RF Sputtering Process Research Articles

Deposition and Characterization of Indium-Tin Oxide Thin Films Deposited by RF Sputtering

Tin-doped indium oxide (ITO) is an n-type degenerate semiconductor routinely used as an electrode in various optoelectronic devices such as flat panel displays, solar cells and organic electroluminescence devices due to its unique combination of properties, including high optical transparency, low electrical resistance and excellent surface adhesion. The purpose of this work is to find out the best method of obtaining ITO thin films through RF sputtering process. The ITO samples used in this study were obtained by reactive RF sputtering; each one acquired with different sputtering parameters, in special the RF power. The characterization of the samples was made by measuring their thickness and refraction index in three different wavelengths. Measures as sheet resistances and atomic percentages were also found by equipments such as ellipsometer, four point probe and micro analyse.

The Heat Treatment Characteristics of Hydroxyapatite Thin Films Deposited by RF Sputtering

RF sputtering process was applied to produce thin hydroxyapatite(HAp, Ca10(PO4)6(OH)2) films on Ti-6Al-4V alloy substrates. The effects of different heat treatment conditions on the bonding strength between HAp thin films and Ti-6Al-4V alloy substrates were studied. Before deposition, the Ti-6Al-4V alloy substrates were heat treated for 1hr at 850°C under 3.0×10-3torr, and after deposition, the HAp thin films were heat treated for 1hr at 400°C, 600°C and 800°C under the atmosphere, and analyzed optical microscope, FESEM, FTIR, XRD, nano-indentor, micro-vickers hardness, respectively. Experimental results represented that the HAp thin films on the heat treated substrates had higher hardness than none-heat treated substrates before the deposition.

Study of Reactive RF Sputtering Process of Silicon Target Under ArO2N2 Atmospheres

The instability phenomenon of RF sputtering of silicon target under ArO2N2 gas mixtures was investigated. The variations of plasma characteristics are correlated to those of the total pressure and the target bias voltage. The transition between the elemental and compound sputtering modes corresponds to an oxidation of the target surface and leads to abrupt changes in the analysed parameters. The influence of nitrogen flow, argon pressure and discharge power on the shape of the hysteresis loop is reported. This study allows us to set up a process calibration method by means of a correlation between the concentration of silicon, oxygen and nitrogen in the plasma and the elemental composition of the deposit.

Transport properties of some rare‐earth mono and bilayer manganite films

AbstractWe report the transport properties of both single‐layer (SL) La0.67Sr0.33MnO3 (SL1), La0.67Ca0.33MnO3 (SL2) and La0.67Sr1.33MnO4 (SL3) each of thickness 135 nm and bilayers (BL) SL1/SL3 (BL1) and SL2/SL3 (BL2) each of thickness 270 nm. All the films are deposited on SrTiO3(001) substrates by the off‐axis RF sputtering process. Compared to SL films, a large enhancement of magnetoresistance (MR) at 1.2 T field is observed in the BL films. Except for the antiferromagnetic (AF) SL3 film, two ferromagnetic (FM) films SL1 and SL2 showed metallic transitions, respectively, at T MI = 248 and 365 K. For the BL films, T MI shifts largely towards a lower temperature than the corresponding T MI of the corresponding SL films due to the increase of disorder and strain effect at the junction of the films. Temperature‐dependent resistivity (ρ ) curves, above T MI, are best fitted by the adiabatic small‐polaron hopping model, i.e. ρ = ρ 0T exp (E a/k BT ) with activation energy E a (BL) > E a(SL). Within the temperature range T D/2 < T < T MI (T D being the Debye temperature), the resistivity curves are well fitted with the variable range hopping (VRH) with effective number of carriers at the Fermi level [N (E F)], being different for BL and SL films. In the SL films, spin ordering completes below a critical temperature (T *, say) and a changeover of the transport mechanism dominated by the electron–electron scattering regime (T < T *) to an electron–magnon‐dominated scattering regime (T > T *) is observed. (© 2006 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)

The ESCA Analysis of Hydroxyapatite Thin Films Deposited by RF Sputtering

RF sputtering process was applied to produce thin hydroxyapatite(HAp) films on Ti-6Al-4V alloy substrates. The effects of different heat treatment conditions on the chemical composites between HAp thin films and Ti-6Al-4V alloy substrates were studied. After deposition, the HAp thin films were heat treated for 1h at under the atmosphere, and analyzed O/M, FESEM-EDX and ESCA, respectively. Experimental results represented that interface of HAp thin films and Ti-6Al-4V alloy substrates was composed Ti-OH, TiO, TiN, . pyrophosphate and decreased carbide followed by the increase of heat treatment temperature.

