Generation of Charged Ti Nanoparticles and Their Deposition Behavior with a Substrate Bias during RF Magnetron Sputtering

Kwon, Jihye; Kim, Du-Yun; Hwang, Nong‐Moon

doi:10.3390/coatings10050443

Cited by 9 publications

(6 citation statements)

References 40 publications

(45 reference statements)

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“…At the same time, they will be repelled by the substrate with the bias of +50 V, decreasing the number density of Ti NPs captured on the TEM membrane (Figure 3c,f). In agreement with these results, Kwon et al reported that the positively charged Ti NPs were generated during Ti RF sputtering [32]. The strong dependence of the number density of Ti NPs on the electrical bias in Figure 3 indicates not only that some of the Ti NPs are electrically charged but also that they were formed in the gas phase instead of being nucleated on the TEM membrane.…”

Section: Capturing Charged Nps With Various Pressure During Rf Sputtering With a Ti Targetsupporting

confidence: 73%

“…One possible way to determine which of the small neutral NPs and atoms is a dominant flux for film deposition would be studying the crystallinity of the film deposited under the positive bias. A similar study was conducted by Kwon et al [32]. The results will be shown later.…”

Section: Capturing Charged Nps With Various Pressure During Rf Sputtering With a Ti Targetsupporting

confidence: 63%

“…Jeon et al [26] reported that porous films with a rough surface morphology were obtained under the condition in which neutral NPs were generated, whereas dense films with a smooth morphology were obtained under the condition in which charged NPs were generated during the thermal evaporation of copper. This aspect was also studied by Kwon et al [32], who reported that neutral NPs produce not only films of poor crystallinity but also films of low density. To determine whether neutral atoms or neutral NPs are the main flux, the crystallinity of films, which can be analyzed by XRD, should be examined.…”

Section: Deposition Of Ti Thin Films Under Various Pressuresmentioning

confidence: 68%

“…Recently, the generation of negatively charged NPs and their contribution to film growth were studied during DC sputtering of Ag [31]. Only one paper was published on the generation of positively charged NPs and their contribution to film growth during RF sputtering of Ti [32]. Thus, a more systematic study is needed concerning how the generation of charged NPs is affected by processing parameters such as pressure in the sputtering process.…”

Section: Introductionmentioning

confidence: 99%

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Effect of Pressure on the Film Deposition during RF Magnetron Sputtering Considering Charged Nanoparticles

et al. 2021

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Non-classical crystallization, in which charged nanoparticles (NPs) are the building blocks of film growth, has been extensively studied in chemical vapor deposition (CVD). Recently, a similar mechanism of film growth has been reported during radio frequency (RF) sputtering with a Ti target and DC magnetron sputtering using an Ag target. In this study, the effect of pressure on the generation of Ti NPs and on the film deposition was studied during RF sputtering with a Ti target. Ti NPs were captured on transmission electron microscopy (TEM) membranes with the electric biases of −30, 0, and +50 V under 20 and 80 mTorr. The number densities of the Ti NPs were 134, 103, and 21 per 100 × 100 nm2, respectively, with the biases of −30, 0, and +50 V under 20 mTorr and were 196, 98, and 0 per 100 × 100 nm2, respectively, with the biases of −30, 0, and +50 V under 80 mTorr, which was analyzed by TEM. The growth rate of Ti films deposited on Si substrates was insensitive to the substrate bias under 20 mTorr but was sensitive under 80 mTorr, with the thicknesses of 132, 133, 97, and 29 nm, respectively, after being deposited for 15 min with the substrate biases of −30, −10, 0, and +50 V. This sensitive dependence of the film growth rate on the substrate bias under 80 mTorr is in agreement with the sensitive dependence of the number density of Ti NPs on the substrate bias under 80 mTorr.

