NH+4，F-对萤石浮选的影响机理及红外光谱分析

萤石浮选过程中矿浆中的NH+₄,F-对萤石的可浮性有重要影响,而目前关于难免离子对浮选影响的研究主要集中在稳定的阳离子对浮选的活化或抑制作用机理,而关于不稳定阳离子（NH+₄）、阴离子（F-）影响油酸钠吸附萤石作用机制的研究较少。因此借助于红外光谱分析,结合纯矿物浮选、Zeta电位和溶液化学计算等手段,研究难免离子（NH+₄,F-）对油酸钠浮选萤石的作用机理。实验结果表明,在酸性条件下,NH+₄对萤石有较强的活化作用,提高了萤石的回收率, 在pH值为6时,不同NH+₄浓度下,萤石的回收率均提高到94%左右,而在碱性条件下,NH+₄对萤石的浮选的有一定的抑制作用,且随着pH值增加,抑制作用增强,回收率逐渐下降;但F-对萤石浮选有一定的抑制作用,且在pH值为6时,不同F-浓度的抑制作用均明显增强,导致萤石回收率降低;而在碱性条件下,F-对萤石的可浮性影响不大。其作用机理为阳离子（NH+₄）与萤石表面解离到溶液中的F-生成NH₄F,在酸性条件下提高了萤石表面的正电性,增强萤石表面与油酸的一聚物、二聚物和分子-离子缔合物的吸附作用,而在碱性条件下NH+₄的水解生成NH₃·H₂O,正电性降低,导致油酸钠在萤石表面的吸附作用减弱;F-抑制萤石表面F-的解离,从而抑制了油酸根在萤石表面的化学吸附。红外分析结果表明,油酸钠在萤石表面发生了化学吸附;NH+₄的加入,在酸性条件下对萤石有很强的活化作用,-CH₃,-CH₂-和-COO-的特征峰峰位红移,峰强度加强,显现出较强的化学吸附作用;而在碱性条件下,仅出现了-CH₂-的特征峰的峰位红移,且特征峰强度减弱,说明NH+₄在弱碱条件在萤石表面的化学吸附较弱,起抑制作用;当加入F-后只出现了-CH₃的反对称伸缩振动峰,峰位并未发生偏移,故F-加入后油酸钠在萤石表面并未发生任何基团的化学吸附,从而抑制了萤石的可浮性。     

Preparation of alumina/silica core-shell abrasives and their CMP behavior

Abrasive is one of key influencing factors on the surface quality during the chemical mechanic polishing (CMP). α-Alumina particles, as a kind of widely used abrasive in CMP slurries, often cause to surface defects because of its high hardness. In the present paper, a series of novel alumina/silica core-shell abrasives in slurries were described. The CMP performances of the alumina/silica core-shell abrasives on hard disk substrate were investigated by using a SPEEDFAM-16B-4M CMP equipment. Experimental results indicate that the CMP performances are strong dependent on the coated SiO₂ content of the alumina/silica composite abrasives. Slurries containing the alumina/silica composite abrasives exhibited lower surface roughness and waviness as well as lower topographical variations and less scratch than that containing pure alumina abrasive under the same testing conditions.     

Evolution of morphologic properties on the preparation of Ir/Al2O3 catalysts with high metallic contents

Ir/Al₂O₃ catalysts with high metallic contents are applied on satellite thruster to decompose hydrazine. The present work has as principal aim the study of the morphologic evolution of Ir/Al₂O₃ catalysts with metallic contents from 12 to 30 wt.%. The catalysts were prepared through consecutive impregnations from the H₂IrCl₆ precursor, using three different types of aluminas. The specific surface area, volume and distribution of pore size, specific metallic area and metallic particles average diameter, as well as the mechanical resistance were determined. Results show that the Ir addition leads to a decrease of the specific surface area and the pores volumes, while increases the mechanical resistance. Values for average diameter of metallic particles are comprised between 1.4 and 2.4 nm when the metallic content increases from 12 to 30 wt.%. Catalysts containing 30 wt.% of Ir presents specific metallic areas around 30 m²/g, although pores volumes and distributions of pore size were considerably different for the three supports. Their metallic particles dispersion and size values are very close to those of a commercial catalyst Shell 405, even though the preparation methods were different. These results show that there is a strong interaction between the alumina and the iridium precursor.     

