of nitrogen hybridization with transition metals . Binding energies near 398.8 eV are typical of oxynitrides .…”

Section: Resultsmentioning

confidence: 91%

“…In the case of the final peaks of the high‐resolution Ru3d spectra, the envelope curve does not fulfill the experimental data; this behavior is because peaks exhibit asymmetries and tails that are not totally fulfilled by the Shirley Background. For this reason, Doniach Sunjic line shape method was applied to deconvolute these peaks; furthermore, in the literature, it is reported that peaks belonging to noble metals do not exhibit significant changes when they are bonded with low concentrations of nitrogen . Because in all cases, nitrogen is present at lower percentages than Ru, even after the SE process, it can be concluded that the films are mainly composed of a metallic phase.…”

Section: Resultsmentioning

confidence: 99%

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Influence of nitrogen partial pressure on the microstructure and morphological properties of sputtered RuN coatings

Quintero

Ospina

Mello

et al. 2017

Surf Interface Anal

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In this work, the production of RuN thin films using the reactive direct current magnetron sputtering technique is presented. Samples were grown with varying Ar/N2 ratio with values of 60/40, 80/20, 85/15, 90/10, 95/5, and 100/0. X‐ray photoelectron spectroscopy was employed to determine the presence of RuN before and after a sputtering etching process. According to the high‐resolution of N1s spectra, 3 peaks were identified at 397.4 ± 0.3 eV, 398.3 ± 0.3 eV, and 398.8 ± 0.3 eV binding energies, corresponding to hybridizations of nitrogen with transition metals, oxynitrides, and oxycarbides. X‐ray diffraction analyses were performed, showing the coexistence of the RuN face‐centered cubic and Ru hexagonal compact packed phases. After the etching process, the samples grown at nitrogen flow rates greater than 15% continued to show the RuN face‐centered cubic phase. Atomic force microscope analyses showed that as the nitrogen concentration increased, the grain size and roughness also tended to increase.

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Section: Resultsmentioning

confidence: 91%

Section: Resultsmentioning

confidence: 99%

Influence of nitrogen partial pressure on the microstructure and morphological properties of sputtered RuN coatings

Quintero

Ospina

Mello

et al. 2017

Surf Interface Anal

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“…Displacements, shifts to the higher or lower Bragg angles with respect to the PDF pattern, can be observed commonly in thin films for a compressive stress or tensile stress (Li et al ., 1998). Asymmetry can be due to a new phase in interstitial sites, causing the lattice planes to be unbalanced or resulting/deriving in a mechanical flexion of the crystal (Quintero et al ., 2015). Apparently, the factor for the SiNWs asymmetry is silver depositing on the SiNWs to cause mechanical flexion of SiNWs.…”

Section: Resultsmentioning

confidence: 99%

Grazing incidence X-ray diffraction measurement of silver nanoparticles in metal-assisted etching of silicon

et al. 2020

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Silicon nanowires (SiNWs) were fabricated in a metal-assisted chemical etching method with two steps including dipping silicon wafers in AgNO3/HF solutions and then in H2O2/HF solutions. Grazing incidence X-ray diffraction measurements with a set of incidence angles were carried out on the resulting samples to detect characteristics of silver nanoparticles in the etched silicon. Compared with the uniform size of silver nanoparticles on the surface, the silver nanoparticles in etched silicon were found with size increasing and content decreasing corresponding to the depths. Based on the silver size increasing phenomenon, a detailed supplementary hypothesis about SiNWs formation was proposed about silver disintegration and redeposition in the later stage of silicon etching. For 2, 3, 4, and 8 mM AgNO3 solutions used to study their effect on the SiNWs, it was found that a higher quantity of Ag+ concentration such as 8 mM were not beneficial for producing good quality SiNWs.

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“…In C1s: C, 16 CO, 17 CN, 18 CO 3 . 19 In N1s: MeN (metal nitride), 20,21 CN, 22 CNO, 23 CN and NO, 24,25 to blocking the slip grain border. 47 If the temperature is continuously increasing, the presence of the CO 2 would accelerate the corrosion on the surface and increase the roughness such that the hardness falls abruptly 8 ; besides, the displacement produced by O atoms would have a decisive effect on the oxidation behavior.…”

Section: Results and Analysismentioning

confidence: 99%

“…In C1s: C, 16 CO, 17 CN, 18 CO 3 19 . In N1s: MeN (metal nitride), 20,21 CN, 22 CNO, 23 CN and NO, 24,25 NO, 26 N 2 , 27 NO 2 26 . In O1s: O 2 , 28 C x O y , 29 TiO 2 and ZrO 2 , 30 TiNO x , 31 TiO, 18 CNO, 23 NO x , 32 CO 33 .…”

Section: Results and Analysismentioning

confidence: 99%

Thermal treatment of (TiZr)N coatings on CO₂‐controlled atmosphere

Rincón‐Ortiz

Ospina

Páez

et al. 2020

Surface & Interface Analysis

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Currently, studies about the CO 2 gas injection improve the production efficiency of crude oil. The surface interaction between CO 2 and thin films is a large area of research in the scientific community. In this work, we are showing that The TiZrN (coating) + Si (substrate) system immersed on environments of fully CO 2 can interact to below 400 C temperature, because the TiZrN (coating) + Si (substrate) system is broken to temperatures above of the 400 C. The Ti2p, Zr3d, N1s, O1s, and C1s narrow spectra are shown, which illustrate the evolution of TiZrN to TiN x , TiO x , and TiON x compounds and afterwards to TiO 2 and ZrO 2 phases. TiN x , TiO x , and TiON x compounds are responsible for the increase of the micro-hardness (measured through Vickers Hardness Testing) of the system (TiZrN [coating] + Si [substrate]) due to that are found at 400 C thermal treatment. Topographical images obtained by atomic force microscopy showed an increase of the surface roughness due to the thermal treatment. Scanning electron microscopy demonstrated that sample submit to 600 C temperature suffered fracture with small indentations.

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AuN films - structure and chemical binding

Cited by 12 publications

References 30 publications

Influence of nitrogen partial pressure on the microstructure and morphological properties of sputtered RuN coatings

Influence of nitrogen partial pressure on the microstructure and morphological properties of sputtered RuN coatings

Grazing incidence X-ray diffraction measurement of silver nanoparticles in metal-assisted etching of silicon

Thermal treatment of (TiZr)N coatings on CO₂‐controlled atmosphere

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AuN films - structure and chemical binding

Cited by 12 publications

References 30 publications

Influence of nitrogen partial pressure on the microstructure and morphological properties of sputtered RuN coatings

Influence of nitrogen partial pressure on the microstructure and morphological properties of sputtered RuN coatings

Grazing incidence X-ray diffraction measurement of silver nanoparticles in metal-assisted etching of silicon

Thermal treatment of (TiZr)N coatings on CO2‐controlled atmosphere

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Thermal treatment of (TiZr)N coatings on CO₂‐controlled atmosphere