Evaporation of a thin film coated on a substrate induced by a pulsed laser

The two-dimensional Laplace integral transform technique has been applied to get the spatial and temporal temperature distributions in both the molten layer thickness of a thin film coated on a substrate, the still solid part of the thin film of the target and the temperature distribution in the substrate. Also a formula for the time dependence of the evaporated part of the thin film of the target as well as the molten layer thickness of the thin film were obtained. Calculations of the obtained relations were carried out during the irradiation with a pulsed laser. The derivation has taken into account the temperature-dependent absorption coefficient of the irradiated surface and the chemical reaction in the vapor of the thin film. As an illustrative example, computations were carried out on an aluminum thin film coated on a glass substrate.     

Formation of disperse particles under high-power ion beam irradiation of metals with a coating

Metal systems based on aluminum and copper coated with nickel irradiated by a high-power ion beam of nanosecond duration have been studied by scanning electron microscopy and local X-ray microanalysis. Dispersed particles of micro- and nanosizes have been found on the surface target. Their composition and formation mechanism differ. It has been shown that microparticles were formed during mixing of film and target atoms and consisted of corresponding components. Nanoparticles were mainly composed of the coating material, and their formation was associated with the dispersion of the Ni film due to the presence of a thin oxide layer on the sample surface. The deposition of Ni ablated by a high-power ion beam can affect the formation of nanoparticles.     

新型的覆纳米粒子薄膜阴极的研究

采用直流磁控溅射的方法制备出Ir金属纳米粒子薄膜.利用扫描电子显微镜分析了纳米粒子的形态和分布以及不同工艺条件对粒子粒径及形貌的影响,表明纳米粒子的大小可通过调节溅射气体压强来控制.在25%孔度的W海绵基体内浸入6∶1∶2铝酸盐发射物质,然后在其表面沉积上厚度为200—500 nm的纳米粒子薄膜层,最后在H₂气中1200℃烧结,即制成了新型纳米粒子薄膜阴极.利用阴极发射微观均匀性测试仪对纳米粒子薄膜阴极和传统覆膜阴极的热电子发射的均匀性进行了对比研究.采用飞行时间质谱仪测试了真空本底、纳米粒子薄膜阴极、传统覆膜阴极等各种阴极蒸发物的成分,研究了阴极蒸发速率与阴极温度的关系,比较了不同阴极蒸发速率的大小.研究了Ba-W阴极覆上纳米粒子薄膜后的发射特性. 关键词： 纳米粒子薄膜 热阴极 发射均匀性 蒸发     

Characterizing the coating and size-resolved oxidative stability of carbon-coated aluminum nanoparticles by single-particle mass-spectrometry

Aluminum nanoparticles are of significant interest in enhancing the rate of energy release from propellants. One of the major impediments to their use is that bare aluminum is highly reactive, while oxide coated aluminum significantly decreases overall performance. We investigate creating aluminum nanoparticles with a thin carbon coating using either a laser induced plasma or a DC plasma-arc. The carbon coating was created by injecting ethylene (C₂H₄) directly downstream of the plasma. The elemental composition of the coated aluminum nanoparticles was measured in real time with a recently developed quantitative single particle mass spectrometer (SPMS). We found that the aluminum nanoparticles were coated with a carbon layer of thickness around 1–3 nm.The thermal and oxidative stability of these particles was determined by passing the aerosols through a heated flow reactor in a carrier flow of either air or argon, and measuring the aluminum, carbon and oxygen content in the particles with the single particle mass spectrometer. We found that below 700°C the coating was stable, but that the coating oxidized above ∼ ∼800°C. In contrast the carbon coating was thermally stable above ∼ ∼900°C. These results indicate that a carbon coating may be a suitable passivating agent.     

Optical and structural analysis of plasma-treated and annealed Al–Sb bilayer thin films

Aluminum–antimony (Al–Sb) seems to be a promising semiconducting material for high-temperature application especially for transistors and P–N junction diodes and is a highly coefficient solar material. No attempt has been made to study the bilayer diffusion properties of Al–Sb thin film by plasma exposure. In this paper, the characterization of plasma-exposed Al–Sb bilayer thin films is presented. Thin films were coated by thermal vapor coating technique, and after coating, the sample was annealed and exposed with plasma. Results were obtained from optical band gap data and X-ray diffraction for treated and untreated Al–Sb thin films, and these results were compared with annealed Al–Sb thin films.     