Interaction of copper and NO2: Effect of joint presence of SO2, relative humidity and temperature

This paper reports laboratory tests involving the dry deposition on copper surfaces of NO₂, alone and in combination with SO₂, at different concentrations (200 and 800 μg m⁻³), temperatures (15, 25 and 35 °C) and relative humidities (50%, 70% and 90%). Gravimetric results and characterisation of the corrosion products by optical microscopy, scanning electron microscopy (SEM/EDX), grazing incidence X-ray diffraction (GIXD) and X-ray photoelectron spectroscopy (XPS) show that the corrosive effect of NO₂ acting alone depends greatly on the RH. At 90% RH copper behaves in the same way as in unpolluted atmospheres, while at lower RH localised attack is detected. Analysis reveals the presence of basic copper nitrate (gerhardtite, Cu₂(OH)₃NO₃). However, in SO₂-polluted atmospheres no differential behaviour with RH or temperature is observed. In these atmospheres copper corrosion is similar to that obtained in unpolluted or in NO₂-polluted atmospheres at high RH, although GIXD detects basic copper sulphate (posnjakite, Cu₄(OH)₆SO₄·2H₂O). In the case of mixed atmospheres (SO₂+NO₂) a significant accelerating effect is observed when [NO₂]>[SO₂]. Otherwise an inhibitive effect is detected. At high RH in the presence of SO₂, NO₂ favours SO₂ oxidation and finally sulphuric acid formation, which attacks the cuprite layer. S-containing compounds, especially basic copper sulphate, are easily detected by GIXD and XPS in the outermost corrosion product layer. However, at low RH, NO₂ reacts preferentially with adsorbed water to produce nitrous and nitric acids that attack the cuprite layer. In this case, an outer corrosion product layer containing copper nitrite (soluble) and basic copper nitrate is formed over an intermediate layer that contains significant amounts of basic copper sulphate from the previous interaction of sulphuric acid and cuprite.     

Tetrakis(diethylamido) titanium (TDEAT) interactions with SiO2 and Cu substrates

X-ray photoelectron spectroscopy (XPS) is used to characterize the chemical interactions of tetrakis(diethylamido) titanium (TDEAT) with SiO₂ and Cu surfaces under ultrahigh vacuum (UHV) conditions. XPS studies show that TDEAT dissociatively chemisorbs on SiO₂ at room temperature or above, resulting in Ti---N bond scission, and Ti---O bond formation. No Ti carbide or Si carbide formation is observed. In the presence of co-adsorbed NH₃, Ti---N bond formation is enhanced and is stable at temperature up to 900 K in UHV. Continuous exposures of TDEAT on SiO₂ at 500 K produce both Ti oxides and nitride formation. The presence of an overpressure of NH₃ enhances Ti nitride formation. In contrast, TDEAT physisorbed on Cu at 120 K and annealed to 500 K results in desorption of Ti-containing species from the surface. Successive exposures of TDEAT on Cu at 500 K yield a Ti-alkyl reaction product. The presence of NH₃ does not significantly alter TDEAT interaction with Cu.     

Corrosion resistance study of Fe–Mn–Al–C alloys using immersion and potentiostatic tests

The interaction of the Fe–32.7Mn–6.59Al–1.26Si–0.25C (wt.%) and Fe–32.3Mn–8.54Al–1.31Si–0.54C (wt.%) alloys with the environment was evaluated. Potentiostatic and total immersion tests, planned and analyzed by the statistic model of fixed effects were used for the evaluation of corrosion in gasoline, alcohol fuel, lactic acid solution (40 wt.%), sodium chloride solution (3 wt.%), and boiler water. Potentiostatic tests in 1N H₂SO₄ medium presented that the alloys showed a tendency towards passivation. The role that aluminum and silicon play in alloy corrosion mechanism was discussed.     