The Heat Treatment Characteristics of Hydroxyapatite Thin Films Deposited by RF Sputtering

【RF sputtering process was applied to produce thin hydroxyapatite(HAp) films on Ti-6Al-4V alloy substrates. The effects of different heat treatment conditions on the hardness between HAp thin films and Ti-6Al-4V alloy substrates were studied. Before deposition, the Ti-6Al-4V alloy substrates were heat treated for 1h at $850^{\circ}C\;under\;3.0{\times}10^{-3}torr$ , and after deposition, the HAp thin films were heat treated for 1h at $400^{\circ}C,\;600^{\circ}C\;and\;800^{\circ}C$ under the atmosphere, and analyzed FESEM-EDX, FTIR, XRD, nano-indentor, micro-vickers hardness, respectively. Experimental results represented that the surface defects of thin films decreased by relaxation of internal stress and control of substrate structure followed by heat treatment of substrates before the deposition, and the HAp thin films on the heat-treated substrates had higher hardness than none heattreated substrates before the deposition, and the hardness properties of HAp thin films and Ti-6Al-4V alloy substrates appeared independent behavior, and the hardness of HAp thin films decreased by formation of $VTiO_3(OH),\;{\theta}-Al_{0.32}V_2O_5,\;Al_{0.33}V_2O_5$ .】

Comparison of Electrochemical Behavior of LiCoO2 Thin Films Prepared by Sol-Gel and Sputtering Processes

The effects of crystal orientation and the presence of impurity phase on Li-ion insertion and extraction processes and oxidation behavior of propylene carbonate (PC) containing were investigated by using thin films prepared by the sol-gel process and rf sputtering with cyclic voltammetry, electrochemical impedance measurement, in situ Fourier transform infrared (FTIR) spectroscopy, and X-ray photoelectron spectroscopy (XPS). Three kinds of thin film electrodes were prepared by rf sputtering and sol-gel processes. These electrodes contained different amounts of cubic phase as an impurity phase and had different crystal orientations depending on the preparation conditions. These properties greatly influenced the electrochemical behaviors and adsorption phenomena of oxidation products derived from PC. The organic surface film on thin film was analyzed with XPS. This surface film formation also depended on the crystal orientation and amount of impurity involved in the thin films. When the (003) plane of the is more perpendicular to substrate and the thin film does not contain impurity, the best electrochemical performance can be attained.

Effects of O2/Ar flow ratio on the alcohol sensitivity of tin oxide film

Abstract The aim of this study is to find the effects of oxygen flow rate during manufacturing on the sensitivity of SnO 2 (tin oxide) thin films to ethanol (C 2 H 5 OH). In this study, an RF sputtering process was employed to fabricate the SnO 2 thin films. The SnO 2 was deposited on gold electrode silicon microchips. A target composed of SnO 2 doped with 1 at.% Li was used with a working pressure of 3 mTorr. The RF power was fixed at 150 W. The reaction gas was a mixture of argon and oxygen. The total flow rate was constant at 50 sccm with the O 2 /Ar ratio varying from 0.2 to 0.8. An annealing heat treatment was employed at 400 °C for 1 h to stabilize the properties of the films. The sensitivity of the film to ethanol was tested by placing the micro-reactor device on a hot plate, heated to 300 °C, and measuring the variation of electrical resistivity of the film with and without the presence of ethanol. The results show that an O 2 /Ar flow ratio of 0.2 produces films with the highest ethanol sensitivity. Before heat treating, the ethanol sensitivity was 126. After heat treating at 400 °C for 1 h, the sensitivity decreased to 104.