Pulsed laser deposition (PLD) — an advanced state for technical applications

The conventional thin-film deposition equipment of pulsed laser deposition (PLD) has been modified for the preparation of individual thin solid films and nanometer-layer stacks of uniform thickness across 100-mm substrates. The planar target configuration was replaced by a cylindrical one and the target motion regime has been improved to provide precise spatial control of the plasma plume orientation. During thin-film deposition, substrate translation is preferred instead of the usual rotation technique. With this arrangement the emission characteristic of the plasma source can be computer controlled and the desired coating can be tailored via a stepper-motor-driven manipulator for the desired layer thickness profile across an extended substrate. Thus, for example, a homogeneous film thickness is obtained even for lower target/substrate distances, and an appropriate deposition rate can be maintained. In a second version, this cylinder geometry principle of plasma plume control by target surface morphology is extended to a spatial solution. The hemispherical target surface becomes the basic element for inside-wall coating of tubes or even of more complex hollow bodies. First applications of the equipment are explained and compared with typical results of the conventional technique.     

Glassy carbon - A promising substrate material for pulsed laser deposition of thin Li1+xMn2O4−δ electrodes

The spinel LiMn₂O₄ is a promising candidate for future battery applications. If used as a positive electrode in a battery, the charging capacity of such a battery element is limited by the formation of a solid electrolyte interphase like layer between the electrolyte and the spinel. To study the electrolyte-electrode interaction during electrochemical cycling, spinel thin films are deposited as model electrodes on glassy carbon substrates by pulsed laser ablation. The obtained polycrystalline oxide thin films show a well defined surface morphology and are electrochemical active. Adhesion of these thin films on glassy carbon is in general poor, but can be improved considerably by a surface pretreatment or adding a thin metallic coating to the substrate prior deposition. The best adhesion is obtained for films deposited on argon plasma pretreated as well as Pt coated glassy carbon substrates. During the electrochemical characterization of Li_1.06Mn₂O_3.8 thin film electrodes, no additional reactions of the substrate are observed independent of the used electrolyte. The best cycle stability is achieved for films on Pt coated glassy carbon substrates.     

Chemical Surface Coating: Synthesis and Characterization of a Silicon Oxynitride Coated Silica Sel

Mesoporous silica gel has been coated with a thin silicon oxynitridefilm via chemical surface coating. In the first part of the synthesis, achemically bound preceramic polysilazane coating is formed layer by layer onthe pore walls at low temperature, using SiCl₄ andNH₃ as reagents. In the second part of the synthesis, thepolysilazane coated silica gel is pyrolysed, yielding a chemically bound,thin oxynitride coating.During the synthesis, the evolution of the chemical and morphologicalcomposition has been investigated with several elemental and spectroscopicanalysis techniques as well as with nitrogen porosimetry.     

Formation process of a strong water-repellent alumina surface by the sol-gel method

A novel strong water-repellent alumina thin film is fabricated by chemically adsorbing stearic acid (STA) layer onto the porous and roughened aluminum film coated with polyethyleneimine (PEI). The formation process and the structure of the strong water-repellent alumina film are investigated by means of contact angle measurement and atomic force microscope (AFM). Results show that the water contact angles for the alumina films increase with the increase of the immersion time in the boiling water, and meanwhile, the roughness of the alumina films increases with the dissolution of the boehmite in the boiling water. Finally, the strong water-repellent film with a high water contact angle of 139.1° is obtained when the alumina films have distinct roughened morphology with some papillary peaks and porous structure. Moreover, both the roughened structure and the hydrophobic materials of the STA endow the alumina films with the strong water-repellence.     