Tensile properties of structural I clathrate hydrates: Role of guest–host hydrogen bonding ability

Clathrate hydrates (CHs) are one of the most promising molecular structures in applications of gas capture and storage, and gas separations. Fundamental knowledge of mechanical characteristics of CHs is of crucial importance for assessing gas storage and separations at cold conditions, as well as understanding their stability and formation mechanisms. Here, the tensile mechanical properties of structural I CHs encapsulating a variety of guest species (CH₄, NH₃, H₂S, CH₂O, CH₃OH, and CH₃SH) that have different abilities to form hydrogen (H-) bonds with water molecule are explored by classical molecular dynamics (MD) simulations. All investigated CHs are structurally stable clathrate structures. Basic mechanical properties of CHs including tensile limit and Young’s modulus are dominated by the H-bonding ability of host–guest molecules and the guest molecular polarity. CHs containing small CH₄, CH₂O and H₂S guest molecules that possess weak H-bonding ability are mechanically robust clathrate structures and mechanically destabilized via brittle failure on the (1 0 1) plane. However, those entrapping CH₃SH, CH₃OH, and NH₃ that have strong H-bonding ability are mechanically weak molecular structures and mechanically destabilized through ductile failure as a result of gradual global dissociation of clathrate cages.     

Standing waves, clustering, and phase waves in 1D simulations of kinetic relaxation oscillations in NO+NH3 on Pt(1 0 0) coupled by diffusion

The Lombardo–Imbihl–Fink (LFI) ODE model of the NO+NH₃ reaction on a Pt(1 0 0) surface shows stable relaxation oscillations with very sharp transitions for temperatures T between 404 and 433 K. Here we study numerically the effect of linear diffusive coupling of these oscillators in one spatial dimension. Depending on the parameters and initial conditions we find a rich variety of spatio-temporal patterns which we group into four main regimes: bulk oscillations (BOs), standing waves (SW), phase clusters (PC), and phase waves (PW). Two key ingredients for SW and PC are identified, namely the relaxation type of the ODE oscillations and a nonlocal (and nonglobal) coupling due to relatively fast diffusion of the kinetically slaved variables NH₃ and H. In particular, the latter replaces the global coupling through the gas phase used to obtain SW and PC in models of related surface reactions. The PW exist only under the assumption of (relatively) slow diffusion of NH₃ and H.     

Preparation of high purity spherical γ-alumina using a reduction-magnetic separation process

A purified alumina hydrosol has been prepared by removing metal impurities using a new reduction-magnetic separation process. The amount of iron in the alumina hydrosol was reduced by over 78% from 0.0094% to 0.0020%. As a result of co-crystallization, the copper content was simultaneously reduced from 0.0003% to 0.0001%. Spherical γ-alumina granules were prepared by the oil-drop method using the purified alumina hydrosol as starting material. The γ-alumina granules had a bulk density of about 0.50 g cm⁻³, crush strength of around 90N per granule, specific surface area of about 200 m² g⁻¹ and pore volume of about 0.75 cm³ g⁻¹. The purification process employed during the preparation of the alumina hydrosol had no effect on the physical properties, pore structure and crystal structure of the final spherical alumina granules.     

Novel multi-walled nanotubes-supported and alkali-promoted Ru catalysts for ammonia synthesis under atmospheric pressure

A novel ammonia synthesis catalyst, alkali-promoted ruthenium supported on multi-walled nanotubes (MWNT), has been developed. Various alkali-promoters and carbon-based supports were compared. The effects of the contents of Ru and K, the treatment of MWNT, and the reaction temperature on ammonia synthesis activity were investigated. It was found that, as a support, the MWNT is much better than other carbon-based supports. The yield of NH₃ was 47.423 ml NH₃/h g-cat at 693 K, at atmospheric pressure and N₂/3H₂ flow-rate of 1800 ml/h for the catalyst with K/Ru/MWNT = 4/4/100 (w/w).     