Internal field and self-polarization in sol–gel-derived lead zirconate titanate films

An internal electric field is induced in a sol–gel-derived lead zirconate titanate (PZT) film of thickness 2 μm after the rf-sputtering deposition of the top electrode and this is exhibited as a shift of the P–E loop towards the positive side of the electric field axis. The direction of the internal field is towards the bottom electrode. As the discharge power used for the sputtering decreases, the internal field increases. We suggest that the internal field is induced by the high-energy ion bombardment on the film surface during the rf-sputtering process. Due to the occurrence of the internal field, the as-prepared PZT film becomes self-polarized at a high deposition temperature of 150 °C, thus showing a non-zero pyroelectric coefficient at room temperature. As the internal field increases, the observed pyroelectric coefficient increases and has a large value of 230 μC/m2 K for an as-prepared PZT film with an internal field of 40 kV/cm.

Performance Characterization of Thin AlN Films deposited on Mo Electrode for Thin-Film Bulk Acoustic-Wave Resonators

In this paper, we discuss the implementation and testing of a film bulk acoustic-wave resonator (FBAR) comprising an AlN piezoelectric thin film sandwiched between two metal electrodes and located on a silicon substrate with a low-stress silicon nitride (Si3N4) support membrane. In the present study, we choose molybdenum as the bottom electrode rather than the conventionally used Pt/Ti, Au/Cr or Al because it has a low acoustic attenuation and a good electrical conductivity, and provides a good adhesion between the thin AlN film and the low-stress Si3N4 membrane. We investigate the influence of AlN film thickness and top-electrode thickness on the resonance frequency of the FBAR device. The results indicate that decreasing the thickness of either the AlN film or the top electrode increases the resonance frequency. This suggests the potential of tuning the performance of the FBAR device by the carefully controlling AlN film thickness. Furthermore, it is also determined that the resonance frequency of the device can be increased by specifying a higher RF power for the magnetron sputtering process used to deposit the AlN film. This study employs an X-ray diffraction (XRD) technique to investigate the influence of AlN film thickness and RF power on the c-axis orientation of the thin film. It is shown that increasing either the thickness of the AlN film or the power of the RF sputtering process improves c-axis orientation. However, scanning electron microscopy (SEM) and atomic force microscopy (AFM) results reveal that a thicker AlN film exhibits a rougher surface and a larger grain size, both of which decrease the coupling factor of the FBAR device.

The effect of pre-treatment of substrate on fretting tribological behavior of MoS 2 coatings

MoS 2 coatings were deposited by a radio frequency (rf) sputtering process on 1045 steel substrate which was pre-treated with ion-plated TiN and shot-peening processes. A series of fretting wear experiments were conducted to investigate the effects of various properties of substrate induced by different pre-treatment methods on the fretting tribological behavior of MoS 2 coatings. The results showed that the fretting damage of MoS 2 coating was greatly dependent on the surface characteristics, mechanical and physical-chemical properties of the substrate. The transfer and smearing of MoS 2 coating in the initial wear stage, the oxidation, and delamination of MoS 2 layers in the later wear process, were always subjected to the effects of mechanical properties of substrate, surface morphology, distribution of contact stress, and the adhesion strength of MoS 2 coatings. Additionally, the fretting tribological behavior of MoS 2 coatings was also affected by the change of its microstructure, the plastic deformation ability of the substrate and their synergistic effect.

The Fabrication of Hydroxyapatite Teargets and the Characteristics of Hydroxyapatite/Ti-6Al-4V alloy Thin Films by RF Sputtering(I)

RF sputtering process was applied to produce thin hydroxyapatite［HA, Ca10(<TEX>$PO_4$</TEX>)<TEX>$_{6}$</TEX> <TEX>$ (OH)_2$</TEX>films on Ti-6Al-4V alloy substrates. To make a 101.6 mm dia.<TEX>${\times}$</TEX>5 mm HA target, the commercial HA powder was first calcinated for 3h at <TEX>$200^{\circ}C$</TEX>. A certain amount of the calcinated HA powder was pressed under a pressure of 20,000 psi by the cold isostatic press(CIP) and the pressed HA target was sintered for 6 h at <TEX>$1,200^{\circ}C$</TEX>. The effects of different heat treating conditions on the bonding strength between HA thin films and Ti-6Al-4V alloy substrates were studied. Before deposition, the alloy substrates were annealed for 1 h at <TEX>$850^{\circ}C$</TEX> under <TEX>$3.0<TEX>${\times}$</TEX>10^{-3}$</TEX> Xtorr, and after deposition, the hydroxyapatite/Ti-6Al-4V alloy thin films were annealed for 1 h at 400, 600 and <TEX>$800^{\circ}C$</TEX> under the atmosphere, respectively. Experimental results represented that the HA thin films on the annealed substrates had higher hardness than non-heat treated substrates before the deposition.