Effect of aluminum on the corrosion behavior of NiTiAl thin films

An electrochemical study for the evaluation of corrosion behavior using potentiodynamic and Tafel techniques was conducted in 0.9% NaCl solution on Ni-Ti and Ni-Ti-Al shape memory thin films. Atomic force microscopy (AFM) and electron probe microanalyzer (EPMA) were applied to observe morphology of the surface film and elemental distribution, respectively, prior to and after immersion in 0.9% NaCl solution. The concentration of dissolved Ni from Ni-Ti-Al thin films in the electrolyte, measured with inductively coupled plasma atomic emission spectrometer (ICP-AES), was significantly lower after immersion for 7 days, as compared to Ni-Ti thin film. This demonstrated that a better corrosion resistance and lower corrosion current density were revealed for Ni-Ti-Al thin films than that for Ni-Ti thin film. The improved corrosion performance of Ni-Ti-Al thin films would be potentially beneficial for related biological applications. This was attributed to the introduction of aluminum after exposure to an aqueous environment.     

On the blue emission of a novel solution-processed stilbenoid dendrimer thin film for OLED displays

A novel blue fluorescent first generation stilbenoid dendrimer built on the 1,3,5-benzene core and endowed with a periphery of hexyloxy branches has been synthesized and is proposed as an active layer for organic light-emitting diodes processed by spin coating. In this work, we have obtained homogeneous thin films with blue emission (2.8 eV) by spin coating instead of the usual evaporation method used for low-weight molecular materials. The absorption and emission spectra of the films are analyzed and compared to that of the molecule. The obtained results show the dependence of the absorption and emission properties on the morphology and the dendrimer aggregation in the film. The effect of inter-dendrimer interactions leads to a broadening of the absorption bands and to a reduction of the threshold as the aggregation increases. The most efficient solid-state emission is for the films obtained from chloroform as solvent in the precursor solution.     

Photoluminescence and its time evolution of AlN thin films

We report the room temperature photoluminescence measurements of AlN thin films stimulated by above-band-gap pulsed light excitation. Two AlN thin films with different composition and structure were studied. One AlN film, prepared by pulsed laser deposition from sintered aluminum nitride ceramic target, contains oxide impurities. The other one, prepared by plasma assisted reactive pulsed laser deposition from pure aluminum metal target, is composed of pure AlN compound. Upon the irradiation of the samples by 193 nm excimer laser pulses, both the as-grown AlN thin films luminesce in the ultraviolet and the green regions, peaked at 440 and 400 nm, respectively. We also examined the time evolution of the luminescence and found that the entire broad luminescence band decays non-exponentially at approximately the same rate.     

声表面波生物传感器质量灵敏度的理论与实验验证

针对声表面波传感器在生物检测中的性能评价与优化,提出一种快捷验证适用于生物传感器的声表面波器件质量负载灵敏度的实时检测方法.首先基于二维近似假设和周期性边界条件,建立了以石英为压电基底材料、SiO2为波导层的Love波传感器的三维有限元分析模型,从理论上验证了波导层对Love波传感器灵敏度的影响.在实验上,通过MEMS...     

Coupling of surface plasma oscillations in thin periodically corrugated silver films

We investigated surface plasma oscillations (SPO's) in a layer system of thin dielectric films with a periodically corrugated surface coated by a silver film. SPO's at both surfaces of the silver film could be excited by light. We observed coupling of the two SPO's through the thin film via the periodicity of the surface and as a consequence a discontinuity in the dispersion relations of the SPO.     

Study on the composition and phase change of BaO/Hf/Mo under high temperature

Hafnium films were deposited onto the molybdenum grids by radio-frequency magnetron sputtering from an Hf target in argon gas. Emission current of Mo grids coated with and without Hf film during the lifetime testing, which were contaminated by active electron-emission substances (i.e. Ba or BaO) from the cathode, were measured using an analogous-diode method. The results show that emission current from the Mo grid coated with Hf film is much less than that from the Mo grid without Hf film. The BaO layer was deposited on Hf/Mo substrates by chemical method in order to simulate the working conditions of the grids contaminated by electron-emission substances from the cathode. The suppression mechanism of electron emission from the Mo grid coated with Hf film is discussed according to the experimental results and the calculation of the reaction free energy.     