Real-time monitoring of SiO2/Si(1 1 1) interlayer etching by Brewster-angle reflectometry

A transitory etching regime after SiO₂ dissolution and before bulk Si(1 1 1) etching in neutral NH₄F solutions was monitored by in situ Brewster-angle reflectometry (BAR). An observed intermediate increase of the BAR reflectance signal is attributed to a fast dissolution of a stressed/strained interlayer beneath the SiO₂/Si(1 1 1) interface. Similar effects were observed on thin thermal oxides (18.2 nm), grown on float zone silicon, as well as on ultra-thin native oxides (1.2 nm) on Czochralsky silicon. Native oxide covered samples showed an increased surface roughness in the course of interlayer dissolution while the surface is progressively covered with compounds of fluorinated silicon. The etch rate, determined by atomic force microscopy (AFM) and compared to the etch rate of bulk silicon, is increased by a factor of four. In the limit of extended etching, the known low etch rates for silicon in 40% NH₄F are observed. Structural and chemical properties of the interfacial layer were analyzed by synchrotron radiation photoelectron spectroscopy (SRPES) which confirmed the presence of Si^3+/4+ valence states throughout the interlayer and by near open-circuit potential (N-OCP) dark current measurements. As a result, oxide etch rates in NH₄F in the pH-range 7–8 as well as the silicon interlayer depth can be assessed by in situ BAR.     

Hydrolysis of microporous polyamide-6 membranes as substrate for in situ synthesis of oligonucleotides

This article provides a novel method of preparing substrate for in situ synthesis of oligonucleotide by hydrolyzing microporous polyamide-6 membranes in a 0.01 mol/l/NaOH/(H₂O–CH₃OH) mixture medium with refluxing about 36 h. Attenuated total reflectance Fourier transform infrared spectroscopy (ATR-FTIR) demonstrated the emergence of amines (NH₂) on the surface. Optimum hydrolyzing conditions were determined through the ultra-violet (UV) spectra. A pH value of 12 and a hydrolysis time of 36 h are the preferred conditions for the modification. The treated membrane can be applied to in situ synthesis of oligonucleotide and, for example, the oligonucleotide probes of 5^′-AAC CAC CAA ACA CAC-3^′ were successfully synthesized on the hydrolyzed membrane. The single step coupling efficiency determined by ultraviolet (UV) spectra is above 98%.     

The influence of preparative parameters on the adhesion of alumina washcoats deposited on metallic supports

Well-adhered alumina washcoats on FeCrAl metallic supports were prepared using boehmite sols and alumina slurries. The microstructure and the surface performance of the washcoat/support were investigated by SEM, XRD, and ultrasonic vibration. The effects of the main preparative parameters on the coating adherence were studied. The optimal coating conditions are presented as follows: pre-oxidation of the metallic supports was performed at 900 °C for 10 h, the sol layer loadings were 2.0-6.6 wt.%, and the slurry layer loadings were less than 25.3 wt.%. The sol layer drying was performed at 30 °C for 1 h and that for the slurry layer the drying was performed at 120 °C for 2 h, and the coating calcining was performed at 900 °C for 2 h. The SEM photographs of coated samples show that alumina washcoats were well deposited on the metallic supports.     

Growth and characterization of model oxide catalysts

Oxide catalysts are frequently used to convert toxic species to environmentally benign molecules, and to prevent the formation of toxic species in the first place. In this paper, growth and characterization of model oxide systems employed in both approaches is discussed. An example of the former approach is the selective catalytic reduction (SCR) of NO emitted from power plants by NH₃, which employs tungsten and vanadium oxides supported on the anatase polymorph of TiO₂. To model SCR catalysts, epitaxial titanium, vanadium and tungsten oxide films were grown using molecular beam epitaxy and magnetron sputtering. Two different anatase orientations were grown on LaAlO₃ substrates and their interactions with vanadia were characterized. On LaAlO₃ (0 0 1), anatase exposed a (4 × 1) reconstructed (0 0 1) surface. Vanadia lifted the reconstruction and at 1 ML a (1 × 1) surface with mostly V⁵⁺ was observed. Continued V₂O₅ growth led to loss of order, but at high temperatures epitaxial VO₂ could be grown; vanadia behaved similarly on anatase films on LaAlO₃ (1 1 0). Results suggested that the monolayer is pseudomorphic with O adsorption oxidizing the surface V to 5+, since the anatase structure cannot accommodate more bulk oxygen, only a monolayer can be pseudomorphic and have only V⁵⁺. Thus the vanadia monolayer has unique structural and chemical properties that can help explain why vanadia monolayers on TiO₂ are much more active than bulk V₂O₅. For WO₃, a series of added row reconstructions were observed as the epitaxial films were reduced. The effect of these structures on surface chemistry was characterized by studying 1-propanol adsorption. The results indicated that the structure of the WO₃ surface did not alter its catalytic function but had a strong effect on reaction kinetics. As an example of a system where catalysts prevent the formation of toxic species, the reactivity of oxidized Pd surfaces used in CH₄ catalytic combustion were studied. An ordered PdO-like monolayer was found to be less reactive towards CO than adsorbed O on Pd. On the other hand, the PdO layer favored a lower activation energy C₃H₆ oxidation pathway. The results indicated that Pd oxidation reduces the sticking coefficient of reactive species but once molecules adsorb, the oxide surface can reduce the activation energy for subsequent reaction.     