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Section: Capturing Charged Nps With Various Pressure During Rf Sputtering With a Ti Targetsupporting

confidence: 73%

Section: Capturing Charged Nps With Various Pressure During Rf Sputtering With a Ti Targetsupporting

confidence: 63%

Section: Deposition Of Ti Thin Films Under Various Pressuresmentioning

confidence: 68%

Section: Introductionmentioning

confidence: 99%

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Effect of Pressure on the Film Deposition during RF Magnetron Sputtering Considering Charged Nanoparticles

et al. 2021

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“…However, an electric bias in these techniques would be used toward the anode, which can overlap within the plasma or require complicated and costly requirements. So the DC sputtering technique can be considered a simple and low cost to obtain metal's and alloy's thin films [24]. In the physical vapor deposition (DC sputtering process), an electron is accelerated from the cathode toward the argon atom and collide with it to produce the argon ion, this ion has a positive charge, so it will attract toward the cathode to eject an atom from the target toward the substrate.…”

Section: Introductionmentioning

confidence: 99%

Improvement of Substrates Properties by Incorporating Titanium Nanoparticles Deposited by DC Diode Sputtering Approach

Hadi¹,

Jawad²,

Hassoon³

2022

JASN

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In this work, the synthesis of titanium thin films on two different substrates (glass and n-type Si), with thicknesses of 90 and 145 nm at two different times (5 and 10 min) respectively, have been obtained. The thin films have been successfully deposited on glass and silicon substrates using DC diode sputtering technique. The optical properties of the prepared thin films have been checked out using the optical reflectance spectrum. A significant reduction in surface reflectivity was observed at (10 min) sputtering time. The structural properties of the prepared thin films were studied using X-ray diffraction (XRD) and field-emission scanning electron microscopy (FE-SEM). XRD results confirmed that titanium thin films had a hexagonal structure with preferred orientation on (002). The images of FESEM showed that all the samples had a uniform distribution of granular surface morphology. The grain sizes of the Ti nanostructure were estimated using Scherrers' analysis. The thickness of Ti thin film increased as the sputtering time increased for both glass and Si n-type substrates. The repeated experiments revealed that the most uniform Ti thin film is on Si substrate (n-type) with particle size 10 nm at deposition time 5 min.

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Dependence of the Generation Behavior of Charged Nanoparticles and Ag Film Growth on Sputtering Power during DC Magnetron Sputtering

Jang

Kim

Hwang

2021

Electron. Mater. Lett.

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Effects of sputtering power on the deposition rate and microstructure, crystallinity, and electrical properties of Ag films during direct current (DC) magnetron sputtering are investigated. Thin films (~ 100 nm) are deposited at sputtering powers of 10, 20, 50, 100, 200 and 300 W and analyzed by field-emission scanning electron microscopy (FESEM), X-ray diffraction (XRD), transmission electron microscopy (TEM) and a four-point probe. The film deposited at a sputtering power of 10 W has the lowest growth rate, but the highest crystalline quality, with the lowest full width at half maximum (FWHM) and the lowest resistivity. The film deposited at a sputtering power of 200 W has the highest growth rate, and the second best crystalline quality in view of FWHM and resistivity. The film deposited at a sputtering power of 50 W has the moderate growth rate, and the worst crystalline quality in view of FWHM and resistivity. High-resolution TEM observations reveal that films deposited at sputtering powers of 10 and 200 W have far fewer defects, such as grain boundaries, dislocations and stacking faults than those deposited at a sputtering power of 50 W. Such deposition behavior could be explained by sputtering power, which affected the generation of the charged nanoparticles. And the high quality of films could be obtained at a high deposition rate, in which charge plays an important role. Graphic Abstract

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Generation of Charged Ti Nanoparticles and Their Deposition Behavior with a Substrate Bias during RF Magnetron Sputtering

Cited by 9 publications

References 40 publications

Effect of Pressure on the Film Deposition during RF Magnetron Sputtering Considering Charged Nanoparticles

Effect of Pressure on the Film Deposition during RF Magnetron Sputtering Considering Charged Nanoparticles

Improvement of Substrates Properties by Incorporating Titanium Nanoparticles Deposited by DC Diode Sputtering Approach

Dependence of the Generation Behavior of Charged Nanoparticles and Ag Film Growth on Sputtering Power during DC Magnetron Sputtering

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