Enhancement of emission characteristics for field-emitter arrays by optimizing the etched feature of the gate electrode

The etched features of thin chromium (Cr) films deposited on SiO2–Si substrate were investigated as a function of the substrate temperature during rf sputtering deposition. In this work, the changes of both the grain structures and crystallographic orientations of sputtered Cr films as a function of substrate temperature were examined, and we found that the tapering angle θt of thin Cr film after reactive ion etching depends on the deposition condition, especially the substrate temperature during the rf sputtering process. Based on the obtained results, we fabricated two kinds of Cr-grated Mo-tip field-emitter arrays (FEAs): the first kind is a FEA with tapered-gate electrode (tapered-gated FEA, θt⩽90°) and the second kind is a FEA with taper-free gate electrode (nontapered-gated FEA, θt=90°). We obtained more emission current than that of tapered-gated FEAs, whereas the gate leakage current of nontapered-gated FEAs was almost the same value as compared to that of tapered-gated FEAs. Because of the optimized etched shape of the gated electrode, the field conversion factor β of the nontapered-gated FEAs increased to 32% more than that of tapered-gated FEAs. Furthermore, the total transconductance Gm of nontapered-gated FEAs increased to 20% without increasing the packing density of FEAs.

Transparent films on polymers for photovoltaic applications

Highly conductive and transparent tin-doped indium oxide (ITO) films have been prepared by RF sputtering processes on polymer substrates, polyethylene terepthalate (PET) and polyimide (Kapton KJ ®), and onto glass as reference. The utilisation of a RF plasma pre-treatment of the organic substrate surface leads to the realisation of adherent films on unheated substrates with good optoelectronic properties and without damage to the polymers. High transparency, near 80% on the 400–1100 nm spectra range, and conductivity, σ>10 3 (Ω cm) –1, have been achieved for ITO films deposited onto PET and Kapton KJ ® substrates. These are adequate values for the utilisation of these modified polymer samples as substrates for photovoltaic solar cells. Better optical and electrical properties of the ITO films have been observed when deposited on polymer foils if compared with those deposited on glass. Improved quality of ITO samples have been correlated with the growth of more oriented and crystalline ITO films along the preferred orientation 〈1 0 0〉. The ITO films fabricated on polymers by the method proposed do not require substrate heating during the film preparation or any post-deposition annealing treatment in order to achieve the optoelectronic quality required.

Electrical and mechanical properties of SnO 2:Nb films for touch screens

SnO 2:Nb (Nb: 0–3.0 wt%) films were deposited on glass substrates by RF sputtering process. Electrical, optical and mechanical properties of the films as-deposited and post-annealed are measured in order to examine the feasibility for using as an electrode of the resistive touch screen with an analogue-type. X-ray diffraction (XRD) measurements of sintered SnO 2:Nb specimen and the Rietvelt analysis of the XRD pattern were also carried out in order to find the doping effect of Nb to SnO 2. Glancing angle XRD patterns of SnO 2:Nb films showed a single phase of SnO 2 with rutile structure. Average optical transmittance of the films in visible range was >80%. For the films deposited at 300°C, the resisitivity decreases to 1×10 −1 Ω cm with increasing Nb concentration to 2.0 wt%. After the post-annealing of the films at 300°C in air and N 2, the resistivity of the films decreased to 3×10 −2 and 7×10 −3 Ω cm, respectively. These properties of the post-annealed films satisfy the requirements for an electrode of the touch screen. From the results of XRD measurements and the Rietvelt analysis for the sintered SnO 2:Nb specimen, it is found that Sn ions are substituted by Nb ions for sintered SnO 2:Nb powder with Nb⩽2 wt%. For the films, it is assumed that electron carriers were not generated by the substitution of Sn to Nb but by the oxygen vacancies induced by the distortion of the lattice.