Formation of high quality gallium nitride thin films on Ga-diffused Si(1 1 1) substrate

High quality gallium nitride thin films have been successfully grown on the Ga-diffused Si(1 1 1) substrates through ammoniating Ga₂O₃ thin films deposited by r.f. magnetron sputtering. X-ray diffraction (XRD), X-ray photoelectron spectroscopy (XPS), transmission electron microscopy (TEM), atomic force microscope (AFM) and photoluminescence (PL) were used to characterize the synthesized samples. The analyses reveal that the formed films are high quality polycrystalline hexagonal gallium nitride. The as-formed GaN films show a flat surface topography with RMS roughness varied from 29 to 48 Å. The strong near-band-edge-emission peak around 368 nm was observed at room temperature. This is a novel method to fabricate GaN thin films based on the direct reaction between Ga₂O₃ and NH₃ on the Ga-diffused Si(1 1 1) substrates.     

Formation of luminescent (NH4)2SiF6 phase from vapour etching-based porous silicon

In this paper we describe the formation of a luminescent (NH₄)₂SiF₆ via porous silicon (PS) obtained from HNO₃/HF vapour etching (VE) silicon (Si) substrates. It was found that at specific conditions, PS transforms in a luminescent thick white powder (WP) layer. Scanning electron microscopy (SEM) revealed that the WP has a coral-like structure. It was also found that PS persists as an intermediate layer between the Si substrate and the WP, and seems to be the seed that transforms into the WP. SEM microanalysis show that the WP is essentially composed of silicon (Si), nitrogen (N) and fluorine (F). Fourier transform infrared (FTIR) spectroscopy investigations show that this WP contains SiF₆²⁻ and NH₄⁺ ions and N---H chemical bonds. X-ray diffraction (XRD) patterns of the WP confirm that a (NH₄)₂SiF₆ cubic phase is concerned. SEM microanalyses show an excess of Si in the WP matrix. FTIR spectroscopy and XRD analysis reveal the presence of crystalline Si particles and SiO_x, both originating from the excess of Si. The (NH₄)₂SiF₆ WP phase emits an intense photoluminescence (PL) band, shifted towards higher energies as compared to the starting PS layer. The possible origin and mechanism of the luminescence emission was discussed taking into account the ability of small SiO_x-surrounded Si particles to emit PL at rather high energy. The wide range variation of the thickness of the (NH₄)₂SiF₆ WP may be easily used for the grooving of Si wafers.     

