TiO<sub>2</sub> thin film patterns prepared by chemical vapor deposition and atomic layer deposition using an atmospheric pressure microplasma printer

Aghaee, Morteza; Verheyen, J Joerie; Stevens, A.A.E.; Kessels, W.M.M.; Creatore, M.

doi:10.1002/ppap.201900127

Cited by 24 publications

(19 citation statements)

References 67 publications

(92 reference statements)

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“…A microplasma printer which was originally developed for surface functionalization has also now been demonstrated for patterned deposition of metal oxide films via atomic layer deposition (ALD). [ 140 ] Importantly, the printing head illustrated in the left of Figure 12a is comprised of multiple needle electrodes (top right of Figure 12a) that can individually actuate (bottom right of Figure 12a) to selectively deposit and obtain patterned films. Though these results remain primarily focused on 2D geometries, one can easily envision the build‐up of layers in 3D.…”

Section: Towards 3d‐printed Fabricationmentioning

confidence: 99%

“…Plasmas in three‐dimensional (3D) printing configurations. (a) Microplasma printer composed of a multi‐needle‐to‐plate dielectric barrier discharge shown by illustrations of printing head (left), printing when all needle electrodes are activated (top right), and printing a pattern when specific needle electrodes are activated (bottom right), reprinted with permission from Aghaee et al [ 140 ] (b) Capacitively‐coupled radiofrequency plasma with a double‐helix electrode configuration termed HelixJet shown by photo at 3‐ns exposure time (left), 3D plot of the calculated electric field (middle), and axial cut ( y = 0) of the calculated electric field (right), reprinted with permission from Schafer et al [ 141 ] Isosurfaces with constant electric field are indicated by A (102 kV/m), B (130 kV/m), and C1 or C2 (174 kV/m)…”

Section: Towards 3d‐printed Fabricationmentioning

confidence: 99%

“…Therefore, the possibility of rapid treatment is realistic. Arrays of microplasma jets, as demonstrated by the microplasma printer, [ 140 ] could aid in shortening the processing times for larger area films.…”

Section: Challenges and Outlookmentioning

confidence: 99%

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Plasmas for additive manufacturing

Sui

Zorman

Sankaran

2020

Plasma Processes & Polymers

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Additive methods for manufacturing materials have recently emerged, particularly for the fabrication of three-dimensional architectures. Because of their long history in thin-film etching and deposition, plasmas offer unique advantages for many of the materials and surface processes associated with additive manufacturing. Here, we review recent efforts that have been primarily focused on the direct writing of patterned structures and the post-treatment of printed materials. Different configurations, materials, and applications are presented. Current challenges and a future outlook are also provided. 3D printing, additive manufacturing, microdischarges, nanotechnology, roll-to-roll

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Section: Towards 3d‐printed Fabricationmentioning

confidence: 99%

Section: Towards 3d‐printed Fabricationmentioning

confidence: 99%

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Plasmas for additive manufacturing

Sui

Zorman

Sankaran

2020

Plasma Processes & Polymers

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“…Because it is still challenging to use PEALD to manufacture TiO 2 thin films roll-to-roll, other possibilities to use this technique for industrial applications were explored. Very recently, a micro-plasma printer was employed to deposit TiO 2 thin film with desired patterns using PEALD at atmospheric pressure with a N 2 /O 2 gas mixture [93]. The properties of TiO 2 films deposited by this method showed a higher refractive index and lower level of impurities compared to the properties of films deposited using the CVD technique.…”

Section: Plasma-enhanced Atomic Layer Depositionmentioning

confidence: 99%

“…The properties of TiO 2 films deposited by this method showed a higher refractive index and lower level of impurities compared to the properties of films deposited using the CVD technique. Moreover, the patterning resolution was twice as high as those from the latter technique, but it still requires more improvements to be applied in plasma printing technology in area-selective deposition [93].…”

Section: Plasma-enhanced Atomic Layer Depositionmentioning

confidence: 99%

Atmospheric Pressure Plasma Deposition of TiO2: A Review

et al. 2020

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Atmospheric pressure plasma (APP) deposition techniques are useful today because of their simplicity and their time and cost savings, particularly for growth of oxide films. Among the oxide materials, titanium dioxide (TiO2) has a wide range of applications in electronics, solar cells, and photocatalysis, which has made it an extremely popular research topic for decades. Here, we provide an overview of non-thermal APP deposition techniques for TiO2 thin film, some historical background, and some very recent findings and developments. First, we define non-thermal plasma, and then we describe the advantages of APP deposition. In addition, we explain the importance of TiO2 and then describe briefly the three deposition techniques used to date. We also compare the structural, electronic, and optical properties of TiO2 films deposited by different APP methods. Lastly, we examine the status of current research related to the effects of such deposition parameters as plasma power, feed gas, bias voltage, gas flow rate, and substrate temperature on the deposition rate, crystal phase, and other film properties. The examples given cover the most common APP deposition techniques for TiO2 growth to understand their advantages for specific applications. In addition, we discuss the important challenges that APP deposition is facing in this rapidly growing field.

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Thin‐film deposition by combining plasma jet with spark discharge source at atmospheric pressure

Ussenov

Toktamyssova

Dosbolayev

et al. 2020

Contributions to Plasma Physics

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This study demonstrates a method for the deposition of CuO x thin films by combining atmospheric pressure plasma jet with spark discharge. In this type of discharge source, the bulk copper material of spark discharge electrodes plays the role of a precursor. Copper atoms and particles go through the physical processes of sputtering, evaporation, and further agglomeration and condensation in the plasma jet and on the substrate. The experiments were carried out with and without a combination of discharges. The material coated on the substrate was studied using a scanning electron microscope, Raman spectroscopy, and energy-dispersive X-ray spectroscopy. The characteristics of the setup and plasma, such as I-V curves, optical emission spectra, and substrate temperature, were also measured. Copper electrodes were examined for erosion by a scanning electron microscope. The results demonstrate that deposits coated by combined discharge show denser and thicker films. K E Y W O R D S atmospheric pressure plasma jet, dielectric barrier discharge, low-temperature atmospheric-pressure plasma, spark discharge, thin film deposition

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TiO₂ thin film patterns prepared by chemical vapor deposition and atomic layer deposition using an atmospheric pressure microplasma printer

Cited by 24 publications

References 67 publications

Plasmas for additive manufacturing

Plasmas for additive manufacturing

Atmospheric Pressure Plasma Deposition of TiO2: A Review

Thin‐film deposition by combining plasma jet with spark discharge source at atmospheric pressure

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TiO2 thin film patterns prepared by chemical vapor deposition and atomic layer deposition using an atmospheric pressure microplasma printer

Cited by 24 publications

References 67 publications

Plasmas for additive manufacturing

Plasmas for additive manufacturing

Atmospheric Pressure Plasma Deposition of TiO2: A Review

Thin‐film deposition by combining plasma jet with spark discharge source at atmospheric pressure

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Product

Resources

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TiO₂ thin film patterns prepared by chemical vapor deposition and atomic layer deposition using an atmospheric pressure microplasma printer