Self-Polarization in PZT Films

Sol-gel derived lead zirconate titanate (PbZr 0.4 Ti 0.6 O 3 , PZT) films of thickness 2 w m were spin-coated on RuO 2 /SiO 2 /Si substrates. A RuO 2 top electrode was then deposited on the PZT film by reactive rfmagnetron sputtering. X-ray diffraction studies reveal that the c-axis of the crystallites in the PZT film lies preferably in the plane of the film before the deposition of the RuO 2 top electrode. However, after the deposition of the RuO 2 top electrode, the c-axis of a large number of crystallites becomes normal to the plane of the film, thus leading to a large initial polarization (self-polarization) in the PZT film. The room-temperature pyroelectric coefficient of the PZT film is about 230 w C/m 2 K, and a large internal field of 40 kV/cm is also observed. We suggest that the PZT film is self-polarized by the internal field which is induced by the high-energy ion bombardment on the film surface during the rf-sputtering process.

P‐42: Effects of Deposition Temperature on the Etched Feature of Thin Chromium Film and Their Application to Field Emitter Arrays (FEAs)

AbstractThe etched features of the thin Chromium (Cr) films deposited on SiO2‐Si substrate were investigated as a function of substrate temperature during rf‐sputtering deposition. In this work, the changes of both the grain structures and crystallographic orientations of sputtered Cr‐films as a function of substrate temperature were examined by Scanning Electron Microscopy (SEM) and X‐Ray Diffraction (XRD) measurement. In these measurements, we found that the tapering angle (θt) of thin Cr‐film after reactive ion etching depends on the deposition condition, especially, substrate temperature during rf‐sputtering process. Based on the obtained results, we fabricated the two kinds of Cr‐gated Mo‐tip field emitter arrays (FEAs): one is a FEAs with tapered gate electrode (tapering gated FEAs, θt ≤ 90°) and the other is a FEAs with tapering‐free gate electrode (non‐tapering gated FEAs, θt = 90°), compared the electron emission characteristics for this two kinds of FEAs.

Influence of process conditions on the ferroelectric characteristics of SrBi2Ta2O9 films prepared by rf magnetron sputtering

The effects of sputtering conditions on the SrBi2Ta2O9 films deposited via a single-target RF-sputtering process were investigated in this study. It was found that the composition of targets significantly affected the phases and the composition of the deposited films. When the target contained high bismuth content, SrBi2Ta2O9 and a secondary Bi2O3 phase were formed. When the bismuth content in the targets was insufficient, a pyrochlore phase was produced. SEM images revealed that the composition of the targets also affected the surface morphology of the obtained films. When the target-to-substrate distance was increased, bismuth oxide was formed, which resulted in an increase in the leakage current. By optimizing the deposition conditions, the ferroelectric properties of SrBi2Ta2O9 films were improved.

Bismuth- and aluminum-substituted Iron Garnet Film, Deposited by rf Magnetron-sputtering Using a Novel Target