固相萃取-电感耦合等离子体质谱法测定地表高盐水体中的痕量稀土元素

基于电感耦合等离子体质谱（ICP-MS）建立测定地表高盐水体中痕量稀土元素的分析方法,提出UV/H₂O₂去除地表水体中有机物的新策略。地表水体中的溶解态稀土浓度极低,质量浓度在ng·L-1数量级,分析测试非常困难。当水体中总溶解性固体超过1 g·L-1时,样品直接测试会造成严重的质谱干扰,同时可能会导致雾化器、截取锥和样品锥阻塞。因此,测试高盐水体中的稀土元素需要先去除水体中的盐类。为提高测试的准确度,样品测试前通常需要对水体进行预富集以增加待测物质量浓度。但是,内陆地表水体中有机物浓度较高,在进行预富集的过程中有机物和稀土元素发生络合作用,使得溶解态稀土在富集时发生分异,对预富集工作也是一项挑战。首先在样品中加入H₂O₂,将样品放入紫外消解系统中氧化去除水体中的有机物,消解后水体中有机碳的浓度可降低至0.5 mg·L-1。然后采用NobiasPA1固相树脂对样品进行预富集,步骤如下：首先使用流速为2.2 mL·min-1的硝酸,超纯水和醋酸铵缓冲液依次分别清洗预富集系统,去除预富集系统中可能残留的稀土元素;然后用流速为2.0 mL·min-1的醋酸铵缓冲液、样品和醋酸铵缓冲液依次分别通过固相萃取柱,富集样品中的稀土元素并去除吸附在树脂柱上的盐类;最后使用流速为0.7 mL·min-1的HNO₃溶液淋洗树脂柱并收集样品。ICP-MS测试样品时,选择115In为内标校正基体效应。研究结果表明在pH 4.6±0.1的情况下,各稀土元素的检出限和空白值分别在0.34～22.0和0.34～12.9 ng·L-1之间;稀土元素检出的相对标准偏差（n=5）<5%;稀土标准溶液的加标回收率在97%～101%之间。将该方法用于渤海海水、海河河口水体和西藏雅根错水体,加入Tm作为内标,样品的加标回收率在98%～101%, 相对标准偏差（n=3）<5%。这说明该方法适用于地表高盐水体中溶解态稀土元素的定量分析。     

The effect of hydrogen on copper nitride thin films deposited by magnetron sputtering

Copper nitride thin films were deposited on Si (1 0 0) wafers by reactive magnetron sputtering at various H₂/N₂ ratios. X-ray diffraction measurements show that the films are composed of Cu₃N crystallites with anti-ReO₃ structure and exhibit preferred orientation of [1 0 0] direction. Although the relative composition of the films has obviously changes with the H₂/N₂ ratios, the orientations of the films keep almost no changes. However, the grain size, lattice parameter and composition of the films are strongly dependent on the H₂/N₂ ratios. The copper nitride films prepared at 10% H₂/N₂ ratios show poor stability and large weight gain compared to the copper nitride films prepared at 0% H₂/N₂ ratios.     

The chloroform / TBP / aqueous nitric acid interfacial system: a molecular dynamics investigation

We report MD studies on a chloroform / nitric acid water interface, either neat, or saturated by TBP molecules. Two extreme models are compared, where the acid is either neutral HNO₃ or dissociated to NO₃⁻ and H₃O⁺. The latter species are found to be “repelled” by the neat interface, while the neutral HNO₃ molecules are surface active. When the neat interface is saturated by TBP molecules, the latter form highly disordered arrangements instead of a regular monolayer, and water is dragged to the organic phase as 1:1, 1:2 and 2:2 hydrates of TBP. Simulations with the neutral HNO₃ model lead to extraction of acid to the organic phase, hydrogen bonded to the phosphoryl oxygen of TBP, forming HNO₃:TBP adducts of 1:1 and 2:1 types. Simulations with the ionic model lead to H₃O⁺:TBP adducts of 1:1, 1:2 and 1:3 types in the organic phase and significant mixing of the chloroform, TBP and water liquids in the interfacial region.     

(NH4)2SO4，NH4NO3和(NH4)2SO4/NH4NO3混合气溶胶吸湿质量增长因子的快速测量方法

气溶胶颗粒的吸湿性决定了其尺寸、浓度、化学组成以及相态,从而显著影响着全球气候、大气异相化学以及人类健康。运用在线、原位、连续扫描衰减全反射傅里叶变换红外光谱（ATR-FTIR）技术, 结合线性湿度（RH）控制系统,实现了RH连续变化条件下气溶胶FTIR-ATR光谱的快速测量。根据水弯曲振动谱带（~1 640 cm-1）峰面积随RH的变化,得到了(NH₄)₂SO₄,NH₄NO₃和(NH₄)₂SO₄/NH₄NO₃混合气溶胶的质量增长因子（MGFs）、潮解点（DRH）和风化点（ERH）。与气溶胶的E-AIM模型预测值相比较,实验结果表现出良好的一致性,证实该方法是一种测量大气气溶胶MGFs,ERH和DRH的快速测量方法。