Induced growth of high quality ZnO thin filmsby crystallized amorphous ZnO

This paper reports the induced growth of high quality ZnO thin film by crystallized amorphous ZnO. Firstly amorphous ZnO was prepared by solid-state pyrolytic reaction, then by taking crystallized amorphous ZnO as seeds (buffer layer), ZnO thin films have been grown in diethyene glycol solution of zinc acetate at 80℃. X-ray Diffraction curve indicates that the films were preferentially oriented [001] out-of-plane direction of the ZnO. Atomic force microscopy and scanning electron microscopy were used to evaluate the surface morphology of the ZnO thin film. Photoluminescence spectrum exhibits a strong ultraviolet emission while the visible emission is very weak. The results indicate that high quality ZnO thin film was obtained.     

Highly confined hybrid spoof surface plasmons in ultrathin metal-dielectric heterostructures

Highly confined "spoof" surface plasmons (SSPs) are theoretically predicted to exist in a perforated metal film coated with a thin dielectric layer. Strong modes confinement results from the additional waveguiding by the layer. Spectral characteristics, field distribution, and lifetime of these SSPs are tunable by the holes' size and shape. SSPs exist both above and below the light line, offering two classes of applications: "perfect" far-field absorption and efficient emission into guided modes. It is experimentally shown that these plasmonlike modes can turn thin, weakly absorbing semiconductor films into perfect absorbers.     

Hard protective waterproof coating for high-power laser optical elements

We developed a new method for making a waterproof coating by photooxidation of silicone oil. The silicone oil was spin coated onto the surfaces of optical elements, i.e., a plastic lens, a laser mirror, and a nonlinear optical crystal, and then irradiated with a xenon excimer lamp in air, which transformed the organic silicone oil into an amorphous glass film. This technique has enabled an optical thin film to transmit ultraviolet rays of wavelengths below 200 nm and to exhibit the characteristics of homogeneity, high density, and resistance to environmental effects and to corrosion by water, and a Mohs scale value of 5.     

Photoluminescence blue shift of indium phosphide nanowire networks with aluminum oxide coating

This paper describes our finding that optical properties of semiconductor nanowires were modified by depositing a thin layer of metal oxide. Indium phosphide nanowires were grown by metal organic chemical vapor deposition on silicon substrates with gold catalyst resulting in three‐dimensional nanowire networks, and optical properties were obtained from the collective nanowire networks. The networks were coated with an aluminum oxide thin film deposited by plasma‐enhanced atomic layer deposition. We studied the dependence of the peak wavelength of photoluminescence spectra on the thickness of the oxide coatings. A continuous blue shift in photoluminescence spectra was observed when the thickness of the oxide coating was increased. The observed blue shift is attributed to the Burstein–Moss effect due to increased carrier concentration in the nanowire cores caused by repulsion from intrinsic negative fixed charges located at the inner oxide surface. Samples were further characterized by scanning electron microscopy, Raman spectroscopy, transmission electron microscopy, and selective area diffractometry to better understand the physical mechanisms for the blue shift. (© 2014 WILEY‐VCH Verlag GmbH & Co. KGaA, Weinheim)     

Comparison of ZnO thin films grown on a polycrystalline 3C-SiC buffer layer by RF magnetron sputtering and a sol-gel method

Zinc oxide (ZnO) thin films were deposited on a polycrystalline (poly) 3C-SiC buffer layer using RF magnetron sputtering and a sol-gel method. The post-deposition annealing was performed on ZnO thin films prepared using both methods. The formation of ZnO piezoelectric thin films with less residual stress was due to a close lattice mismatch of the ZnO and SiC layers as obtained by the sputtering method. Nanocrystalline, porous ZnO film prepared using the sol-gel method showed strong ultraviolet UV emission at a wavelength of 380 nm. The 3C-SiC buffer layer improved the optical and piezoelectric properties of the ZnO film produced by the two deposition methods. Moreover, the different structures of the ZnO films on the 3C-SiC intermediate layer caused by the different deposition techniques were also considered and discussed.