Bismuth-substituted iron garnet ®lms are promising magneto-optical (MO) recording materials for the next generation because of their high corrosion resistance and large magneto-optical effects in the short visible wavelength [1]. They have been extensively prepared by rf magnetron-sputtering from ceramic targets of constituent oxides. Preparation of the ceramic target involves a complicated process: mixing raw oxide powders by ball milling, ®ring at 800 8C for several hours, grounding synthesized powders with a mill, pressing the powders into a disk of a certain diameter and thickness, and further sintering at around 1000 8C for several hours. The ceramic target for sputtering is 2± 4 inches in diameter and 3±4 mm in thickness [2±5]. Preparing a target with this diameter and thickness by this ceramic process uses a lot of materials and is time-consuming. Furthermore, for sputter-depositing, single-phase garnet ®lms, the composition of the target should be determined through times of adjustment, each of which is ®nished by a ceramic process. Accordingly, the target preparation is quite troublesome. In fact, even after hundreds of sputtering processes, the target is negligibly consumed. Therefore, from the experimental point of view, the ceramic target for sputtering is not economical. In this letter, a novel target for sputter-depositing bismuthand aluminumsubstituted iron garnet (BiAl:DyIG) ®lm is presented. Compared with the conventional ceramic target, the novel target is readily prepared with quite small amounts of raw materials. In the experiments, a metal-chelate, sol-gel process was used to prepare the powders for target. According to the nominal composition of Bi2:2Dy1:2 Fe3:9Al0:7O12, stochiometric amounts of Bi2O3 and Dy2O3 were dissolved in hot nitric acid. Measured amounts of Fe(NO3)3(1:6M) and Al(NO3)3(1M) solution were added and stirred to form a multicomponent nitrate solution, about one ®fth of which was reserved in a separate beaker. To the remaining solution, citric acid (CA) was added to chelate, the metallic cations in the ratio of one CA formula for each matallic cation present in the solution. To avoid precipitation during the subsequent heating process, the pH of the solution was kept under 2. The resulting solution was heated on a hot plate to remove the solvent (water). Along with evaporation of the solvent, the solution gradually turned into a gel. By heating strongly, the gel turned into a black foam and ®nally, after self-combustion with liberating vapors such as H2O, CO2, NOx, a brown powder precursor was obtained. After grounding, the powder precursor was ®red at 700 8C for 1 h to obtain ®ne powders with a nominal composition of Bi2:2Dy1:2Fe3:9Al0:7O12. On the other hand, the reserved multicomponent nitrate solution was heated at 80 8C for the gradual removal of water. Due to the hydrolysis of the metal cations (Bi3‡, Dy3‡, Fe3‡, Al3‡) present in the solution, a viscous sol could be formed when the volume of the solution was half reduced. Subsequently, 5 g of sol-gel-derived Bi2:2 Dy1:2Fe3:9Al0:7O12 powders and about 5 ml viscous sol were mixed to form a paste, which was manually coated on a stainless iron wafer having a diameter of 90 mm. This coating was then dried at 150 8C for 2 h. Finally, the dried coating ®rmly adhering to the iron wafer was used as a target for sputter-depositing garnet ®lms. In the rf-sputtering process, the base pressure was 1 3 10y4 Pa, the Ar gas pressure was 0.2 Pa, the substrate temperature was 400 8C, and the rf power was 100 W. After a 20-min pre-sputtering period, the shutter was opened for ®lm deposition on the substrates of quartz slides and silicon wafers for 1h . The as-sputtering amorphous ®lm was then ®red at 700 8C for 10 min. The ®lm thickness was 360 nm, measured by a DEKTAK thickness meter. The crystal phase present in the ®red ®lm was determined by powder X-ray diffraction (XRD) using Cu-Ka radiation. Fig. 1 shows the XRD pattern of the ®red ®lm. All the peaks are ascribed to garnet phase, which means that the novel target presented in this letter for sputter-depositing garnet ®lm is feasible in the experiment. Fig. 2 illustrates a typical scan electron microscopy (SEM) of the garnet ®lm, which reveals that the ®lm is smooth, dense, crack-free, and has appreciable ®ne grain. The MO rotation spectrum of the garent ®lm shown in Fig. 3 was measured by an advanced MO spectroscopy [6]. There is a maximum MO rotation around a wavelength of 540 nm, which is bene®cial to MO recording in the short visible wavelength. For

Formation of cubic boron nitride by the reactive sputter deposition of boron

Boron nitride films are synthesized by rf magnetron sputtering boron targets where the deposition parameters of gas pressure, flow and composition are varied along with substrate temperature and applied bias. The films are analyzed using Auger electron spectroscopy, transmission electron microscopy, nanoindentation, Raman spectroscopy and X-ray absorption spectroscopy. These techniques provide characterization of film composition, crystalline structure, hardness and chemical bonding, respectively. Reactive, rf-sputtering process parameters are established which lead to the growth of crystalline boron nitride (BN) phases. The deposition of stable and adherent boron nitride coatings consisting of the cubic phase requires 400°C substrate heating and the application of a 300-V negative bias.